Average Fuel Economy Standards for Light Trucks Model Years 2008-2011, 17566-17679 [06-3151]
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Federal Register / Vol. 71, No. 66 / Thursday, April 6, 2006 / Rules and Regulations
DEPARTMENT OF TRANSPORTATION
National Highway Traffic Safety
Administration
49 CFR Parts 523, 533 and 537
[Docket No. NHTSA 2006–24306]
RIN 2127–AJ61
Average Fuel Economy Standards for
Light Trucks Model Years 2008–2011
National Highway Traffic
Safety Administration (NHTSA),
Department of Transportation.
ACTION: Final rule.
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AGENCY:
SUMMARY: This final rule reforms the
structure of the corporate average fuel
economy (CAFE) program for light
trucks and establishes higher CAFE
standards for model year (MY) 2008–
2011 light trucks. Reforming the CAFE
program will enable it to achieve larger
fuel savings, while enhancing safety and
preventing adverse economic
consequences.
During a transition period of MYs
2008–2010, manufacturers may comply
with CAFE standards established under
the reformed structure (Reformed CAFE)
or with standards established in the
traditional way (Unreformed CAFE).
This will permit manufacturers and the
agency to gain experience with
implementing the Reformed CAFE
standards. In MY 2011, all
manufacturers will be required to
comply with a Reformed CAFE
standard.
Under Reformed CAFE, fuel economy
standards are restructured so that they
are based on a measure of vehicle size
called ‘‘footprint,’’ the product of
multiplying a vehicle’s wheelbase by its
track width. A target level of fuel
economy is established for each
increment in footprint. Smaller footprint
light trucks have higher targets and
larger ones, lower targets. A particular
manufacturer’s compliance obligation
for a model year will be calculated as
the harmonic average of the fuel
economy targets for the manufacturer’s
vehicles, weighted by the distribution of
manufacturer’s production volumes
among the footprint increments. Thus,
each manufacturer will be required to
comply with a single overall average
fuel economy level for each model year
of production.
The Unreformed CAFE standards are:
22.5 miles per gallon (mpg) for MY
2008, 23.1 mpg for MY 2009, and 23.5
mpg for MY 2010. To aid the transition
to Reformed CAFE, the Reformed CAFE
standards for those years are set at levels
intended to ensure that the industry-
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wide costs of the Reformed standards
are roughly equivalent to the industrywide costs of the Unreformed CAFE
standards in those model years. For MY
2011, the Reformed CAFE standard is
set at the level that maximizes net
benefits. Net benefits includes the
increase in light truck prices due to
technology improvements, the decrease
in fuel consumption, and a number of
other factors viewed from a societal
perspective. All of the standards have
been set at the maximum feasible level,
while accounting for technological
feasibility, economic practicability and
other relevant factors.
Since a manufacturer’s compliance
obligation for a model year under
Reformed CAFE depends in part on its
actual production in that model year, its
obligation cannot be calculated with
absolute precision until the final
production figures for that model year
become known. However, a
manufacturer can calculate its
obligation with a reasonably high degree
of accuracy in advance of that model
year, based on its product plans for the
year. Prior to and during the model year,
the manufacturer will be able to track all
of the key variables in the formula used
for calculating its obligation (e.g.,
distribution of production and the fuel
economy of each of its models). This
final rule announces estimates of the
compliance obligations, by
manufacturer, for MYs 2008–2011 under
Reformed CAFE, using the fuel economy
targets established by NHTSA and the
product plans submitted to NHTSA by
the manufacturers in response to an
August 2005 request for updated
product plans.
This rulemaking is mandated by the
Energy Policy and Conservation Act
(EPCA), which was enacted in the
aftermath of the energy crisis created by
the oil embargo of 1973–74. The
concerns about reliance on petroleum
imports, energy security, and the effects
of energy prices and supply on national
economic well-being that led to the
enactment of EPCA remain very much
alive today. America is still overly
dependent on petroleum. Sustained
growth in the demand for oil
worldwide, coupled with tight crude oil
supplies, are the driving forces behind
the sharp price increases seen over the
past several years and are expected to
remain significant factors in the years
ahead. Increasingly, the oil consumed in
the U.S. originates in countries with
political and economic situations that
raise concerns about future oil supply
and prices. In the long run,
technological innovation will play an
increasingly larger role in reducing our
dependence on petroleum.
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We recognize that financial
difficulties currently exist in the motor
vehicle industry and that a substantial
number of job reductions have been
announced recently by large full-line
manufacturers. Accordingly, we have
carefully balanced the costs of the rule
with the benefits of conservation.
Compared to Unreformed CAFE,
Reformed CAFE enhances overall fuel
savings while providing vehicle
manufacturers with the flexibility they
need to respond to changing market
conditions. Reformed CAFE will also
provide a more equitable regulatory
framework by creating a level-playing
field for manufacturers, regardless of
whether they are full-line or limited-line
manufacturers. We are particularly
encouraged that Reformed CAFE will
reduce the adverse safety risks
generated by the Unreformed CAFE
program. The transition from the
Unreformed CAFE to the Reformed
CAFE system will begin soon, but ample
lead time is provided before Reformed
CAFE takes full effect in MY 2011.
DATES: Today’s final rule is effective
August 4, 2006. Petitions for
reconsideration must be received by
May 22, 2006.
ADDRESSES: Petitions for reconsideration
must be submitted to: Administrator,
National Highway Traffic Safety
Administration, 400 Seventh Street,
SW., Nassif Building, Washington, DC
20590–001.
FOR FURTHER INFORMATION CONTACT: For
technical issues, call Ken Katz, Lead
Engineer, Fuel Economy Division,
Office of International Vehicle, Fuel
Economy, and Consumer Standards, at
(202) 366–0846, facsimile (202) 493–
2290, electronic mail
kkatz@nhtsa.dot.gov. For legal issues,
call Stephen Wood or Christopher
Calamita of the Office of the Chief
Counsel, at (202) 366–2992, or e-mail
them at swood@nhtsa.dot.gov or
ccalamita@nhtsa.dot.gov.
SUPPLEMENTARY INFORMATION:
Table of Contents
I. Executive summary
A. Events leading to today’s final rule
B. Today’s final rule
C. Energy demand and supply and the
value of conservation
II. Background
A. 1974 DOT/EPA report to Congress on
potential for motor vehicle fuel economy
improvements
B. Energy Policy and Conservation Act of
1975
C. 1979–2002 light truck standards
D. 2001 National Energy Policy
E. 2002 NAS study of CAFE reform
F. 2003 final rule establishing MY 2005–
2007 light truck standards
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G. 2003 comprehensive plans for
addressing vehicle rollover and
compatibility
H. 2003 ANPRM
1. Need for reform
2. Reform options
I. Recent Developments
1. Factors underscoring need for reform
2. Revised Product Plans
III. Summary of the NPRM
IV. Summary of public comments
V. The Unreformed CAFE standards for MYs
2008–2010
A. Legal authority and requirements under
EPCA
B. Establishing Unreformed standards
according to EPCA—process for
determining maximum feasible levels
C. Baseline for determining manufacturer
capabilities in MYs 2008–2010
D. Technologically feasible additions to
product plans
E. Improved product plans
F. Economic practicability and other
economic issues
1. Costs
2. Benefits
3. Comparison of estimated costs to
estimated benefits
4. Uncertainty
G. Unreformed standards for MYs 2008–
2010
VI. The Reformed CAFE standards for MYs
2008–2011
A. Overview of Reformed CAFE
B. Authority for Reformed CAFE
C. Legal issues related to Reformed CAFE
1. Maximum feasible
2. Backstop
3. Transition period
D. Structure of Reformed CAFE
1. Footprint based function
2. Continuous function
a. Overview of establishing the continuous
function standard
b. Industry-wide considerations in defining
the stringency of the standard
c. Improving the light truck fleet
d. Defining the function and the
preliminary shape of the curve
e. Final level of the curve (and the targets)
3. Application of the continuous function
based standard
4. Why this approach to reform and not
another?
a. Continuous function vs. the proposed
step-function (categories)
b. Continuous function and targets vs.
classes and standards
c. Consideration of additional attributes
d. Backstop and ‘‘fuel saving’’ mechanisms
5. Benefits of reform
a. Increased energy savings
b. Reduced incentive to respond to the
CAFE program in ways harmful to safety
i. Reduces incentive to reduce vehicle size
and to offer smaller vehicles
ii. Reduces the difference between car and
light truck CAFE standards
c. More equitable regulatory framework
d. More responsive to market changes
E. Comparison of estimated costs to
estimated benefits
1. Costs
2. Benefits
3. Uncertainty
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F. MY 2008–2011 Reformed CAFE
standards
VII. Technology issues
A. Reliance on the NAS report
B. Technologies included in the
manufacturers’ product plans
C. Lead Time
D. Technology effectiveness and practical
limitations
E. Technology incompatibility
F. Weight reduction
VIII. Economic assumptions
A. Costs of technology
B. Fuel prices
C. Consumer valuation of fuel economy
and payback period
D. Opportunity costs
E. Rebound effect
F. Discount rate
G. Import externalities (monopsony, oil
disruption effects, and costs of
maintaining U.S. presence and strategic
petroleum reserve)
H. Uncertainty analysis
I. The 15 percent gap
J. Pollution and greenhouse gas valuation
K. Increased driving range and vehicle
miles traveled
L. Added costs from congestion, crashes,
and noise
M. Employment impacts
IX. MY 2008–2010 Transition period
A. Choosing the Reformed or Unreformed
CAFE system
B. Application of credits between
compliance options
X. Impact of other Federal motor vehicle
standards
A. Federal motor vehicle safety standards
1. FMVSS 138, Tire Pressure Monitoring
System 2 FMVSS 202, Head Restraints
3. FMVSS 208, Occupant Crash Protection
(Rear Center Seat Lap/Shoulder Belts)
4. FMVSS 208, Occupant Crash Protection
(35 mph Frontal Impact Testing)
5. FMVSS 301, Fuel System Integrity
B. Potential future safety standards and
voluntary safety improvements
1. Anti-lock Brakes and Electronic Stability
Control (ESC)
2. Roof Crush, FMVSS 216
3. Side Impact and Ejection Mitigation Air
Bags (Thorax and Head Air Bags)
4. Offset Frontal Crash Testing
C. Cumulative weight impacts of the safety
standards and voluntary improvements
D. Federal Motor Vehicle Emissions
Standards
1. Tier 2 requirements
2. Onboard vapor recovery
3. California Air Resources Board—Clean
Air Act Section 209 standards
XI. Need of the Nation to Conserve Energy
XII. Comparison of the final and proposed
standards
A. Changes in the Volpe model
B. Higher fuel price forecasts
C. Revisions to the Reformed CAFE system
D. Updated product plans
E. Evaluating the adopted Reformed CAFE
XIII. Applicability of the CAFE standards
A. Inclusion of MDPVs in MY 2011
B. ‘‘Flat-floor’’ provision
XIV. Additional issues
A. Limited-line manufacturer standard
B. Credit trading
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C. Reporting requirements
D. Preemption
XV. Rulemaking analyses and notices
A. Executive Order 12866 and DOT
Regulatory Policies and Procedures
B. National Environmental Policy Act
C. Regulatory Flexibility Act
D. Executive Order 13132 Federalism
E. Executive Order 12988 (Civil Justice
Reform)
F. Unfunded Mandates Reform Act
G. Paperwork Reduction Act
H. Regulation Identifier Number (RIN)
I. Executive Order 13045
J. National Technology Transfer and
Advancement Act
K. Executive Order 13211
L. Department of Energy review
M. Privacy Act
XVI. Regulatory Text
I. Executive Summary
A. Events Leading to Today’s Final Rule
In the notice of proposed rulemaking
(NPRM) that the agency published on
August 30, 2005, the agency proposed to
reform the light truck CAFE program.
The Reformed CAFE standard was to be
based on a step function.1 To aid the
transition to the Reformed CAFE
system, we proposed to provide
manufacturers with two alternative
compliance options (Unreformed and
Reformed) for manufacturers in MYs
2008–2010. The agency proposed
requiring compliance with the Reformed
CAFE system, beginning in MY 2011.
The agency noted in the NPRM that it
was publishing a separate notice
inviting the manufacturers to submit
more updated product plans and stated
that it recognized that the new plans
might differ enough from the previously
submitted plans to necessitate changes
in the shape of the step function as well
as in the levels of stringency of the
standards.
In addition, the agency invited public
comment on a number of additional
changes to the CAFE program. One was
whether to base the Reformed CAFE on
a continuous function instead of a step
function. A second was whether to
include large sport utility vehicles
(SUVs) in the CAFE standards. A third
was whether to revise the ‘‘flat floor’’
criterion for classifying vehicles as light
trucks so that minivans and passenger
vans would be treated as light trucks.
In response to the NPRM and request
for new product plans, the agency
1 As proposed, the structure of Reformed CAFE
for each model year would have three basic
elements—
(1)—six footprint categories of vehicles.
(2)—a target level of average fuel economy for
each footprint category, as expressed by a step
function (see figure 1 below).
(3)—a Reformed CAFE standard based on the
harmonic production-weighted average of the fuel
economy targets for each category.
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obtained a great deal of new
information. Compared to the plans that
the manufacturers submitted to the
agency in early 2004, the new plans
submitted in November 2005 contained
a significant increase in the variety and
amount of efforts to improve fuel
economy. The agency also received
critiques of the analyses it performed to
determine the fuel economy capabilities
of the manufacturers in MYs 2008–2011.
In response to the public comments,
the agency revised its analyses and
assumptions including those related to
the rate at which increased amounts of
fuel saving technologies can be added to
a manufacturer’s fleet. The new
assumptions are closer to the
assumptions made by the National
Academies of Science in a 2002 study
of the CAFE program, and provide
increased assurance that the standards
adopted today will be economically
practicable.
NHTSA also made other changes. It
decided to base Reformed CAFE on a
continuous function instead of a step
function in order to reduce the incentive
under Reformed CAFE for
manufacturers to downsize (thus
reducing safety) or upsize (thus
reducing fuel economy) vehicles. It also
decided to add the larger SUVs and
passenger vans to the mandatory
Reformed CAFE program in MY 2011
and beyond to increase long-term energy
savings.
B. Today’s Final Rule
The final rule adopted today reforms
the structure of the CAFE regulatory
program so that it achieves higher fuel
savings while enhancing safety and
preventing adverse economic
consequences. We have previously set
forth our concerns about the way in
which the current CAFE program
operates and sought comment on
approaches to reforming the CAFE
program. We have also previously
increased light truck CAFE standards,
from the ‘‘frozen’’ level of 20.7 mpg
applicable from MY 1996 through MY
2004, to a level of 22.2 mpg applicable
to MY 2007. In adopting those increased
standards, we noted that we were
limited in our ability to make further
increases without reforming the
program.
The Reformed CAFE structure
established and institutionalized in this
document minimizes those limitations
by establishing a system based on light
truck size, which allows us to establish
higher CAFE standards for MY 2008–
2011 light trucks and achieve greater
fuel savings across the industry. In
addition to the improved energy
savings, this CAFE program enhances
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safety by eliminating the previous
regulatory incentive to downsize
vehicles and by raising the light truck
standards so that there is no regulatory
incentive from the CAFE program to
design small vehicles as light trucks
instead of passenger cars. It prevents
adverse economic consequences by
incorporating greater consideration of
economic practicability issues into the
projections of the timing and rate at
which manufacturers can introduce fuel
economy improving technologies into
their fleets, and by setting the Reformed
CAFE standards, beginning in MY 2011,
at the level at which marginal benefits
equal marginal costs.
During a transition period of MYs
2008–2010, manufacturers may comply
with CAFE standards established under
the reformed structure (Reformed CAFE)
or with standards established in the
traditional way (Unreformed CAFE).
This will permit manufacturers to gain
experience with the Reformed CAFE
standards. The Reformed CAFE
standards for those model years are set
at levels intended to ensure that the
industry-wide costs of those standards
are roughly equivalent to the industrywide costs of the Unreformed CAFE
standards for those model years. The
additional lead time provided by the
transition period will aid, for example,
those manufacturers that, for the first
time, face a binding CAFE standard (i.e.,
one set above their planned level of
CAFE) and will be required to make fuel
economy improvements to achieve
compliance. In MY 2011, all
manufacturers are required to comply
with a Reformed CAFE standard. The
Reformed CAFE standard for that model
year is set at the level that maximizes
net benefits by setting the fuel economy
targets at the point at which marginal
benefits of the last added increment of
fuel savings equal the marginal costs of
the added technology that produced
those savings.
As in prior CAFE rulemakings
establishing Unreformed standards, this
final rule sets the Unreformed standards
for MYs 2008–2010 with particular
regard to the capabilities of and impacts
on the ‘‘least capable’’ full line
manufacturer (i.e., a full line
manufacturer is one that produces a
wide variety of types and sizes of
vehicles) with a significant share of the
market. A single CAFE level, applicable
to each manufacturer, is established for
each model year.
The Unreformed CAFE standards for
MYs 2008–2010 are:
MY 2008: 22.5 mpg
MY 2009: 23.1 mpg
MY 2010: 23.5 mpg
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We estimate that compliance with these
standards will save 4.4 billion gallons of
fuel over the lifetime of the vehicles
sold during those model years,
compared to the savings that would
occur if the standards remained at the
MY 2007 level of 22.2 mpg.
Under Reformed CAFE, each
manufacturer’s required level of CAFE
is based on target levels set according to
vehicle size. The targets are assigned
according to a vehicle’s ‘‘footprint’’—the
product of the average track width (the
distance between the centerline of the
tires) and wheelbase (basically, the
distance between the centers of the
axles). Each vehicle footprint value is
assigned a target specific to that
footprint value. This differs from what
we proposed. The proposed reform was
based on a discontinuous (or ‘‘step’’)
function. The proposal segmented the
light truck fleet into six discrete
categories based on ranges of footprint
and assigned a target fuel economy
value for each category. The reform
adopted in today’s final rule is based on
a continuous function. Under it, targets
are assigned along the continuum of
footprint values in the light truck fleet.
Each footprint value has a different
target. The target values reflect the
technological and economic capabilities
of the industry. The target for a given
footprint value is the same for all
manufacturers, regardless of differences
in their overall fleet mixes. Compliance
is determined by comparing a
manufacturer’s harmonically averaged
fleet fuel economy in a model year with
a required fuel economy level calculated
using the manufacturer’s actual
production levels and the category
targets.
The Reformed CAFE standards
adopted today are more stringent than
those proposed in the NPRM. Under the
Reformed CAFE system in the NPRM,
we estimated that the average CAFE
level required of light truck
manufacturers would be 23.9 mpg. It is
important to note that the MY 2011
standard as adopted in this rule applies
to a larger population of vehicles than
that in the NPRM. Today’s final rule
includes medium duty passenger
vehicles (MDPVs) (i.e., larger passenger
vans and SUVs) as part of the MY 2011
regulated fleet. We estimate that the
average CAFE level required of
manufacturers under this rule in MY
2011 will be 24.0 mpg. Thus, the MY
2011 standard is more stringent than
that proposed while regulating more
vehicles, i.e., larger vehicles with
typically low fuel economy
performance.
As stated above, manufacturers
provided updated product plans that
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reflect changes made to the evaluated
light truck fleet used in the NPRM,
partly in response to changes in fuel
prices. Changing market conditions, a
regulatory landscape revised by our
proposal, and the more stringent fuel
efficiency levels required under Reform
CAFE will result in the production of
MY 2008–2011 light truck fleets that
will consume approximately 11 billion
fewer gallons of fuel over their lifetimes
than the fleets that were originally
planned in 2004.
Apart from the updated product
plans, the agency has revised some of
the assumptions inputted into the
Reformed CAFE analysis. In response to
comments and consistent with the
findings of the National Academy of
Sciences, we revised the phase-in rates
to provide for additional lead-time
when projecting technology
applications. The agency also revised
fuel prices and the vehicle miles
traveled schedule, which is used to
calculate fuel savings, in response to
higher fuel price forecasts.
Given the revised product plans, the
revisions to the model assumptions, and
the more stringent standards adopted in
this rule, the Reformed standards will
save approximately 7.8 billion
additional gallons of fuel over the
lifetime of the vehicles sold during
those four model years. The Reformed
standards for MYs 2008–2010 will save
approximately 500 million more gallons
of fuel than the Unreformed standards
for those model years. As noted above,
the Reformed standard for MY 2011 is
the first Reformed standard set through
a process the explicitly maximizes net
benefits. It will save more than 2.8
billion gallons of fuel over the lifetime
of vehicle sold in that model year.
In order to provide a comparison of
the fuel savings of the final rule versus
the proposed rule, we recalculated the
fuel savings from the proposed
Reformed CAFE standards using the
updated product plans and the final rule
assumptions. Under this analysis, we
calculated that the proposed Reformed
standards would save 5.4 billion gallons
under these more current assumptions.
This compares to the 7.8 billion gallons
of fuel saved under the more stringent
Reformed CAFE standards adopted
today.
If all manufacturers comply with the
Reformed CAFE standards, the total
costs would be approximately $6.7
billion for MYs 2008–2011, compared to
the costs they would incur if the
standards remained at the MY 2007
level of 22.2 mpg. The resulting vehicle
price increases to buyers of MY 2008
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light trucks would be paid back 2 in
additional fuel savings in an average of
2.9 years and to buyers of MY 2011 light
trucks in an average of 4,4 years,
assuming fuel prices ranging from $1.96
to $2.39 per gallon (in 2003 dollars).3
We estimate that the total benefits under
the Unreformed CAFE standards for
MYs 2008–2010 plus the Reformed
CAFE standard for MY 2011 are
approximately $7.6 billion (2003
dollars, discounted at 7%), and under
the Reformed CAFE standards for MYs
2008–2011 are approximately $8.1
billion (2003 dollars, discounted at 7%).
We have determined that the
standards under both Unreformed CAFE
and Reformed CAFE represent the
maximum feasible fuel economy level
for each system. In reaching this
conclusion, we have balanced the
express statutory factors and other
relevant considerations, such as safety
concerns, effects on employment and
the need for flexibility to transition to a
Reformed CAFE program that can
achieve greater fuel savings in a more
economically efficient way.
The Reformed CAFE approach
incorporates several important elements
of reform suggested by the National
Academy of Sciences in its 2002 report
(Effectiveness and Impact of Corporate
2 The payback period represents the length of
time required for a vehicle buyer to recoup the
higher cost of purchasing a more fuel-efficient
vehicle through savings in fuel use. When a more
stringent CAFE standard requires a manufacturer to
improve the fuel economy of some of its vehicle
models, the manufacturer’s added costs for doing so
are reflected in higher prices for these models.
While buyers of these models pay higher prices to
purchase these vehicles, their improved fuel
economy lowers their owners’ costs for purchasing
fuel to operate them. Over time, buyers thus recoup
the higher purchase prices they pay for these
vehicles in the form of savings in outlays for fuel.
The length of time required to repay the higher cost
of buying a more fuel-efficient vehicle is referred to
as the buyer’s ‘‘payback period.’’
The length of this payback period depends on the
initial increase in a vehicle’s purchase price, the
improvement in its fuel economy, the number of
miles it is driven each year, and the retail price of
fuel. We calculated payback periods using the fuel
economy improvement and average price increase
for each manufacturer’s vehicles estimated to result
from the proposed standard, the U.S. Energy
Information Administration’s forecast of future
retail gasoline prices, and estimates of the number
of miles light trucks are driven each year as they
age developed from U.S. Department of
Transportation data. Energy Information
Administration, Annual Energy Outlook 2005 (AEO
2005), Table 100, https://www.eia.doe.gov/oiaf/aeo/
supplement/; and U.S. Department of
Transportation, 2001 National Household Travel
Survey, https://nhts.ornl.gov/2001/index.shtml.
Under these assumptions, payback periods for the
final rule alternatives (i.e., Unreformed and
Reformed CAFE) range from 2.9 to 4.9 years. .
3 The fuel prices used to calculate the length of
the payback periods are those expected over the life
of the MY 2008–2011 light trucks, not the current
fuel prices. Those future fuel prices were obtained
from the AEO 2006 (Early Report).
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Average Fuel Economy (CAFE)
Standards). The agency believes that
these reforms give the Reformed CAFE
approach four basic advantages over the
Unreformed CAFE approach.
First, Reformed CAFE increases
energy savings. The energy-saving
potential of Unreformed CAFE is
limited because only a few full-line
manufacturers are required to make
improvements. In effect, the capabilities
of these full-line manufacturers, whose
offerings include larger and heavier
light trucks, constrain the stringency of
the uniform, industry-wide standard. As
a result, the Unreformed CAFE standard
is generally set below the capabilities of
limited-line manufacturers, who sell
predominantly lighter and smaller light
trucks. Under Reformed CAFE, which
accounts for size differences in product
mix, virtually all light-truck
manufacturers will be required to use
advanced fuel-saving technologies to
achieve the requisite fuel economy for
their vehicles. Thus, Reformed CAFE
will continue to require full-line
manufacturers to improve the overall
fuel economy of their fleets, while also
requiring limited-line manufacturers to
enhance the fuel economy of the
vehicles they sell.
Second, Reformed CAFE offers
enhanced safety. Due to the structure of
Unreformed CAFE standards, vehicle
manufacturers that need to supplement
their product plans in order to comply
with the standards can increase their
likelihood of compliance by pursuing a
variety of compliance strategies that
entail safety risks: Downsizing of
vehicles, design of some vehicles to
permit classification as ‘‘light trucks’’
for CAFE purposes, and offering smaller
and lighter vehicles to offset sales of
larger and heavier vehicles. The adverse
safety effects of downsizing and
downweighting have already been
documented for passenger cars in the
CAFE program. For example, when a
manufacturer designs a vehicle to
permit its classification as a light truck,
it may increase the vehicle’s propensity
to roll over.
Reformed CAFE is designed to lessen
each of these safety risks. Downsizing of
vehicles is discouraged under Reformed
CAFE since as vehicles become smaller,
the applicable fuel economy target
becomes more stringent. Moreover,
Reformed CAFE lessens the incentive to
design smaller vehicles to achieve a
‘‘light truck’’ classification, since many
small light trucks are subject to targets
that have at least the same degree of
stringency as passenger car standards, if
not higher stringency.
Third, Reformed CAFE provides a
more equitable regulatory framework for
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different vehicle manufacturers. Under
Unreformed CAFE, the cost burdens and
compliance difficulties have been
imposed nearly exclusively on the fullline manufacturers. Reformed CAFE
spreads the regulatory cost burden for
fuel economy more broadly across the
industry.
Fourth, Reformed CAFE is more
market-oriented because it more fully
respects economic conditions and
consumer choice. Reformed CAFE does
not force vehicle manufacturers to
adjust fleet mix toward smaller vehicles
unless that is what consumers are
demanding. Instead, it allows the
manufacturers to adjust the mix of their
product offerings in response to the
market place. As a result, as the
industry’s sales volume and mix
changes in response to economic
conditions (e.g., gasoline prices and
household income) and consumer
preferences (e.g., desire for seating
capacity or hauling capability), the level
of CAFE required of manufacturers
under Reformed CAFE will, at least
partially, adjust automatically to these
changes. Accordingly, Reformed CAFE
reduces the need that the agency might
otherwise have to revisit previously
established standards in light of
changed market conditions, a difficult
process that undermines regulatory
certainty for the industry. In the mid1980’s, for example, the agency relaxed
several Unreformed CAFE standards
because fuel prices fell more than had
been expected when those standards
were established and, as a result,
consumer demand for small vehicles
with high fuel economy did not
materialize as expected.
In addition to reforming the structure
of the light truck CAFE program, we are
also expanding its applicability. Starting
in MY 2011, the CAFE program will
include MPDVs, light trucks that have a
gross vehicle weight rating (GVWR) less
than 10,000 lbs., a GVWR greater than
8,500 lbs. or a curb weight greater than
6,000 lbs., and that primarily transport
passengers. We estimate this will bring
an additional 240,000 vehicles into the
CAFE program in that model year.
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C. Energy Demand and Supply and the
Value of Conservation
As we noted in the notice of proposed
rulemaking (NPRM),4 many of the
concerns about energy security and the
effects of energy prices and supply on
national economic well-being that led to
the enactment of EPCA in 1975 persist
4 70
FR 51414, August 30, 2005.
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today.5 The demand for oil is steadily
growing in the U.S. and around the
world. By 2030, U.S. demand for
petroleum products is expected to
increase 33 percent compared to 2004.6
World oil demand is expected to
increase by nearly 44 percent between
2004 and 2025.7 Most of these increases
would occur in the transportation
sector. To meet this projected increase
in world demand, worldwide
productive capacity would have to
increase by more than 36 million barrels
per day over current levels. OPEC
producers are expected to supply nearly
40 percent of the increased production.
By 2025, 60 percent of the oil consumed
in the U.S. would be imported oil.
Strong growth in the demand for oil
worldwide, coupled with tight crude oil
supplies, is the driving force behind the
sharp price increases seen over the past
four years. Increasingly, the oil
consumed in the U.S. originates in
countries with political and economic
situations that raise concerns about
future oil supply and prices.
Energy is an essential input to the
U.S. economy and having a strong
economy is essential to maintaining and
strengthening our national security.
Conserving energy, especially reducing
the nation’s dependence on petroleum,
benefits the U.S. in several ways.
Reducing total petroleum use decreases
our economy’s vulnerability to oil price
shocks. Reducing dependence on oil
imports from regions with uncertain
conditions enhances our energy
security. Reducing the growth rate of oil
use will help relieve pressures on
already strained domestic refinery
capacity, decreasing the likelihood of
future product price volatility.
Today’s final rule is one piece of
President Bush’s strategy to move the
nation beyond a petroleum-based
economy. Aside from the fuel savings
that will be realized by today’s final
rule, the Administration is focusing
research on bio-based transportation
fuels, improved batteries for hybrid
vehicles, and the on-going hydrogen
fuel initiative. The President’s
Advanced Energy Initiative and today’s
final rule will build on the progress
made by the Administration’s 2001
National Energy Policy and the
increased CAFE standards for MY 2005–
2007 light trucks.
5 The sources of the figures in this section can be
found below in section VIII, ‘‘Need for Nation to
conserve energy.’’
6 Annual Energy Outlook 2006 with projections to
2030 (Early Release), https://www.eia.doe.gov/oiaf/
aeo/.
7 Id.
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II. Background
In proposing the CAFE standards for
MYs 2008–2011, the agency provided a
detailed summary of the history of fuel
economy standards, and in particular,
fuel economy standards for light trucks.
Below we have provided a summary of
that discussion. For more background
on the light truck CAFE program, refer
to the NPRM.
A. 1974 DOT/EPA Report to Congress on
Potential for Motor Vehicle Fuel
Economy Improvements
In 1974, the Department of
Transportation (DOT) and
Environmental Protection Agency (EPA)
submitted to Congress a report entitled
‘‘Potential for Motor Vehicle Fuel
Economy Improvement (1974 Report).8
This report was prepared in compliance
with Section 10 of the Energy Supply
and Environmental Coordination Act of
1974, Public Law 93–319 (the Act). In
the 1974 Report, DOT/EPA said that
performance standards regulating fuel
economy could take either of two
modes: a production-weighted average
standard for each manufacturer’s entire
fleet of vehicles or a fuel economy
standard tailored to individual classes
of vehicles. Included as a possible form
for a production-weighted standard was
a variable standard based on the costs or
potential to improve for each
manufacturer (1974 Report, p. 77).
DOT/EPA concluded in the 1974
Report that a production-weighted
standard establishing one uniform
specific fuel economy average for all
manufacturers would, if sufficiently
stringent to have the needed effect,
impact most heavily on manufacturers
who have lower fuel economy, while
not requiring manufacturers of current
vehicles with better fuel economy to
maintain or improve their performance.
(1974 Report, p. 12) Productionweighted standards specifically tailored
to each manufacturer would eliminate
some inequities, but were considered to
be difficult to administer fairly. (Ibid.)
B. Energy Policy and Conservation Act
of 1975
Congress enacted the Energy Policy
and Conservation Act (EPCA Pub. L. 94–
163) during the aftermath of the energy
crisis created by the oil embargo of
1973–74. The Act established an
automobile fuel economy regulatory
program by adding Title V, ‘‘Improving
Automotive Efficiency,’’ to the Motor
Vehicle Information and Cost Savings
Act. Title V has been amended from
time to time and codified without
8 The 1974 report is available in the docket for
this rulemaking.
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substantive change as Chapter 329 of
title 49, United States Code. Chapter 329
provides for the issuance of average fuel
economy standards for passenger
automobiles and separate standards for
automobiles that are not passenger
automobiles (light trucks).
For the purposes of the CAFE statute,
‘‘automobiles’’ include any ‘‘4-wheeled
vehicle that is propelled by fuel (or by
alternative fuel) manufactured primarily
for use on public streets, roads, and
highways (except a vehicle operated
only on a rail line), and rated at not
more than 6,000 pounds gross vehicle
weight.’’ They also include any such
vehicle rated at between 6,000 and
10,000 pounds gross vehicle weight
(GVWR) if the Secretary decides by
regulation that an average fuel economy
standard for the vehicle is feasible, and
that either such a standard will result in
significant energy conservation or the
vehicle is substantially used for the
same purposes as a vehicle rated at not
more than 6,000 pounds GVWR.9
The CAFE standards set a minimum
performance requirement in terms of an
average number of miles a vehicle
travels per gallon of gasoline or diesel
fuel. Individual vehicles and models are
not required to meet the mileage
standard. Instead, each manufacturer
must achieve a harmonically averaged
level of fuel economy for all specified
vehicles manufactured by a
manufacturer in a given MY. The statute
distinguishes between ‘‘passenger
automobiles’’ and ‘‘non-passenger
automobiles.’’ We generally refer to nonpassenger automobiles as light trucks.
In enacting EPCA and after
considering the variety of approaches
presented in the 1974 Report, Congress
made a clear and specific choice about
the structure of the average fuel
economy standard for passenger cars.
Congress established a common
statutory CAFE standard applicable to
each manufacturer’s fleet of passenger
automobiles.
Congress was considerably less
decided and prescriptive with respect to
what sort of standards and procedures
should be established for light trucks. It
neither made a clear choice among the
approaches (or among the forms of those
approaches) identified in the 1974
Report nor precluded the selection of
any of those approaches or forms.
Further, it did not establish by statute a
CAFE standard for light trucks. Instead,
Congress provided the Secretary with a
9 In 1978, we extended the CAFE program to
include vehicles rated between 6,000 and 8,500
pounds GVWR (March 23, 1978; 43 FR 11995, at
11997). Vehicles rated at between 6,000 and 8,500
pounds GVWR first became subject to the CAFE
standards in MY 1980.
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choice of establishing a form of a
production-weighted average standard
for each manufacturer’s entire fleet of
light trucks, as suggested in the 1974
Report, or a form of productionweighted standards for classes of light
trucks. Congress directed the Secretary
to establish maximum feasible CAFE
standards applicable to each
manufacturer’s light truck fleet, or
alternatively, to classes of light trucks,
and to establish them at least 18 months
prior to the start of each model year.
When determining a ‘‘maximum feasible
level of fuel economy,’’ the Secretary is
directed to balance factors including the
nation’s need to conserve energy,
technological feasibility, economic
practicability and the impact of other
motor vehicle standards on fuel
economy.
C. 1979–2002 Light Truck Standards
NHTSA established the first light
truck CAFE standards for MY 1979 and
applied them to light trucks with a
GVWR up to 6,000 pounds (March 14,
1977; 42 FR 13807). Beginning with MY
1980, NHTSA raised this GVWR ceiling
to 8,500 pounds. For MYs 1979–1981,
the agency established separate
standards for two-wheel drive (2WD)
and four-wheel drive (4WD) light trucks
without a ‘‘combined’’ standard
reflecting the combined capabilities of
2WD and 4WD light trucks.
Manufacturers that produced both 2WD
vehicles and 4WD vehicles could,
however, decide to treat them as a single
fleet and comply with the 2WD
standard.
Beginning with MY 1982, NHTSA
established a combined standard
reflecting the combined capabilities of
2WD and 4WD light trucks, plus
optional 2WD and 4WD standards.
Manufacturers had the option of
complying under the combined fleet
standard, or under the separate 2WD
and 4WD standards. Although the
combined standard reflected the
combined capabilities of 2WD and 4WD
light trucks, it did not necessarily reflect
the combined capabilities of the 2WD
and 4WD fleets of an individual
manufacturer (e.g., a manufacturer may
have found it easier to comply with the
combined standard than the 2WD and
4WD standards separately, or vice
versa). After MY 1991, NHTSA dropped
the optional 2WD and 4WD standards.
As explained in the NPRM, NHTSA
twice found it necessary to reduce a
light truck standard when it received
new information relating to the agency’s
past projections. In 1979, the agency
reduced the MY 1981 2WD standard
after Chrysler demonstrated that there
were smaller than expected fuel
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economy benefits from various
technological improvements and larger
than expected adverse impacts from
other federal vehicle standards and test
procedures (December 31, 1979; 44 FR
77199).
In 1984, the agency reduced the MY
1985 light truck standards after we
concluded that market demand for light
truck performance, as reflected in
engine mix and axle ratio usage, had not
materialized as anticipated when the
agency initially established the MY
1985 standards. The agency said that
this resulted from lower than
anticipated fuel prices. The agency
concluded that the only actions then
available to manufacturers to improve
their fuel economy levels for MY 1986
would have involved product
restrictions likely resulting in
significant adverse economic impacts.
The reduction of the MY 1985 standard
was upheld by the U.S. Circuit Court of
Appeals for the District of Columbia.
Center for Auto Safety v. NHTSA, 793
F.2d 1322 (D.C. Cir. 1986) (rejecting the
contention that the agency gave
impermissible weight to the effects of
shifts in consumer demand toward
larger, less fuel-efficient trucks on the
fuel economy levels manufacturers
could achieve).10
On November 15, 1995, the
Department of Transportation and
Related Agencies Appropriations Act for
FY 1996 was enacted, which limited the
ability of the agency to establish CAFE
standards for light trucks (Section 330,
Pub. L. 104–50). Pursuant to that Act,
we then issued a final rule limited to
MY 1998, setting the light truck CAFE
standard for that year at 20.7 mpg, the
same level as the standard we had set
for MY 1997 (61 FR 14680; April 3,
1996). The same limitation on the
setting of CAFE standards was included
in the Appropriations Acts for each of
FYs 1997–2001. The agency followed
the same process as for MY 1998,
established the light truck CAFE
standard at 20.7 mpg, for MYs 1999–
2002.
10 NHTSA similarly found it necessary on
occasion to reduce the passenger car CAFE
standards in response to new information. The
agency reduced the MY 1986 passenger car
standard because a continuing decline in gasoline
prices prevented a projected shift in consumer
demand toward smaller cars and smaller engines
and because the only actions available to
manufacturers to improve their fuel economy levels
for MY 1986 would have involved product
restrictions likely resulting in significant adverse
economic impacts. (October 4, 1985; 40 FR 40528)
This action was upheld in Public Citizen v. NHTSA,
848 F.2d 256 (D.C. Cir. 1988). NHTSA also reduced
the MY 1987–88 passenger car standards (October
6, 1986; 51 FR 35594) and MY 1989 passenger car
standard (October 6, 1988; 53 FR 39275) for similar
reasons.
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While the Department of
Transportation and Related Agencies
Appropriations Act for FY 2001 (Pub. L.
106–346) contained a restriction on
CAFE rulemaking identical to that
contained in prior appropriation acts,
the conference committee report for that
Act directed NHTSA to fund a study by
the NAS to evaluate the effectiveness
and impacts of CAFE standards (H. Rep.
No. 106–940, at p. 117–118).
In a letter dated July 10, 2001,
following the release of the President’s
National Energy Policy, Secretary of
Transportation Mineta asked the House
and Senate Appropriations Committees
to lift the restriction on the agency
spending funds for the purposes of
improving CAFE standards. The
Department of Transportation and
Related Agencies Appropriations Act for
FY 2002 (Pub. L. 107–87), which was
enacted on December 18, 2001, did not
contain a provision restricting the
Secretary’s authority to prescribe fuel
economy standards.
D. 2001 National Energy Policy
The National Energy Policy,11
released in May 2001, stated that ‘‘(a)
fundamental imbalance between supply
and demand defines our nation’s energy
crisis’’ and that ‘‘(t)his imbalance, if
allowed to continue, will inevitably
undermine our economy, our standard
of living, and our national security.’’
The National Energy Policy was
designed to promote dependable,
affordable and environmentally sound
energy for the future. The Policy
envisions a comprehensive long-term
strategy that uses leading edge
technology to produce an integrated
energy, environmental and economic
policy. It set forth five specific national
goals: ‘‘modernize conservation,
modernize our energy infrastructure,
increase energy supplies, accelerate the
protection and improvement of the
environment, and increase our nation’s
energy security.’’
The National Energy Policy included
recommendations regarding the path
that the Administration’s energy policy
should take and included specific
recommendations regarding vehicle fuel
economy and CAFE. It recommended
that the President direct the Secretary of
Transportation to—
—Review and provide
recommendations on establishing
CAFE standards with due
consideration of the National
Academy of Sciences study released
(in prepublication form) in July 2001.
Responsibly crafted CAFE standards
11 https://www.whitehouse.gov/energy/National-
Energy-Policy.pdf.
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should increase efficiency without
negatively impacting the U.S.
automotive industry. The
determination of future fuel economy
standards must therefore be addressed
analytically and based on sound
science.
—Consider passenger safety, economic
concerns, and disparate impact on the
U.S. versus foreign fleet of
automobiles.
—Look at other market-based
approaches to increasing the national
average fuel economy of new motor
vehicles.
E. 2002 NAS Study of CAFE Reform
In response to direction from
Congress, NAS published a lengthy
report in 2002 entitled ‘‘Effectiveness
and Impact of Corporate Average Fuel
Economy (CAFE) Standards.’’ 12
The report concludes that the CAFE
program has clearly contributed to
increased fuel economy and that it was
appropriate to consider further increases
in CAFE standards. (NAS, p. 3 (Finding
1)) It cited not only the value of fuel
savings, but also adverse consequences
(i.e., externalities) associated with high
levels of petroleum importation and use
that are not reflected in the price of
petroleum (e.g., the adverse impact on
energy security). The report further
concluded that technologies exist that
could significantly reduce fuel
consumption by passenger cars and
light trucks within 15 years, while
maintaining vehicle size, weight, utility
and performance. (NAS, p. 3 (Finding
5)) Light duty trucks were said to offer
the greatest potential for reducing fuel
consumption. (NAS, p. 4 (Finding 5))
The report also noted that vehicle
development cycles—as well as future
economic, regulatory, safety and
consumer preferences—would influence
the extent to which these technologies
could lead to increased fuel economy in
the U.S. market. The report noted that
the widespread penetration of even
existing technologies will probably
require 4–8 years. To assess the
economic trade-offs associated with the
introduction of existing and emerging
technologies to improve fuel economy,
the NAS conducted what it called a
‘‘cost-efficient analysis’’—‘‘that is, the
committee [that authored the report]
identified packages of existing and
emerging technologies that could be
introduced over the next 10 to 15 years
that would improve fuel economy up to
the point where further increases in fuel
12 The NAS submitted its preliminary report to
the Department of Transportation in July 2001 and
released its final report in January 2002.
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economy would not be reimbursed by
fuel savings.’’ (NAS, p. 4 (Finding 6))
Recognizing the many trade-offs that
must be considered in setting fuel
economy standards, the report took no
position on what CAFE standards would
be appropriate for future years. It noted,
‘‘(s)election of fuel economy targets will
require uncertain and difficult trade-offs
among environmental benefits, vehicle
safety, cost, oil import dependence, and
consumer preferences.’’
The report found that, to minimize
financial impacts on manufacturers, and
on their suppliers, employees, and
consumers, sufficient lead-time
(consistent with normal product life
cycles) should be given when
considering increases in CAFE
standards. The report stated that there
are advanced technologies that could be
employed, without negatively affecting
the automobile industry, if sufficient
lead-time were provided to the
manufacturers.
The report expressed concerns about
increasing the standards under the
CAFE program as currently structured.
While raising CAFE standards under the
existing structure would reduce fuel
consumption, doing so under alternative
structures ‘‘could accomplish the same
end at lower cost, provide more
flexibility to manufacturers, or address
inequities arising from the present’’
structure. (NAS, pp. 4–5 (Finding 10))13
Further, the committee said, ‘‘to the
extent that the size and weight of the
fleet have been constrained by CAFE
requirements * * * those requirements
have caused more injuries and fatalities
on the road than would otherwise have
occurred.’’ (NAS, p. 29) Specifically,
they noted: ‘‘the downweighting and
downsizing that occurred in the late
1970s and early 1980s, some of which
was due to CAFE standards, probably
resulted in an additional 1300 to 2600
traffic fatalities in 1993.’’ (NAS, p. 3
(Finding 2)).
To address those structural problems,
the report suggested various possible
13 The report noted the following about the
concept of equity:
Potential Inequities
The issue of equity or inequity is subjective.
However, one concept of equity among
manufacturers requires equal treatment of
equivalent vehicles made by different
manufacturers. The current CAFE standards fail this
test. If one manufacturer was positioned in the
market selling many large passenger cars and
thereby was just meeting the CAFE standard,
adding a 22-mpg car (below the 27.5-mpg standard)
would result in a financial penalty or would require
significant improvements in fuel economy for the
remainder of the passenger cars. But, if another
manufacturer was selling many small cars and was
significantly exceeding the CAFE standard, adding
a 22-mpg vehicle would have no negative
consequences.
(NAS, p. 102).
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reforms.14 The report found that the
‘‘CAFE program might be improved
significantly by converting it to a system
in which fuel targets depend on vehicle
attributes.’’ (NAS, p. 5 (Finding 12)).
The report noted that a system in which
fuel economy targets were dependent on
vehicle weight, with lower fuel
consumption targets set for lighter
vehicles and higher targets for heavier
vehicles, up to some maximum weight,
would create incentives to reduce the
variance in vehicle weights between
large and small vehicles, thus providing
for overall vehicle safety. (NAS, p. 5
(Finding 12)). The report stated that
such a system has the potential to
increase fuel economy with fewer
negative effects on both safety and
consumer choice.
The report noted further that under an
attribute-based approach, the required
CAFE levels could vary among the
manufacturers based on the distribution
of their product mix. NAS stated that
targets could vary among passenger cars
and among trucks, based on some
attribute of these vehicles such as
weight, size, or load-carrying capacity.
The report explained that a particular
manufacturer’s average target for
passenger cars or for trucks would
depend upon the fractions of vehicles it
sold with particular levels of these
attributes (NAS, p. 87). For example, if
weight were the criterion, a
manufacturer that sells mostly light
vehicles would have to achieve higher
average fuel economy than would a
manufacturer that sells mostly heavy
vehicles.
The report illustrated an example of
an attribute-based system using a
continuous function (NAS, p. 109).
Essentially, as illustrated, the
continuous function was represented as
a line, which graphed ‘‘gallons per
mile’’ versus ‘‘curb weight.’’ Under the
continuous function example, a
vehicle’s target fuel economy would be
determined by locating the vehicle’s
curb weight along the line and
identifying the corresponding gallons
per mile value.
14 In assessing and comparing possible reforms,
the report urged consideration of the following
factors:
Fuel use responses encouraged by the policy,
Effectiveness in reducing fuel use,
Minimizing costs of fuel use reduction,
Other potential consequences
—Distributional impacts
—Safety
—Consumer satisfaction
—Mobility
—Environment
—Potential inequities, and Administrative
feasibility.
(NAS, p. 94).
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In February 2002, Secretary Mineta
asked Congress ‘‘to provide the
Department of Transportation with the
necessary authority to reform the CAFE
program, guided by the NAS report’s
suggestions.’’
F. 2003 Final Rule Establishing MY
2005–2007 Light Truck Standards
On April 7, 2003, the agency
published a final rule establishing light
truck CAFE standards for MYs 2005–
2007: 21.0 mpg for MY 2005, 21.6 mpg
for MY 2006, and 22.2 mpg for MY 2007
(68 FR 16868; Docket No. 2002–11419;
Notice 3). The agency determined that
these levels are the maximum feasible
CAFE levels for light trucks for those
model years, balancing the express
statutory factors and other included or
relevant considerations such as the
impact of the standard on motor vehicle
safety and employment. NHTSA
estimated that the fuel economy
increases required by the standards for
MYs 2005–2007 would generate
approximately 3.6 billion gallons of
gasoline savings over the 25-year
lifetime of the affected vehicles.
We recognized in the final rule that
the standard established for MY 2007
could be a challenge for General Motors.
We recognized further that, between the
issuance of the final rule and the last
(MY 2007) of the model years for which
standards were being established, there
was more time than in previous light
truck CAFE rulemakings for significant
changes to occur in external factors
capable of affecting the achievable
levels of CAFE. These external factors
include fuel prices and the demand for
vehicles with advanced fuel saving
technologies, such as hybrid electric
and advanced diesel vehicles. We said
that changes in these factors could lead
to higher or lower levels of CAFE,
particularly in MY 2007. Recognizing
that it may be appropriate to re-examine
the MY 2007 standard in light of any
significant changes in those factors, the
agency reaffirms its plans to monitor the
compliance efforts of the manufacturers.
G. 2003 Comprehensive Plans for
Addressing Vehicle Rollover and
Compatibility
In September 2002, NHTSA
completed a thorough examination of
the opportunities for significantly
improving vehicle and highway safety
and announced the establishment of
interdisciplinary teams to formulate
comprehensive plans for addressing the
four most promising problem areas.15
Based on the work of the teams, the
15 A fifth problem area was announced in 2004,
improving traffic safety data.
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agency issued detailed reports analyzing
each of the problem areas and
recommending coordinated strategies
that, if implemented effectively, will
lead to significant improvements in
safety.
Two of the problems areas are vehicle
rollover and vehicle compatibility. The
reports on those areas identify a series
of vehicle, roadway and behavioral
strategies for addressing the problems.16
Among the vehicle strategies, both
reports identified reform of the CAFE
program as one of the steps that needed
to be taken to reduce those problems:
The current structure of the CAFE system
can provide an incentive to manufacturers to
downweight vehicles, increase production of
vehicle classes that are more susceptible to
rollover crashes, and produce a less
homogenous fleet mix. As a result, CAFE is
critical to the vehicle compatibility and
rollover problems.
Recognizing the role of CAFE, we
stated:
It is NHTSA’s goal to identify and
implement reforms to the CAFE system that
will facilitate improvements in fuel economy
without compromising motor vehicle safety
or American jobs. * * *
* * * NHTSA intends to examine the safety
impacts, both positive and negative, that may
result from any modifications to CAFE as it
now exists. Regardless of the root causes, it
is clear that the downsizing of vehicles that
occurred during the first decade of the CAFE
program had serious safety consequences.
Changes to the existing system are likely to
have equally significant impacts. NHTSA is
determined to ensure that these impacts are
positive.
H. 2003 ANPRM
On December 29, 2003, the agency
published an ANPRM seeking comment
on various issues relating to reforming
the CAFE program (68 FR 74908; Docket
No. 2003–16128).17 The agency sought
comment on possible enhancements to
the program that would assist in further
fuel conservation, while protecting
motor vehicle safety and the economic
vitality of the automobile industry. The
agency indicated that it was particularly
interested in structural reform. That
document, while not espousing any
particular form of reform, sought
specific input on various options aimed
16 See https://www-nrd.nhtsa.dot.gov/vrtc/ca/
capubs/IPTRolloverMitigationReport/; https://wwwnrd.nhtsa.dot.gov/departments/nrd-11/aggressivity/
IPTVehicleCompatibilityReport/.
17 On the same date, we also published a request
for comments seeking manufacturer product plan
information for MYs 2008–2012 to assist the agency
in analyzing possible reforms to the CAFE program
which are discussed in a companion notice
published today. (68 FR 74931) The agency sought
information that would help it assess the effect of
these possible reforms on fuel economy,
manufacturers, consumers, the economy, motor
vehicle safety and American jobs.
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at adapting the CAFE program to today’s
vehicle fleet and needs.
1. Need for Reform
The 2003 ANPRM discussed the
principal criticisms of the current CAFE
program that led the agency to explore
light truck CAFE reform (68 FR 74908,
at 74910–13). First, the energy-saving
potential of the CAFE program is
hampered by the current regulatory
structure. The Unreformed approach to
CAFE does not distinguish between the
various market segments of light trucks,
and therefore does not recognize that
some vehicles designed for
classification purposes as light trucks
may achieve fuel economy similar to
that of passenger cars. The Unreformed
CAFE approach instead applies a single
standard to the light truck fleet as a
whole, encouraging manufacturers to
offer small light trucks that will offset
the larger vehicles that get lower fuel
economy. A CAFE system that more
closely links fuel economy standards to
the various market segments reduces the
incentive to design vehicles that are
functionally similar to passenger cars
but classified as light trucks.
Second, because weight strongly
affects fuel economy, the current light
truck CAFE program encourages vehicle
manufacturers to reduce weight in their
light truck offerings to achieve greater
fuel economy.18 As the NAS report and
a more recent NHTSA study have found,
downweighting of the light truck fleet,
especially those trucks in the low and
medium weight ranges, creates more
safety risk for occupants of light trucks
and all motorists combined.19
Third, the agency noted the adverse
economic impacts that might result from
steady future increases in the stringency
of CAFE standards under the current
regulatory structure. Rapid increases in
the light truck CAFE standard could
have serious adverse economic
consequences. The vulnerability of fullline manufacturers to tighter CAFE
standards does not arise primarily from
poor fuel economy ratings within
weight classes, i.e., from less extensive
use of fuel economy improving
technologies. As explained in the 2003
ANPRM, their overall CAFE averages
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18 Manufacturers
can reduce weight without
changing the fundamental structure of the vehicle
by using lighter materials or eliminating available
equipment or options. In contrast, reducing vehicle
size, and particularly footprint, generally entails an
alteration of the basic architecture of the vehicle.
19 However, both studies also suggest that if
downweighting is concentrated on the heaviest
light trucks in the fleet there would be no net safety
impact, and there might even be a small fleet-wide
safety benefit. There is substantial uncertainty
about the curb weight cut-off above which this
would occur.
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are low compared to manufacturers that
produce more relatively light vehicles
because their sales mixes service a
market demand for bigger and heavier
vehicles capable of more demanding
utilitarian functions. An attribute-based
(weight and/or size) system could avoid
disparate impacts on full-line
manufacturers that could result from a
sustained increase in CAFE standards.
2. Reform Options
In discussing potential changes, the
agency focused primarily on structural
improvements to the current CAFE
program authorized under the current
statutory authority, and secondarily on
definitional changes to the current
vehicle classification system and
whether to include vehicles between
8,500 to 10,000 lbs. GVWR. The NPRM
explored the various reform options
raised in the ANPRM. It is worth noting
again several of those options.
Included in the reform discussion was
an attribute-based ‘‘continuousfunction’’ system, such as that discussed
in the NAS report. We chose various
measures of vehicle weight and/or size
to illustrate the possible design of an
attribute-based system. However, we
also sought comment as to the merits of
using other vehicle attributes as the
basis of an attribute-based system.
The 2003 ANPRM also presented
potential reform options under which
vehicles with a GVWR of up to 10,000
lbs. could be included under the CAFE
program. One presented option would
be to include vehicles defined by EPA
as medium duty passenger vehicles 20
for use in the CAFE program. This
definition would essentially make SUVs
and passenger vans between 8,500 and
10,000 lbs. GVWR subject to CAFE,
while continuing to exclude most
medium- and heavy-duty pickups and
most medium- and heavy-duty cargo
vans that are primarily used for
agricultural and commercial purposes.
Through the 2003 ANPRM, the agency
intended to begin a public discussion on
potential ways, within current statutory
authority, to improve the CAFE program
to better achieve our public policy
objectives. The agency set forth a
number of possible concepts and
measures, and invited the public to
present additional concepts. The agency
expressed interest in any suggestions
toward revamping the CAFE program in
such a way as to enhance overall fuel
economy while protecting occupant
safety and the economic vitality of the
auto market.
20 The EPA’s discussion of the MDPV definition
is at 65 FR 6698, 6749–50, 6851–6852.
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I. Recent developments
1. Factors underscoring need for reform
In the NPRM, we recognized two
important complicating factors that
underscore the need for CAFE reform.
One factor is the fiscal problems
reported by General Motors and Ford,
while the other is the recent surge in
gasoline prices, a development that may
be exacerbating the financial challenges
faced by both companies.
Two of the larger, full-line light-truck
manufacturers, General Motors and
Ford, have reported serious financial
difficulties. The investment community
has downgraded the bonds of both
companies. Further, both companies
have announced significant layoffs and
other actions to improve their financial
condition. While these financial
problems did not give rise to the
Administration’s CAFE reform
initiative, the financial risks now faced
by these companies, including their
workers and suppliers, underscore the
importance to full-line vehicle
manufacturers of establishing an
equitable CAFE regulatory framework.
There has also been a sharp and
sustained surge in gasoline prices since
our last light truck final rule in April
2003 and the December 2003 ANPRM
on CAFE reform. According to the
Energy Information Administration
(EIA), the retail price for gasoline in
April 2003 was $1.59 per gallon and in
December 2003 was $1.48 per gallon.21
When the NPRM was published the
weekly U.S. retail price was $2.55 per
gallon.22 While the retail price of
gasoline has declined since publication
of the NPRM it is still $2.34, which is
$.75 per gallon higher than when the
2003 final rule was published.23
We noted in the NPRM that it is
important to recognize that CAFE
standards for MYs 2008–2011 should
not be based on current gasoline prices.
They should be based on our best
forecast of what average real gasoline
prices will be in the U.S. during the
years that these vehicles will be used by
consumers: The 36-year period
beginning in 2008 and extending to
2034.24 Since miles of travel tend to be
21 See https://tonto.eia.doe.gov/oog/info/gdu/
gaspump.html.
22 See https://www.eia.doe.gov/oil_gas/petroleum/
data_publications/wrgp/mogas_home_page.html
and https://tonto.eia.doe.gov/oog/info/gdu/
gasdiesel.asp.
23 See id.
24 To calculate the fuel savings for the light trucks
manufactured in a model year, we consider the
savings over a 26-year period. The number of light
trucks manufactured during each model year that
remains in service during each subsequent calendar
year is estimated by applying estimates of the
proportion of light trucks surviving to each age up
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concentrated in the early years of a
vehicle’s lifetime, the projected gasoline
price in the 2008–2020 period is
particularly relevant for this
rulemaking.
The Preliminary Regulatory Impact
Analysis (PRIA) for the NPRM was
based on projected gasoline prices from
the then most recent Annual Energy
Outlook 2005 (AEO2005) (published in
2004 before the recent price rises),
which projected gasoline prices ranging
from $1.51 to $1.58 per gallon.25 The
Final Regulatory Impact Analysis (FRIA)
for today’s rule is based on the revised
forecast EIA published in the AEO2006
(Early outlook) (see FRIA p. XIII–26).
The current forecasted price for gasoline
ranges from $1.96 to $2.39 per gallon.26
2. Revised product plans
In response to a request for comment
(RFC) 27 published in conjunction with
the NRPM, the agency has received
updated product plans from the vehicle
manufacturers. While the NPRM was
based on product plans received in
response to the 2003 ANPRM, the final
rule relied on product plans received in
response to the August 2005 RFC.
III. Summary of the NPRM
On August 30, 2005, the agency
published a notice of proposed
rulemaking (NPRM) to establish CAFE
wwhite on PROD1PC61 with RULES2
to 26 years (see Table VIII–2 in the PRIA). At the
end of 26 years, the proportion of light trucks
remaining in service falls below 10 percent.
25 https://www.eia.doe.gov/oiaf/aeo/.
26 The EIA gasoline prices are provided in 2003
dollars. In terms of 2006 dollars (based on the 2003
GDP deflator; see, https://www.gpoaccess.gov/
usbudget/fy05/sheets/hist10z1.xls) the forecasted
range of fuel prices would be $2.04 to 2.49.
27 70 FR 51466; August 30, 2005; Docket No.
NHTSA–2005–22144–03.
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standards for model years (MYs) 2008
through 2011, and more importantly to
reform the CAFE program (70 FR
51414). The NPRM was one piece of the
Department of Transportation’s
continuing effort to achieve higher fuel
savings while enhancing safety and
preventing adverse economic
consequences. We noted that the
previous rulemaking efforts increased
the light truck CAFE standards, from the
‘‘frozen’’ level of 20.7 mpg applicable
from MY 1996 through MY 2004, to a
level of 22.2 mpg applicable to MY
2007. However, in order to continue
moving forward with improved fuel
savings while enhancing safety and
preventing adverse economic
consequences the agency proposed to
reform the light truck CAFE system.
In the NPRM, we proposed fuel
economy standards for light trucks in
MYs 2008–2010, established under the
traditional CAFE system (Unreformed
CAFE system). We also proposed
standards for MYs 2008–2010
established under a proposed reformed
CAFE system (Reformed CAFE). During
MYs 2008–2010, manufacturers would
have an option of complying with
standards established under the
Unreformed or the Reformed CAFE
system. We proposed that this period
would serve as a transition period to
provide manufacturers an opportunity
to adjust to changes in the CAFE system
and to provide this agency and the
manufacturers’ opportunity to gain
experience with the new system. For
MY 2011, we proposed standards
established under Reformed CAFE only.
The Unreformed standards for MYs
2008–2010 were proposed with
particular regard to the capabilities of
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and impacts on the ‘‘least capable’’ fullline manufacturer (a full-line
manufacturer is one that produces a
wide variety of types and sizes of
vehicles) with a significant share of the
market. A single CAFE level, applicable
to each manufacturer, was proposed
each model year as follows:
MY 2008: 22.5 mpg
MY 2009: 23.1 mpg
MY 2010: 23.5 mpg
We estimated that these standards could
save 4.4 billion gallons of fuel over the
lifetime of the vehicles sold during
those model years, compared to the
savings that would occur if the
standards remained at the MY 2007
level of 22.2 mpg.
The proposed Reformed CAFE system
relied on a category and target system in
which the light truck fleet was
segmented according to size and a
manufacturer’s required fuel economy
level would be based on its actual fleet
distribution across the categories as
compared to applicable fuel economy
targets. As proposed, the structure of
Reformed CAFE for each model year
would have three basic elements—
(1)—six footprint 28 categories of
vehicles.
(2)—a target level of average fuel
economy for each footprint category, as
expressed by a step function (The step
or ‘‘staircase’’ nature of the function can
be seen in Figure 1 below.).
(3)—a Reformed CAFE standard based
on the harmonic production-weighted
average of the fuel economy targets for
each category.
28 Footprint is an aspect of vehicle size—the
product of multiplying a vehicle’s wheelbase by its
average track width.
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To define the proposed category
boundaries (step boundaries), we first
plotted the light truck production
volumes by footprint. We then sought to
designate the category boundaries at
points where there was low volume
footprint immediately adjacent to and to
left of a high volume footprint. Our
intent in doing this was to reduce any
incentive for manufacturers to increase
footprint in order to move a model into
a category with a lower fuel economy
target. We sought to create a reasonable
number of categories that would also
combine, to the extent practicable,
similar vehicle types into the same
category. Each category was then
assigned a fuel economy target.
The proposed fuel economy targets
were determined by a three-step
process. First, the agency applied
feasible technology to each of the seven
largest light truck manufacturers’
fleets 29 individually until the marginal
cost of the added technology equaled
the marginal benefit of the additional
technology. Next, initial targets were
determined by placing all of the
improved vehicles into the six
categories and calculating a productionweighted fuel economy average within
each category. Finally, the initial targets
were adjusted by equal increments of
fuel savings to a level at which marginal
cost equaled marginal benefit for
industry as a whole. This final level
provided the targets as proposed, which
would be used to determine a
manufacturer’s required fuel economy
level.
Under the proposed reform, the
required level of CAFE for a particular
manufacturer for a model year would be
calculated after inserting the following
data into the standard for that model
year: that manufacturer’s actual total
production and its production in each
footprint category for that model year.30
The calculation of the required level
would be made by dividing the
manufacturer’s total production for the
model year by the sum of the six
fractions (one for each category)
obtained by dividing the manufacturer’s
production in a category by the
category’s target.
As proposed, a manufacturer’s
required fuel economy was represented
as the following formula:
Manufacturer X’s Total Production of Light Trucks
= X’s required level of CAFE
X’s production in category 1 X’s production in category 2
c
+
+ etc
Target for category 1
Target for category 2
industry-wide cost of those standards
were roughly equivalent to the industrywide cost of the Unreformed CAFE
standards for those model years.
29 The seven largest light truck manufacturers are
General Motors, Ford, DaimlerChrysler, Toyota,
Honda, Hyundai, and Nissan.
30 Since the calculation of a manufacturer’s
required level of average fuel economy for a
particular model year would require knowing the
final production figures for that model year, the
final formal claculation of that level would not
occur until after those figures are submitted by the
manufacturer to EPA. That submission would not,
of course, be made until after the end of that model
year.
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ER06ap06.001</GPH>
Unreformed CAFE. To further ease the
transition, and to ensure that the
Reformed standards were economically
practical, the proposed Reformed CAFE
standards were set at levels at which the
ER06AP06.000</GPH>
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During the MY 2008–2010 transition
period, we proposed that manufacturers
may comply with CAFE standards
established under Reformed CAFE or
with standards established under
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As proposed, all manufacturers would
be required to comply with a Reformed
CAFE standard in MY 2011. The
proposed Reformed CAFE standard for
that model year was set at the level that
maximized net benefits.
Under the NPRM, the range of targets
for each model year was as follows:
MY 2008: From 26.8 mpg for the
smallest vehicles to 20.4 mpg for the
largest;
MY 2009: From 27.4 mpg for the
smallest vehicles to 21.0 mpg for the
largest;
MY 2010: From 27.8 mpg for the
smallest vehicles to 20.8 mpg for the
largest;
MY 2011: From 28.4 mpg for the
smallest vehicles to 21.3 mpg for the
largest
We estimated that the standards based
on these targets would save
approximately 10.0 billion gallons of
fuel over the lifetime of the vehicles
sold during those four model years,
compared to the savings that would
occur if the standards remained at the
MY 2007 level of 22.2 mpg. The
Reformed standards for MYs 2008–2010
were estimated to save 525 million more
gallons of fuel than the Unreformed
standards for those years. We estimated
the proposed MY 2011 standard to save
an additional 2.8 billion gallons of fuel.
We tentatively determined that the
proposed standards under both
Unreformed CAFE and Reformed CAFE
represent the maximum feasible fuel
economy level for each system. In
reaching this conclusion, we balanced
the express statutory factors and other
relevant considerations, such as safety
concerns, effects on employment and
the need for flexibility to transition to a
Reformed CAFE program that can
achieve greater fuel savings in a more
economically efficient way.
The proposed Reformed CAFE
approach incorporated several
important elements of reform suggested
by the National Academy of Sciences in
its 2002 report (Effectiveness and
Impact of Corporate Average Fuel
Economy (CAFE) Standards; NAS
report). The agency outlined four basic
advantages that the proposed Reformed
CAFE approach has over the
Unreformed CAFE approach: enlarged
energy savings, enhanced safety, a more
equitable regulatory framework for
different vehicle manufacturers, and a
more market oriented approach that
more fully respects economic conditions
and consumer choice. Reformed CAFE
forces vehicle manufacturers to ensure
that they are incorporating available
technologies to enhance fuel efficiency
in all the vehicles they produce.
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In addition to the proposed step
function approach, the agency also
discussed a continuous function
approach. We explained that under a
continuous function approach there
would be no categories, but instead each
footprint value would be assigned a fuel
economy target. We provided an
example of a continuous function
standard and requested comment on
such an approach.
Aside from proposing structural
changes to the CAFE program, the
agency also discussed the potential of
expanding the applicability of the
program to include heavier and heavier
rated light trucks in MY 2011. The
agency requested comment on the
inclusion of vehicles classified by the
Environmental Protection Agency (EPA)
as medium duty passenger vehicles
(MDPVs) 31 in the light truck CAFE
program.
Along with soliciting comment on the
CAFE proposal, the agency also
requested updated product plan
information and other data to assist in
developing a final rule. We noted that
based on public comments and other
information, new data and analysis, and
updated product plans, the standards
adopted in the final rule could well be
different then those proposed.
IV. Summary of Public Comments
NHTSA received over 45,000
individual submissions to the
rulemaking docket prior to the close of
the comment period, including ones
from vehicle manufacturers and
associations, environmental and
consumer advocacy groups, members of
Congress, and private individuals. The
vast majority of the submissions were
letters or e-mails prepared by various
organizations and submitted by private
individuals to the docket.
Light truck manufacturers and their
trade associations that commented on
the proposal included General Motors
Corporation (Docket No. 2005–22223–
1493), Ford Motor Company (Docket No.
NHTSA–2005–22223–1570),
31 In 40 CFR 86–1803–01, EPA defines ‘‘MPDV’’
as a light truck rated at more than 8,500 lbs GVWR,
or that has a vehicle curb weight of more than 6,000
pounds, or that has a basic vehicle frontal area in
excess of 45 square feet. ‘‘MDPV’’ does not include
a vehicle that:
Is an ‘‘incomplete truck’’ as defined in this
subpart; or
Has a seating capacity of more than 12 persons;
or
Is designed for more than 9 persons in seating
rearward of the driver’s seat; or
Is equipped with an open cargo area (for example,
a pick-up truck box or bed) of 72.0 inches in
interior length or more. A covered box not readily
accessible from the passenger compartment will be
considered an open cargo area for purposes of this
definition.
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DaimlerChrysler (Docket No. 20005–
22223–1573), Toyota (Docket No.
NHTSA–2005–22223–1724), Honda
(Docket No. NHTSA–2005–22223–
1649), Nissan (Docket No. NHTSA–
2005–22223–2058), Mitsubishi Motor
Company (Docket No. NHTSA–2005–
22223–1819), Hyundai (Docket No.
NHTSA–2005–22223–2035), Porsche
(Docket No. NHTSA–2005–22223–
1688), BMW of North America (Docket
No. NHTSA–2005–22223–1616),
Volkswagen of North America (Docket
No. NHTSA–2005–22223–1674), the
Alliance of Automobile Manufacturers
(Alliance; Docket No. NHTSA–2005–
22223–1642), and the Association of
International Automobile Manufacturers
(Docket No. NHTSA–2005–22223–
1645).
Manufacturers generally agreed that
distinguishing vehicles within the light
truck fleet according to a size metric,
i.e., footprint, adequately recognized
differences in manufacturers’
compliance efforts due to differences in
fleet mix. They stated that step-function
standard based on footprint would
provide manufacturers greater flexibility
in complying with the CAFE
requirements while at the same time,
address safety concerns associated with
the program. Contrary to their general
support for the proposed step function
standard, manufacturers expressed
reservations with a continuous function
standard as discussed in the NPRM.
Manufacturers stated that a continuous
function standard would be overly
complex to administer and with which
to comply.
While manufacturers expressed
general support for the structure of the
proposed Reformed CAFE,
manufacturers generally expressed
concern with the process, as well as the
assumptions relied upon in that process,
used to define the Reformed CAFE
standards. Manufacturers argued that
the agency’s reliance on a cost-benefit
analysis to determine the stringency of
the light truck CAFE standards did not
adequately account for the capabilities
of the industry, and in some instances
would not satisfy the ‘‘economic
practicability’’ consideration required
under EPCA. Additionally,
manufacturers took issue with the
economic and technological
assumptions employed in the Reformed
CAFE analysis, as well as in the
Unreformed CAFE analysis.
Manufacturers asserted that the agency
did not properly account for
technological and market risks that have
the potential to render the standards
infeasible.
With regard to the applicability of the
light truck CAFE program, the vehicle
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manufacturers generally opposed
including vehicles with a GVWR greater
than 8,500 lbs in the light truck
program. Manufacturers asserted that
standards were not practical for these
vehicles; these vehicles are used in a
substantially different manner than
lighter vehicles, making the CAFE
standards inappropriate; and that
regulation of these vehicles would not
result in significant fuel savings.
Environmental, consumer and safety
advocacy groups commenting on the
proposal included Environmental
Defense (Docket No. NHTSA–2005–
22223–1491, 1698–1703, 1805), Natural
Resource Defense Council (NRDC;
Docket No. NHTSA–2005–22223–1705
through 1710), the Union of Concerned
Scientists (Docket No. NHTSA–2005–
22223–1977, 1978), the Insurance
Institute for Highway Safety (IIHS;
Docket No. NHTSA–2005–22223–2082),
Center for Biological Diversity (Docket
No. NHTSA–2005–22223–1638 through
1641), National Environmental Trust
(Docket No. NHTSA–2005–22223–1483,
1484), Sierra Club (Docket No. NHTSA–
2005–22223–1623), U.S. PIRG (Docket
No. NHTSA–2005–22223-1623),
Alliance to Save Energy—American
Council for an Energy-Efficient
Economy (ACEEE; (Docket No. NHTSA–
2005–22223–1711), the American
Jewish Committee (Docket No. NHTSA–
2005–22223–1420), Alliance for
Affordable Energy et al. (Docket No.
NHTSA–2005–22223–1726),32 AAA
(Docket No. NHTSA–2005–22223–
1804), and Public Citizen (Docket No.
NHTSA–2005–22223–2188, 2189).
In general, the environmental and
consumer groups stated that the
increased fuel prices, the need of the
nation to conserve energy and the
availability of ‘‘effective technologies’’
necessitate more stringent standards.
Several of these commenters stated that
the light truck standard should
approach that for passenger cars or
higher. These groups generally asserted
that any reform proposal must include
a mechanism to guarantee the fuel
savings projected by the agency under
the new standards. Many of these
groups expressed concern that the
proposed structure and reliance on
vehicle footprint in the Reformed CAFE
system would permit manufacturers to
32 Signatories to the Alliance for Affordable
Energy et al., included representatives from
Environmental and Energy Study Group,
Environmental Energy Solutions, Global
Possibilities, Institute for Environmental Research
Education, Mainstay Energy, National
Environmental Trust, North Carolina Solar Center,
Oregon Environmental Council, Redwood Alliance,
The Stella Group, Ltd., SUN DAY Campaign,
SustainableBusiness.com, Triangle Clean Cities
Coalition, and Vermont Energy Investment Corp.
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‘‘upsize’’ their fleets, which would
result in reduced fuel savings. Several
commenters stated that the statutory
requirement to set ‘‘maximum feasible’’
standards makes it impermissible for the
agency to limit the level of the new
standards based on the concepts of
‘‘optimal economic efficiency’’ or ‘‘least
capable manufacturer.’’ They argued
that setting the Reformed CAFE
standards during the transition period at
levels that impose the same costs as the
Unreformed standards was inconsistent
with the ‘‘maximum feasible’’
requirement. Additionally, some of
these groups disagreed with the
agency’s statement regarding the
preemption of State regulation of
greenhouse gas emissions from motor
vehicles. The Center for Biological
Diversity asserted that the
accompanying draft Environmental
Assessment was inadequate.
IIHS expressed concern that the
category system as proposed would
provide an incentive for unsafe
compliance strategies. IIHS stated that
the category system still provided an
incentive to downsize a vehicle within
a category in order to improve its fuel
economy. IIHS stated that downsizing,
particularly among the smaller vehicles,
can have a negative impact on safety. To
address this issue, IIHS recommended
that the agency adopt a continuous
function approach as discussed in the
NPRM.
A number of comments representing
the interests of States were received.
These comments generally voiced
opposition to various parts of the
NPRM. The New York State Department
of Environmental Conservation (NY
DEC; Docket No. NHTSA–22223–1646),
the State of New Jersey Department of
Environmental Protection (Docket No.
NHTSA–22223–1651), NESCAUM 33
(Docket No. NHTSA–22223–1625), the
Pennsylvania Department of
Environmental Protection (PA DEP;
Docket No. NHTSA–22223–1807), the
California Air Resources Board (Docket
No. NHTSA–22144–31), STAPPA/
ALAPCO 34 (Docket No. NHTSA–
22223–1494), and the Connecticut
Department of Environmental Protection
(Docket No. NHTSA–22223–1624)
disagreed with the statement in the
NPRM preamble about preemption of
State greenhouse gas regulations for
motor vehicles and requested that not
33 NESCAUM (Northeast States for Coordinated
Air Use Management) is an interstate association of
air quality control divisions representing the six
New England States, as well as New York and New
Jersey.
34 State and Territorial Air Pollution Program
Administrators and the Association of Local Air
Pollution Control Officials.
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include any such statement in the final
rule. These commenters generally also
requested that the agency increase the
stringency of the final fuel economy
requirements as well as regulate the fuel
economy of light trucks with a GVWR
up to 10,000 lbs. The Attorneys General
for California, Massachusetts, New
York, Connecticut, New Jersey, Maine,
Oregon, Vermont, and the New York
City Corporation Counsel (Attorneys
General; Docket No. NHTSA–22223–
2223) also objected to the preemption
language, and further stated that the
agency is obligated to perform an
environmental impact statement under
the National Environmental Policy Act.
The California Energy Commission
expressed support for the Reformed
CAFE structure, but stated that, because
of uncertainty in the economic
assumptions relied upon by the agency,
standards should be established at this
time for model year 2008 only (Docket
No. NHTSA–22144–19).
Members of Congress also submitted
comment, expressing concern over the
proposal. A letter signed by
Representatives Tammy Baldwin, Jim
McDermott, Susan Davis, Raul Grijalva,
Barbara Lee, Michael Michaud, Ed Case,
Robert Wexler, Pete Stark, Dennis
Cardoza, Allyson Y. Schwartz, and Jim
Moran stated that the proposal contains
a number of positive aspects,
particularly the use of footprint instead
of weight as the basis for Reformed
CAFE (Docket No. NHTSA–22223–
1334). However, Representative
Baldwin et. al asked that the agency
establish more stringent standards and
establish standards for vehicles with a
GVWR between 8,500 and 10,000 lbs,
stating that such revisions are necessary
to reduce the nation’s demand for
foreign oil and to lower gasoline costs
for consumers.
Comments were also received from a
variety of additional organizations and
interests. The Competitive Enterprise
Institute (Docket No. NHTSA–22223–
1682) commented that the proposal
would provide more flexibility to
manufacturers and be more
accommodating to consumer preference,
but argued that increased CAFE
standards have the potential to affect
motor vehicle safety adversely. The
Mercatus Center (Docket No. NHTSA–
22223–1632) and Criterion Economics
(Docket No. NHTSA–22223–1976)
raised concerns relating to many of the
analytic assumptions used in the
preliminary regulatory impact analysis.
The Sport Utility Vehicle Owners of
America (Docket No. NHTSA–22223–
1599) and Marine Retailers Association
of America (Docket No. NHTSA–22223–
84) argued that there was a need to
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consider the utility of light trucks,
particularly towing capacity.
As stated above, the vast majority of
comments received were submitted by
individual citizens. Private individuals
expressed concern that the proposed
standards would not be sufficient to
meet the nation’s need to conserve
energy, would not protect the nation
from future spikes in fuel prices, would
negatively impact the environment, and
would encourage manufacturers to build
larger vehicles with lower fuel
economy.
NRDC provided citizens with a letter
requesting that the agency increase the
light truck standard by 1 mpg a year
over five years. These letters raised
concern that the fuel economy standards
as proposed would not adequately
address the nation’s need to conserve
fuel.
The Union of Concerned Scientists
also provided citizens with form letters
that requested the agency to regulate
vehicles with a GVWR greater than
8,500 lbs, to consider ‘‘cost-efficient
technologies’’ for ‘‘mid-size SUVs,’’ and
to provide a mechanism to ensure that
manufacturers do not ‘‘up-size’’
vehicles. Other similar documents were
also submitted to the docket.
Some expressed belief that sufficient
technology is available that would
enable the manufacturers to exceed the
proposed CAFE standards.
While the above discussion very
briefly describes the comments
submitted by the various interested
parties, more detailed discussions of the
comments and the agency’s responses
are embedded in the analysis and
discussion which follow.
V. The Unreformed CAFE Standards for
MYs 2008–2010
The agency is establishing
Unreformed CAFE standards of 22.5
miles per gallon (mpg) for model year
(MY) 2008, 23.1 mpg for MY 2009, and
23.5 mpg for MY 2010. We estimate that
these standards will save 4.4 billion
gallons of fuel over the lifetime of
vehicles sold during those model years,
compared to the savings that would
occur if the standards remained at the
MY 2007 level of 22.2 mpg. We have
determined that these requirements
represent the maximum feasible fuel
economy levels achievable by industry
in those model years.
Consistent with the NPRM, the
Unreformed CAFE standards in MYs
2008–2010 are one option for
compliance during a transition period in
which manufacturers may comply with
either the Reformed or Unreformed
CAFE systems. During the transition
period, the requirements under the
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Reformed CAFE systems are linked to
those of the Unreformed system, in the
sense that the Reformed CAFE standards
for MYs 2008–2010 are set at levels
intended to ensure that the industrywide cost of the Reformed standards are
roughly equivalent to the industry-wide
cost of the Unreformed CAFE standards
in those model years.
As stated in the NPRM, this transition
approach has several important
advantages. We have determined the
Unreformed standards to be
economically practicable. The Reformed
standards spread the cost burden across
the industry to a greater extent. As such,
equalizing the cost between the
Unreformed and the Reformed CAFE
systems ensures that the costs
associated with the transition period do
not result in economically severe
compliance requirements. Further, this
approach promotes an orderly and
effective transition to the Reformed
CAFE system since experience will be
gained prior to MY 2011. In this section,
we describe how we developed the
Unreformed CAFE standards.
In arriving at the Unreformed CAFE
standards, we used the same type of
analyses as in the NPRM and as we
employed in establishing light truck
CAFE standards for MYs 2005–2007.
First, we analyzed the confidential
product planning data submitted by the
manufacturers to ascertain the
‘‘baseline’’ capabilities and fuel
economy of each manufacturer that has
a significant share of the light truck
market. Second, we conducted a threestage manual engineering analysis (the
Stage Analysis), in conjunction with a
computer-based engineering analysis
(the Volpe Analysis), to determine what
technologies each company with a
significant share of the market could use
to enhance its overall fleet fuel economy
average. In order to perform the two
analyses, the agency relied on the
National Academy of Sciences (NAS)
report entitled, ‘‘Effectiveness and
Impact of Corporate Average Fuel
Economy (CAFE) Standards,’’ which
contains costs and effectiveness
estimates for various technologies that
could be used to enhance vehicle fuel
economy.
As explained in the August 2005
NPRM,35 the Stage Analysis involves
application of the agency’s engineering
expertise and judgment about possible
adjustments to the detailed product
plans submitted by individual
manufacturers. More specifically, Stage
I analysis involves the application of
technologies which are deemed to be
available for use by MY 2008 and which
35 70
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17579
would not require significant changes to
the vehicle’s driveline components (i.e.,
the engine and transmission). Stage II
analysis involves the application of
more advanced transmission upgrades
and engine improvements that are
readily available in the marketplace.
Stage III analysis involves the
application of diesel and hybrid
powertrains to select products.
The Volpe Analysis was described in
detail in the NPRM and Final Rule
establishing light truck CAFE standards
for MYs 2005–2007.36 The Volpe
analysis uses a technology application
algorithm to systematically apply
consistent cost and performance
assumptions to the entire industry, as
well as consistent assumptions
regarding economic decision-making by
manufacturers. The resultant computer
model (the CAFE Compliance and
Effects Model), developed by technical
staff of the DOT Volpe National
Transportation Systems Center in
consultation with NHTSA staff, is used
to help estimate the overall economic
impact of the Unreformed CAFE
standards. The Volpe analysis shows the
economic impact of the standards in
terms of increases in new vehicle prices
on a manufacturer-wide, industry-wide,
and average per-vehicle basis. Based on
these estimates and corresponding
estimates of net economic and other
benefits, the agency is able to set the
standards that are economically
practicable and technologically feasible.
The Stage Analysis and the Volpe
Analysis rely on the same product plan
information from manufacturers,
consider many of the same technologies
(the Stage Analysis considers some
manufacturer-specific technologies not
represented in the Volpe Analysis), and
apply similar conditions regarding the
applicability of those technologies.
We note that the Volpe model has
been updated and refined with respect
to its representation of some fuel-saving
technologies, but remains
fundamentally the same. The updated
model has also been peer reviewed.37
The model documentation, including a
description of the input assumptions
and process, as well as peer review
reports and the agency’s response to
reviewers, were made available in the
rulemaking docket for the August 2005
NPRM.38
We received a significant number of
comments in response to the proposed
36 See 67 FR 77015 (December 16, 2002) and 68
FR 16868 at 16871 (April 7, 2003). Docket Nos.
NHTSA–2002–11419–55 and NHTSA–2002–11419–
18361.
37 The agency’s response to the peer review is
provided in the docket at NHTSA–2005–22223–52.
38 See Docket Nos. NHTSA–20005–22223–3, 4, 5.
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Unreformed CAFE standards, expressing
a wide range of views. While some of
those commenting argued that
technology is available to set the
standards higher, others argued that
insufficient lead time, as well as
technological and monetary constraints,
make it unlikely that the proposed
standards would be attainable. We have
reviewed these comments and adjusted
many aspects of the analyses used to
determine the Unreformed CAFE
standards in order to account for issues
brought to our attention. Responses to
comments that raised specific
technology and economic assumptions
issues are discussed in detail below in
sections VIII. Technology issues, and IX.
Economic Assumptions
In the balance of this section, we
describe in further detail how we
developed the Unreformed CAFE
standards. After considering the
foregoing and taking into consideration
the statutory criteria specified in 49
U.S.C. 32092(f) 39, we are adopting the
Unreformed CAFE standards specified
above, having concluded that they
constitute the maximum feasible
standards for MYs 2008–2010.
A. Legal Authority and Requirements
Under EPCA
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As previously stated, EPCA requires
that the CAFE standards set a minimum
performance standard at a level
determined by the Secretary of
Transportation to be the ‘‘maximum
feasible’’ average fuel economy
achievable by manufacturers in a given
model year (49 U.S.C. 32902). To guide
determinations of the maximum feasible
fuel economy level, Congress specified
four statutory criteria that must be
considered: technological feasibility,
economic practicability, the effect of
other Federal motor vehicle standards
on fuel economy, and the need of the
United States to conserve energy. The
agency is permitted to consider
additional societal considerations and
historically has considered the potential
for adverse safety consequences when
deciding upon a maximum feasible
level.40 The overarching principle that
39 The statutory criteria, which are addressed
elsewhere in this document, are: (1) The nation’s
need to conserve energy; (2) technological
feasibility; (3) economic practicability (including
employment consequences); and the impact of other
regulations on fuel economy.
40 See, e.g., Center for Auto Safety v. NHTSA
(CAS), 793 F. 2d 1322 (D.C. Cir. 1986)
(Administrator’s consideration of market demand as
component of economic practicability found to be
reasonable); Public Citizen 848 F.2d 256 (Congress
established broad guidelines in the fuel economy
statute; agency’s decision to set lower standard was
a reasonable accommodation of conflicting
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emerges from the enumerated factors
and the court-sanctioned practice of
considering safety and links them
together is that CAFE standards should
be set at a level that will achieve the
greatest amount of fuel savings without
leading to significant adverse societal
consequences.
We have set the Unreformed
standards with particular regard to the
‘‘least capable manufacturer with a
significant share of the market,’’ in
response to the direction in the
conference report on the CAFE statute
language to consider industry-wide
considerations, but not necessarily base
the standards on the manufacturer with
the greatest compliance difficulties.41
This approach is consistent with the
Conference Report on the legislation
enacting the CAFE statute:
Such determination [of maximum feasible
average fuel economy level] should take
industry-wide considerations into account.
For example, a determination of maximum
feasible average fuel economy should not be
keyed to the single manufacturer that might
have the most difficulty achieving a given
level of average fuel economy. Rather, the
Secretary must weigh the benefits to the
nation of a higher average fuel economy
standard against the difficulties of individual
manufacturers. Such difficulties, however,
should be given appropriate weight in setting
the standard in light of the small number of
domestic manufacturers that currently exist
and the possible implications for the national
economy and for reduced competition
association [sic] with a severe strain on any
manufacturer.
S. Rep. No. 94–516, 94th Congress, 1st
Sess. 154–155 (1975). The agency must
consider the industry’s ability to
improve fuel economy, but with
appropriate consideration given to the
difficulties of individual manufacturers.
In response to this congressional
direction, we have traditionally given
particular regard to the ‘‘least capable
manufacturer with a substantial share of
the market.’’ The agency must take
particular care in considering the
statutory factors with regard to these
manufacturers— weighing their asserted
capabilities, product plans and
economic conditions against agency
projections of their capabilities, the
policies). As the United States Court of Appeals
pointed out in upholding NHTSA’s exercise of
judgment in setting the 1987–1989 passenger car
standards, ‘‘NHTSA has always examined the safety
consequences of the CAFE standards in its overall
consideration of relevant factors since its earliest
rulemaking under the CAFE program.’’ Competitive
Enterprise Institute v. NHTSA (CEI I), 901 F.2d 107,
120 at n.11 (D.C. Cir. 1990).
41 ‘‘Least capable manufacturer’’ is something of
a misnomer as a major manufacturer could install
substantial amounts of fuel saving technologies and
still be the major manufacturer with lowest
projected CAFE due to its mix of vehicles.
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need for the nation to conserve energy
and the effect of other regulations
(including motor vehicle safety and
emissions regulations) and other public
policy objectives.
The agency has historically assessed
whether a potential CAFE standard is
economically practicable in terms of
whether the standard is one ‘‘within the
financial capability of the industry, but
not so stringent as to threaten
substantial economic hardship for the
industry.’’ 42 See, e.g., Public Citizen,
848 F.2d at 264. In essence, in
determining the maximum feasible level
of CAFE, the agency assesses what is
technologically feasible for
manufacturers to achieve without
leading to significant adverse economic
consequences, such as a significant loss
of jobs or the unreasonable elimination
of consumer choice.
At the same time, the law does not
preclude a CAFE standard that poses
considerable challenges to any
individual manufacturer. The
Conference Report makes clear, and the
case law affirms: ‘‘(A) determination of
maximum feasible average fuel economy
should not be keyed to the single
manufacturer which might have the
most difficulty achieving a given level
of average fuel economy.’’ CAS, 793
F.2d at 1338–39. Instead, the agency is
compelled ‘‘to weigh the benefits to the
nation of a higher fuel economy
standard against the difficulties of
individual automobile manufacturers.’’
Id. The statute permits the imposition of
reasonable, ‘‘technology forcing’’
challenges on any individual
manufacturer, but does not contemplate
standards that will result in ‘‘severe’’
economic hardship by forcing
reductions in employment affecting the
overall motor vehicle industry.43
42 In adopting this interpretation in the final rule
establishing the MY 1981–1984 fuel economy
standards for passenger cars (June 30, 1977; 42 FR
33534, at 33536–7), the Department rejected several
more restrictive interpretations. One was that the
phrase means that the standards are statutorily
required to be set at levels solely on a cost-benefit
basis. The Department pointed out that Congress
had rejected a manufacturer-sponsored amendment
to the Act that would have required standards to be
set at a level at which benefits were commensurate
with costs. It also dismissed the idea that economic
practicability should limit standards to free market
levels that would be achieved with no regulation.
43 In the past, the agency has set CAFE standards
above its estimate of the capabilities of a
manufacturer with less than a substantial, but more
than a de minimis, share of the market. See, e.g.,
CAS, 793 F.2d at 1326 (noting that the agency set
the MY 1982 light truck standard at a level that
might be above the capabilities of Chrysler, based
on the conclusion that the energy benefits
associated with the higher standard would
outweigh the harm to Chrysler, and further noting
that Chrysler had 10–15 percent market share while
Ford had 35 percent market share). On other
occasions, the agency reduced an established CAFE
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By focusing primarily on the least
capable manufacturer with a significant
share of the market, this approach has
ensured that the standards are
technologically feasible and
economically practicable for
manufacturers with a significant share
of the market. If a standard is
technologically feasible and
economically practicable for the ‘‘least
capable’’ manufacturer, it can be
presumed to be so for the ‘‘more
capable’’ manufacturers. Together, the
manufacturers with a significant share
of the market represented a very
substantial majority of the light trucks
manufactured and thus were deemed to
represent ‘‘industry-wide
considerations.’’
B. Establishing Unreformed Standards
According to EPCA—Process for
Determining Maximum Feasible Levels
In establishing the Unreformed
standards for MYs 2008–2010, the
agency relied upon its historical
standard setting process, which
includes consideration of the ‘‘least
capable manufacturer with a significant
share of the market.’’
NRDC, Environmental Defense and
the Union of Concerned Scientists
stated that the ‘‘least capable
manufacturer’’ approach applied by the
agency in setting standards under the
Unreformed CAFE standards violates
EPCA and Congress’ expressed intent.
NRDC argued that ‘‘while the agency is
permitted to consider the single, least
capable manufacturer in assessing
economic practicability, it simply may
not allow that manufacturer’s
capabilities to drive the standard setting
process,’’ and referred to CAS.
In CAS, the petitioners alleged that
the agency had given ‘‘impermissible
weight to shifts in consumer demand
toward larger, less fuel-efficient
trucks’’44 in reducing the MY 1985
standard for light trucks and in
establishing the MY 1986 standard for
light trucks. In reducing the MY 1985
standard as well as in establishing the
MY 1986 one, NHTSA considered the
impacts of different levels of standards
on the least capable manufacturer. The
Court noted the conference report for
EPCA ‘‘states that the fuel economy
standards delegated to NHTSA are to be
the product of balancing the benefits of
higher fuel economy levels against the
difficulties individual manufacturers
would face in achieving those levels,’’45
Then it quoted language to that effect
from the conference report. In the end,
the Court upheld the standards
established through consideration of the
least capable manufacturer with a
significant share of the market, stating
that ‘‘a standard with harsh economic
consequences for the auto[mobile]
industry * * * would represent an
unreasonable balancing of EPCA’s
policies.’’46
As a first step toward ensuring that
the CAFE levels selected as the
maximum feasible levels under
Unreformed CAFE will not lead to
significant adverse consequences, we
reviewed in detail the confidential
product plans provided by the
manufacturers with a substantial share
of the light truck market (General
Motors, Ford and DaimlerChrysler) and
all other manufacturers that submitted
confidential product plan data and
assessed their technological capabilities
to go beyond those plans. By doing so,
we are able to determine the extent to
which each can enhance their fuel
economy performance using technology.
C. Baseline for Determining
Manufacturer Capabilities in MYs 2008–
2010
In order to determine the maximum
feasible fuel economy levels for MYs
2008–2010 under the Unreformed CAFE
system, we first determined each
manufacturer’s fuel economy baselines
for MYs 2008–2010. That is, we
determined the fuel economy levels that
manufacturers were planning to achieve
in those years.
The manufacturer baselines relied
upon for the proposed Unreformed
17581
CAFE standards were based upon
information submitted by manufacturers
in response to the December 29, 2003
request for product plans 47, and any
additional manufacturer updates. In
conjunction with the August 2005
NPRM, we issued a RFC seeking
updated product plans to enable
NHTSA to use the most accurate and
up-to-date product plan information in
establishing the Reformed and
Unreformed CAFE standards.48
In response to the RFC, we received
product plans from DaimlerChrysler,
Ford, General Motors, Honda, Hyundai,
Mitsubishi, Nissan, Subaru and Toyota.
To supplement the data provided in
response to the RFC, we also relied on
product data available from public
sources. Taken together, it was this
updated information that the agency
used in development of the standards
for today’s final rule.
We note that BMW, Porsche, and
Volkswagen previously paid fines in
lieu of complying with the MY 2002 and
2003 light truck CAFE standards. The
agency assumes that because of that past
history and their low light truck
production volumes Porsche and
Volkswagen will continue to pay fines
instead of bringing their fleets into
compliance. For purpose of the NPRM,
we also assumed that BMW would
continue to pay fines. However, BMW
has indicated that it does not intend to
pay fines in the model years subject to
this rulemaking. We have adjusted our
analysis accordingly.
Finally, in response to a comment
from DaimlerChrysler, we removed
Mitsubishi’s information from
DaimlerChrysler’s product plans due to
DaimlerChrysler’s recent sale of its
entire share of Mitsubishi stock and
adjusted DaimlerChrysler’s baseline
capabilities accordingly.
Based on the updated manufacturer’s
responses and the available public data,
we determined the baseline capabilities
as follows:
TABLE 1.—ESTIMATED MARKET SHARES AND PLANNED CAFE LEVELS (WITHOUT CREDITS)
Market
share*
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Manufacturer
General Motors ........................................................................................................
Ford ..........................................................................................................................
DaimlerChrysler .......................................................................................................
Toyota ......................................................................................................................
Honda ......................................................................................................................
Nissan ......................................................................................................................
standard to address unanticipated market
conditions that rendered the standard unreasonable
and likely to lead to severe economic consequences.
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25.8
19.4
23.0
11.6
6.5
5.7
49 FR 41250, 50 FR 40528, 53 FR 39275; see Public
Citizen, 848 F.2d at 264.
44 Id. at 1323–4.
45 Id. at 1338.
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MY 2008
(mpg)
21.36
21.53
21.96
22.51
24.56
21.01
46 Id.
MY 2009
(mpg)
21.43
21.79
22.01
22.44
24.56
20.70
MY 2010
(mpg)
21.59
22.65
22.42
22.65
24.56
21.13
at 1340.
68 FR 74931; see also Docket No. NHTSA–
2003–16709–1.
48 See Docket No. NHTSA–2005–22144.
47 See
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TABLE 1.—ESTIMATED MARKET SHARES AND PLANNED CAFE LEVELS (WITHOUT CREDITS)—Continued
Market
share*
Manufacturer
Hyundai ....................................................................................................................
Subaru .....................................................................................................................
BMW ........................................................................................................................
Porsche ....................................................................................................................
Isuzu ........................................................................................................................
Suzuki ......................................................................................................................
Volkswagen ..............................................................................................................
Mitsubishi .................................................................................................................
MY 2008
(mpg)
3.6
1.1
0.8
0.2
0.4
0.3
0.3
1.3
23.22
25.87
21.29
16.80
20.38
21.93
18.78
24.33
MY 2009
(mpg)
23.49
27.15
21.29
16.80
20.24
21.93
18.78
24.41
MY 2010
(mpg)
23.36
27.05
21.29
16.80
20.14
21.93
18.78
24.70
*Based on 2005 production data.
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After ascertaining the baseline
capabilities of individual
manufacturers, the agency applied the
Stage analysis to analyze the potential
technological improvements to the
product offerings for each manufacturer
with a substantial share of the light
truck market, as well as for the
remaining light truck manufacturers.49
The Alliance and Ford argued that in
establishing manufacturer baselines for
our analysis, the agency erroneously
assumed that each manufacturer’s fleet
average would be at 22.2 mpg for Model
Year 2007. These commenters stated
that this assumption is incorrect,
because some manufacturers did not
submit product plan information to
support this assumption and other
manufacturers achieve compliance with
the CAFE requirements through the use
of credits and payment of fines. The
Alliance and Ford also stated that some
manufacturers (in anticipation of future
CAFE increases) might have taken steps
in support of higher fleet averages and
might have already incorporated fuel
saving technologies.
In response, we note that the agency
did not assume that each manufacturer’s
fleet average would be 22.2 mpg for MY
2007. We used the manufacturer’s plans
to determine the fleet average. When a
manufacturer’s plans were below 22.2
mpg, we estimated the technologies and
costs necessary to bring their fleet
average up to a 22.2 mpg baseline.
These costs were assigned to the MY
2007 standards, and such costs were not
included in the costs for MY 2008.
With respect to alternative fuel
vehicles, we note that manufacturers
may improve their calculated fuel
49 A more detailed discussion of these issues is
contained in the Chapter VI of the FRIA, which has
been placed in the docket for this notice. Some of
the information included in the FRIA, including the
details of manufacturers’ future product plans, has
been determined by the Agency to be confidential
business information, the release of which could
cause competitive harm. The public version of the
FRIA omits the confidential information. The FRIA
also discusses in detail the fuel-economy-enhancing
technologies expected to be available during the
MY 2008–2011 time period.
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economy performance by placing these
vehicles into the market through MY
2012.50 However, 49 U.S.C. 32902(h)
prohibits us from taking such benefits
into consideration in determining the
maximum feasible fuel economy
standard. Accordingly, the baseline
projections cannot reflect those
credits.51
D. Technologically Feasible Additions to
Product Plans
As explained in the August 2005
NPRM, we performed a Stage analysis to
determine what fuel-saving technologies
could be applied to a manufacturer’s
baseline. At each of the three stages, we
add technologies based on our
engineering judgment and expertise
about possible adjustments to the
detailed product plans submitted by the
manufacturers. Our decision on whether
and when to add a technology reflects
our consideration of the practicability of
applying a specific technology and the
necessity for sufficient lead-time in its
application. In addition to considering
lead time and practicability, the agency
adds technologies in a cost-minimizing
fashion. That is, we add technologies in
order of lower to higher costs as
explained in the FRIA (see FRIA p. VI–
13).
While technologies are applied in
order of ‘‘effective cost,’’ the level of
technology added to a manufacturer’s
fleet is based on the agency’s
engineering expertise. Technologies are
not added until net benefits are
maximized as under the Reformed
CAFE system. Instead, the agency uses
engineering expertise to apply
technology. We impose phase-in caps
for applications of technology over time
and do not make significant changes
50 The applicability of the alternative fuel
provision in § 32905 was extended in the Energy
Policy Act of 2005 (Pub. L. 109–58).
51 Sec. 32902(h) states that when establishing fuel
economy standards, the agency:
(1) May not consider the fuel economy of
dedicated automobiles; and
(2) Shall consider dual fueled automobiles to be
operated only on gasoline or diesel fuel.
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until a vehicle is refreshed or
redesigned to account for product
cycles. As such, the price of fuel does
not directly factor into the application
of technology under the Unreformed
CAFE system to the degree that it does
under the Reformed CAFE system.
New product plan data in response to
the NPRM indicated that manufacturers
had shifted the fleet mix and improved
the fuel economy of some vehicles.
These changes reduced the amount of
technology available to be applied. For
this reason, more costly technologies
(diesel and hybrids) were projected onto
the fleet. The agency feels justified in
doing so because higher gasoline prices
will increase the demand for these types
of technologies.
In evaluating which technologies to
apply, and the sequence in which to
apply them, we follow closely the NAS
report. The NAS report estimated the
incremental benefits and the
incremental costs of technologies that
may be applicable to actual vehicles of
different classes and intended uses.52
The NAS report also identified what it
called ‘‘cost-efficient technology
packages’’ (i.e., combinations of
technologies that would result in fuel
economy improvements sufficient to
cover the purchase price increases that
such technologies would require).53
The Stage I analysis includes
technologies that are available for use by
MY 2008, but that some manufacturers
are not currently choosing to use in
their product plans or are using in a
limited manner. However, many of
these technologies are currently being
used in today’s light truck fleet. They
include non-powertrain applications
such as low-rolling-resistance tires, lowfriction lubricants, aerodynamic drag
reduction, and electric-power steering
pumps.
52 See NAS Report at p. 40. See also Docket No.
2005–22223–10, ‘‘Fuel Economy Potential of 2010
Light Duty Trucks.’’ This document was prepared
under the auspices of the U.S. Department of
Energy for NHTSA, in order to update the estimates
provided by the 2001 NAS Report.
53 See NAS Report at p. 64.
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The Stage II analysis includes two
major categories of technological
improvements to the manufacturers’
fleets. The first category is transmission
improvements, which includes the
introduction and expanded use of 5speed and 6-speed transmissions and
continuously variable transmissions
(CVTs). The second category is engine
improvements, which includes
gradually upgrading light truck engines
to include multi-valve overhead
camshafts; introducing engines with
more than 2 valves per cylinder;
applying variable valve timing or
variable valve lift and timing to multivalve overhead camshaft engines; and
applying cylinder deactivation to 6- and
8-cylinder engines.
The Stage III analysis includes
projections of the potential CAFE
increase that could result from the
application of diesel engines and hybrid
powertrains to select products. Both
diesel engines and hybrid powertrains
appear in several manufacturers plans
within the MY 2008–2010 timeframe,
and other manufacturers have publicly
indicated that they are looking seriously
into both technologies.
The Stage analysis also includes the
possibility that manufacturers could
utilize some vehicle weight reduction as
a fuel economy improvement
technology on light trucks with curb
weights over 5,000 pounds.54 However,
the weight reduction was only applied
in conjunction with a planned vehicle
redesign, and sometimes in concert with
a reduction in aerodynamic drag.
The agency again relied on the NAS
report, which contains costs and
effectiveness estimates for various
technologies that could be used to
enhance a vehicle’s fuel economy. In
most instances, NHTSA used the NAS
report’s mid-range estimate of the
potential fuel economy benefits of
specific technologies. However, if
NHTSA projected the use of a
technology specific to a manufacturer,
NHTSA relied on effectiveness
estimates provided by that manufacturer
when applying that technology to that
manufacturer and if appropriate, to
other manufacturers.
In arriving at the Unreformed CAFE
standard, the agency took into account
the concerns raised by the
manufacturers in response to the August
54 Based on the results of Dr. Kahane’s revised
weight and safety analysis, the net weight-safety
effect of removing 100 lbs. from a light truck—if
footprint is held constant—is zero for all light
trucks with curb weights above 3,900 lbs. However,
the Stage analysis only considered weight reduction
for vehicles with a curb weight in excess of 5,000
lbs. given the statistical uncertainty with the 3,900
lbs. figure. Further discussion of the application of
weight reduction is provided below.
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2005 NPRM. Specifically, the agency is
aware that vehicle manufacturers
require sufficient lead time to
incorporate changes and new features
into their vehicles. The agency is also
aware that the vehicle manufacturers are
unable to deploy new technologies
throughout their entire light truck fleet
in one model year. Similarly, NHTSA
also recognizes that vehicle
manufacturers follow design cycles
when introducing or significantly
modifying a product. In revising and
applying the Stage Analysis, NHTSA
took these concerns into consideration.
For each of the largest manufacturers
that provided product plans with
baselines below our proposed levels for
at least one model year, the agency
projected the use of several Stage I
technologies, beginning with MY 2008,
and several more technologies,
beginning with MY 2009. We note that
in performing the Stage Analysis, the
agency relied on product plans
submitted by the manufacturers as well
as comments received in response to the
August 2005 NPRM. The agency
removed incompatible technologies and
technologies already incorporated into
manufacturers’ product plans from the
Stage Analysis. More importantly, the
agency delayed and ‘‘staggered’’
applications of technologies such that
they are not implemented across the
entire fleet in one model year. Most new
technologies were added in conjunction
with model changes or vehicle
introductions. That is, instead of adding
technologies to existing vehicles in the
middle of their product cycle, we added
technologies to vehicles at the time the
vehicles were undergoing major
engineering changes or when they were
introduced.
Aside from reliance on the NAS
report, we also relied to a limited extent
on technologies present in the
manufacturers’ confidential product
plans. If a technology was present in a
manufacturer’s product plans, we
evaluated the opportunity for additional
application of the technology within
that manufacturer’s fleet, and if
appropriate, other manufacturers’ fleets.
The following are examples of nonconfidential technologies used in the
Stage Analysis.
Stage 1
Electrical power steering—We first
applied this technology to lighter
vehicles that do not require a
conversion to a 42-volt electrical
system. The agency avoided using this
technology for heavier vehicles in the
near term. The power demands for
lighter vehicles do not require a 42-volt
system for operation of electric power
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steering. However, for larger vehicles it
appears that a 42-volt system is required
to accommodate electric power steering,
and adding a 42-volt system was
deemed a technology that can be only
introduced in conjunction with model
changes or product introductions.
In all cases, electric power steering
was added to the Stage Analysis to
coincide with model changes. By MY
2008, electrical power steering was
included on some of the lighter vehicles
undergoing model changes. By MYs
2009 and 2010, this technology was
gradually added to heavier vehicles at
the beginning of their respective
product cycles. That way, installation of
electrical power steering can coincide
with the necessary conversion of these
heavier vehicles to a 42-volt electrical
system.
Low-friction lubricants—This
technology does not require engineering
changes to vehicle engines. Therefore, it
was implemented in MYs 2008 and
2009 on a large percentage of the
eligible fleet without ‘‘staggering’’ the
implementation. That is, the agency
believes that this technology can be
implemented within a relatively short
lead time. The agency did not apply
low-friction lubricants to vehicles with
engines that require higher-friction
lubricants.
Aerodynamic drag reduction—This
technology was applied to certain
vehicles to coincide with a major
vehicle redesign or a vehicle
introduction. Because aerodynamic drag
reduction typically involves actual
vehicle body changes, we were
especially careful not to attribute any
aerodynamic drag reduction, except at
the beginning of a new product cycle.
Low-rolling-resistance tires—This
technology was added to lighter,
passenger-car-based (unibody
construction) light trucks that were
deemed compatible with passenger-carlike tires. Due to compatibility concerns
expressed by several manufacturers,
these tires were not applied to light
trucks intended for significant off-road
duty or pickup trucks with substantial
cargo carrying capabilities. Because this
technology does not require vehicle
engineering resources, we implemented
this technology such that it does not
necessarily coincide with a planned
vehicle introduction or redesign. We
believe that in this case, the lead time
is sufficient for the manufacturers to
make arrangements to purchase
sufficient quantities.
Engine accessory improvement—The
agency projected the use of this
technology for several manufacturers.
This technology category encompasses a
variety of engine accessory
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improvement technologies that several
manufacturers are currently
incorporating, such as improved fuel
and oil pumps. If a manufacturer
provided NHTSA with descriptions for
these specific technologies, they were
applied to that manufacturer’s vehicles
where appropriate. If manufacturers
provided no information regarding their
incorporation of engine accessory
improvement technologies, NHTSA
applied a potential engine accessory
improvement to vehicles that had an
engine and engine technologies that
would benefit from and be compatible
with specific engine accessory
improvements. The agency believes that
this technology is cost-effective. This
technology generally affects the
operation of the engine, thus this
technology was added in conjunction
with a planned introduction of new
models.
Stoichiometric Spark Ignition Direct
Injection—This technology was added
to select vehicles, i.e., those vehicles
produced by manufacturers that have
product plans which reflect a familiarity
with the technology. This technology
was applied in conjunction with a
planned vehicle redesign.
Implementation of this technology was
delayed in response to comments and in
recognition of cost issues associated
with insufficient lead time.
Weight reduction—As explained
below, this fuel economy improvement
method was used sparingly on vehicles
with a curb weights in excess of 5,000
pounds and was applied in conjunction
with a planned vehicle redesign.
Stage 2
5-speed and 6-speed automatic
transmissions—These technologies were
added to some vehicles that, based on
the manufacturers’ product plans, were
projected to continue using 4-speed
automatic transmissions. As with Stage
I technologies, when a transmission
upgrade is used in the Stage Analysis,
it is timed to coincide with model
changes. Further, we first implemented
this technology in vehicles that share
major mechanical components with
vehicles already equipped with 5- or 6speed transmissions. For example, we
project this technology on certain
pickup trucks that share their platforms
and engines with multipurpose
passenger motor vehicles already
equipped with 6-speed transmissions,
knowing that these transmissions were
readily available to the manufacturer
and were compatible with the basic
vehicle architecture.
Cylinder deactivation—In response to
comments, the agency did not apply this
technology to vehicles with
incompatible existing engine
architecture. The agency applied this
technology to select vehicles. In doing
so, the agency took into account
whether this technology was already
available to the manufacturers. In some
instances, this technology was already
utilized by vehicle manufacturers on
some of their light trucks, and the
agency believes that adopting this
technology to other light trucks would
save costs, especially if the technology
is implemented at the time of vehicle
redesign.
Dual overhead cam (DOHC)—The
agency did not use, or delayed the
implementation of this technology in
vehicles where the comments indicated
that the change from single overhead
cam (SOHC) would be too complicated
and would not produce significant fuel
economy improvements because of
incompatibility with the existing engine
architecture. In other vehicles,
implementation of DOHC was timed to
coincide with a planned vehicle or
engine redesign. In applying this
technology, the agency examined the
manufacturers’ current vehicles. In
some instances the manufacturers carry
both DOHC engines and SOHC engines
of the same displacement and basic
architecture. In these instances, the
agency projected a gradual switch to
only the DOHC engines.
Continuous Variable Transmission
(CVT)—CVT technology was relied
upon in the analysis for the NPRM. The
agency did not apply CVTs in the final
rule. The updated product plans
reflected that manufacturers had
applied CVTs or 6-speeds instead to all
of those vehicles to which the agency’s
analysis applied CVTs in the NPRM.
Front Axle Disconnect—Where this
technology was implemented, it was
timed to coincide with planned vehicle
redesign. In addition, in response to
comments regarding the general
´
effectiveness of this technology vis-a-vis
its effectiveness in specific vehicle
applications, we revised downward the
projected fuel economy benefits
attributed to this technology.
Variable Valve Lift and Timing—
Based on comments, this technology
was not used on certain vehicles
because the basic engine architecture
was incompatible. According to
commenters, this technology is
incompatible with overhead valve
engines. Instead, this technology was
applied to certain vehicles already
equipped with overhead cam engines
featuring variable valve timing.
Stage III
Stage III technologies were not
included in the Stage Analysis for all
manufacturers because some
manufacturers can meet the Unreformed
CAFE standards without the need to use
any diesel or hybrid technology. For
some vehicle manufacturers, we
estimated higher sales of light trucks
equipped with hybrid engines compared
to the manufacturer’s product plans.
This revised estimate is based on
continuing strong demand and
increased popularity of hybrid vehicles.
For other manufacturers, we projected
the use of direct-injection diesel engines
in place of large displacement gasoline
V8 engines.
E. Improved Product Plans
The agency’s revised Stage Analysis
produced the following individual
projections:
TABLE 2.—MANUFACTURERS’ FUEL ECONOMY CAPABILITIES AS PROJECTED UNDER THE STAGE ANALYSIS
Model year
2008
Manufacturer
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DaimlerChrysler ...........................................................................................................................
Ford ..............................................................................................................................................
General Motors ............................................................................................................................
Nissan ..........................................................................................................................................
Toyota ..........................................................................................................................................
*22.475
22.455
22.506
22.452
22.506
Model year
2009
23.059
23.060
23.060
23.091
23.054
Model year
2010
23.599
23.935
23.450
23.470
24.044
*While compliance is calculated with the standard is in tenths of a mile per gallon, our initial analysis projects fuel economy capabilities to
thousandths of mpg.
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The technologically-feasible fuel
economy levels determined under the
Stage Analysis provide the basis for the
Unreformed CAFE standards. The Volpe
model is then used to estimate benefits
and costs of these standards. The Volpe
model analyzes what technologies can
be added to meet the standard
determined by the Stage Analysis. More
specifically, the Volpe model uses a
technology application algorithm
developed by Volpe Center staff in
consultation with NHTSA staff to apply
technologies to manufacturers’ baselines
in order to achieve the fuel economy
levels produced under the Stage
Analysis. This algorithm systematically
applies consistent cost and performance
assumptions to the entire industry, as
well as consistent assumptions
regarding economic decision-making by
manufacturers. Technologies are
selected and applied in order of
‘‘effective cost,’’ (total cost ¥ fine
reduction ¥ fuel savings value) ÷
(number of affected vehicles).55 This
formula is a private cost concept (i.e., it
looks at costs to the manufacturer). It is
used to predict how a manufacturer
would sequence the addition of
technologies to meet a given standard.
Although similar, the two analyses do
not apply exactly the same technologies.
Both are merely technologically feasible
ways of achieving the given standard,
not predictions of how manufacturers
will actually meet it. As discussed
below, additional analysis was
performed to ensure that the
Unreformed CAFE standards are
economically practicable for the
industry.
We note that the standards adopted
today are the same as those proposed in
the NPRM, even though the agency
55 In the current model year, the system begins by
carrying over any technologies applied in the
preceding model year, based on commonality of
engines and transmissions, as well as any identified
predecessor/successor relationships among vehicle
models. At each subsequent step toward
compliance by a given manufacturer in the current
model year, the system considers all engines,
transmissions, and vehicles produced by the
manufacturer and all technologies that may be
applied to those engines, transmissions, and
vehicles, where the applicability of technologies is
governed by a number of constraints related to
engineering and product planning. The system
selects the specific application of a technology (i.e.,
the application of a given technology to a given
engine, transmission, vehicle model, or group of
vehicle models) that yields the lowest ‘‘effective
cost’’, which the system calculates by taking (1) the
cost (retail price equivalent) to apply the technology
times the number of affected vehicles, and
subtracting (2) the reduction of civil penalties
achieved by applying the technology, and
subtracting (3) the estimated value to vehicle buyers
of the reduction in fuel outlays achieved by
applying the technology, and dividing the sum of
these components by the number of affected
vehicles.
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performed the Stage analysis on
updated product plans as provided by
the manufacturers. This result is largely
due to the fact that there is a limited
pool of technology that can be applied
to the manufacturers’ fleets in the time
period subject to this rulemaking.
The updated product plans reflected
that some technologies previously
applied by the agency in the Stage
analysis were now applied by the
manufacturers in their product plans,
which meant that these technologies
were no longer available for the Stage
analysis. Because the pool of feasible
technologies that can be applied in the
lead time provided is limited, the
agency projected fewer additional
technologies for the updated product
plans beyond the improvements made
by the manufacturers.
As a result of having limited
technologies and practical constraints
on how and when those technologies
can be applied, the difference between
the NPRM improved fleet and the final
rule improved fleet is largely a matter of
the level of technology voluntarily
added by manufacturers in their revised
product plans submitted in response to
the NPRM. Consequently, the two
improved fleets provide similar fuel
economies.
F. Economic Practicability and Other
Economic Issues
As explained above, the agency has
historically viewed the question of
whether a CAFE standard is
economically practicable in terms of
whether the standard is ‘‘within the
financial capability of the industry, but
not so stringent as to threaten
substantial economic hardship for the
industry.’’ See, e.g., Public Citizen, 848
F.2d at 264. In the Stage analysis,
technologies are applied to project fuel
economy levels that would be
technologically feasible for a
manufacturer. When considering
economic practicability, the agency
assesses whether technologicallyfeasible levels may lead to adverse
economic consequences, such as a
significant loss of sales or the
unreasonable elimination of consumer
choice. The agency must ‘‘weigh the
benefits to the nation of a higher fuel
economy standard against the
difficulties of individual automobile
manufacturers.’’ CAS, 793 F.2d at 1332.
The agency has estimated not only the
anticipated costs that would be borne by
General Motors, Ford, DaimlerChrysler,
Nissan and Toyota to comply with the
standards under the Unreformed CAFE
system, but also the significance of the
societal benefits anticipated to be
achieved through fuel savings and other
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economic benefits from reduced
petroleum use. The baselines provided
by Honda and Hyundai for MYs 2008–
2010 exceeded the standards in each of
those model years. In regard to
economic impacts on manufacturers and
societal benefits, we have relied on the
Volpe model to determine a probable
range of costs and benefits.
The Volpe model is used to evaluate
the standards initially produced under
the Stage Analysis in order to estimate
their overall economic impact as
measured in terms of increases in new
vehicle prices on a manufacturer-wide,
industry-wide, and average per-vehicle
basis. Like the Stage Analysis, the Volpe
model relies on the detailed product
plans submitted by manufacturers, as
well as available data relating to
manufacturers that had not submitted
detailed information. The Volpe model
is used to trace the incremental steps
(and their associated costs) that a
manufacturer would take toward
achieving the standards initially
suggested by the Stage Analysis. In
applying technologies, the Volpe model
is programmed to be as consistent as
practical with the technology
application method and constraints of
the Stage analysis.
Based on the Stage and Volpe
analyses, we have concluded that these
standards would not significantly affect
employment or competition, and that—
while challenging—they are achievable
and that they will benefit society
considerably. For this analysis, we have,
where possible, translated the benefits
into dollar values and compared those
values to our estimated costs for this
proposed rule.
In estimating the costs and benefits of
this rulemaking, the agency employed a
variety of cost estimates (e.g., the cost of
technology, lead-time) and economic
assumptions (e.g., price of fuel, rebound
effect). As the cost estimates and
economic assumptions apply, in many
cases, equally to the Unreformed and
Reformed CAFE system analyses, we
have addressed these comments below
in Section VIII. Technology issues, and
Section IX. Economic assumptions. The
discussion that follows provides our
estimates for the costs and benefits of
the Unreformed CAFE standards
adopted today.
1. Costs
In terms of vehicle costs for
complying with the Unreformed CAFE
standards, we estimate the average
incremental cost per vehicle to be $64
for MY 2008, $185 for MY 2009, and
$195 for MY 2010. The total incremental
costs (the cost necessary to bring the
corporate average fuel economy for light
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trucks from 22.2 mpg (the standard for
MY 2007) to the final rule levels are
estimated to be $536 million for MY
2008, $1,621 million for MY 2009, and
$1,752 million for MY 2010.
Our cost estimates for the Unreformed
CAFE system are based on the
application of technologies and the
resulting costs to individual
manufacturers. We assumed that
manufacturers would apply
technologies on a cost-effectiveness
basis (as described above). More
specifically, within the range of values
anticipated for each technology, as
estimated by the NAS study, we
selected the mid-point for cost and fuel
consumption impacts during the model
years under consideration.
Using the estimated costs and fuel
savings for the different technologies,
the agency then examined the
projections provided by different
manufacturers for their light truck fleet
fuel economy for MYs 2008–2010.
Although the details of the projections
by individual manufacturers are
confidential, we generally observed that
present fuel economy performance
indicates that some manufacturers will,
if their planned fleets remain
unchanged, be able to meet the
proposed standards without significant
expenditures. In contrast, other
manufacturers will need to expend
significantly more effort than they were
planning to meet the final Unreformed
CAFE standards.
Some manufacturers might achieve
more fuel savings than others using
similar technologies on a vehicle-byvehicle basis due to differences in
vehicle weight and other technologies
present. However, this analysis assumes
an equal impact from specific
technologies for all manufacturers and
vehicles. The technologies were ranked
based on the cost per percentage point
improvement in fuel consumption and
applied where available and appropriate
to each manufacturer’s fleet in their
order of rank. The complete list of the
technologies and the agency’s estimates
of cost and associated fuel savings can
be found in Table VI–4 of the FRIA.
2. Benefits
In Chapter VIII of the FRIA, the
agency analyzes the economic and
environmental benefits of the
Unreformed CAFE standards by
estimating fuel savings over the lifetime
of each model year (approximately 36
years). Benefit estimates include both
the benefits to consumers in terms of
reduced fuel usage and other savings,
such as the reduced externalities
generated by the importing, refining,
and consuming of petroleum products.
The total benefits of the increases in
the levels of the Unreformed CAFE
standards are estimated to be $577
million for MY 2008, $1,876 million for
MY 2009 and $2,109 million for MY
2010, based on fuel prices ranging from
$1.96 to $2.39 in 2003 dollars per gallon
and a discount rate of seven percent.
3. Comparison of Estimated Costs to
Estimated Benefits
Table 3 compares the incremental
costs and benefits for the Unreformed
CAFE standards.
TABLE 3.—COMPARISON OF INCREMENTAL COSTS AND BENEFITS FOR THE UNREFORMED CAFE STANDARDS
[In millions]
MY 2008
Total Incremental Costs* .............................................................................................................
Total Incremental Benefits* .........................................................................................................
$536
577
MY 2009
$1,621
1,876
MY 2010
$1,752
2,109
* Relative to the 22.2 mpg standard for MY 2007.
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These estimates are provided as
present values determined by applying
a 7 percent discount rate to the future
impacts.56 The discount rate is intended
to measure the reduction in the value to
society of benefits when they are
deferred until some future date rather
than received immediately. The benefits
are discounted to provide an
appropriate comparison of costs to the
value of future benefits. To the extent
possible, we translated impacts other
than direct fuel savings into dollar
values and then factored them into our
cumulative estimates. We obtained
forecasts of light truck sales for future
years from AEO 2005.57 Based on these
forecasts, NHTSA estimated that
56 In the FRIA, we also evaluated the final rule
using a 3 percent discount rate for discounting
benefits.
57 The agency relied on AEO 2005 projections for
the total sales figures. The manufacturers provided
us with projected sales for passenger cars and light
trucks. However, taken together, the sales
projections provided by the individual companies
to NHTSA yielded unrealistically high industrywide sales volumes. Percentage of total sales per
manufacturer was based on past sales data. A
complete discussion of light truck sales projections
is provided in the FRIA (FRIA p. VIII–8).
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approximately 8.6 million light trucks
affected by this final rule would be sold
in MY 2008. For MYs 2009 and 2010,
we estimated 8.9 million and 9.0
million light truck sales, respectively.
We calculated the reduced fuel
consumption of MY 2008–2010 light
trucks by comparing their consumption
under the final rule for those years to
either the manufacturers’ plans if they
were above 22.2 mpg, or the
consumption they would have if the MY
2007 CAFE standard of 22.2 mpg
remained in effect during those years.
First, the estimated fuel consumption of
MY 2008–2010 light trucks was
determined by dividing the total
number of miles driven during the
vehicles’ remaining lifetime by the fuel
economy level they were projected to
achieve under the 22.2 mpg standard.
Then, we assumed that if these same
light trucks were produced to comply
with higher CAFE standards for those
years, their total fuel consumption
during each future calendar year would
equal the total number of miles driven
(including the increased number of
miles driven because of the ‘‘rebound
effect,’’ the tendency of drivers to
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respond to increases in fuel economy in
the same manner as they respond to
decreases in fuel prices, i.e., by driving
more),58 divided by the higher fuel
economy they would achieve as a result
of that standard. The fuel savings during
each future year that will result from the
higher CAFE standard is the difference
between each model year’s fuel use and
the fuel use that would occur under
either the manufacturer’s plans or if the
MY 2007 standard remained in effect.
This analysis results in estimated
lifetime fuel savings of 555 million,
1,813 million, and 2,023 million gallons
for MYs 2008, 2009, and 2010,
respectively.
A more detailed explanation of our
analysis is provided in Chapter VIII of
the FRIA and the final EA (see EA p.
26).
58 As described in detail in the FRIA, we use a
20 percent rebound effect based on a thorough
review of the literature (FRIA p. VIII–45). We are
nonetheless aware that there is ongoing research in
this area, and will continue to assess this
assumption in future rulemakings in light of new
evidence.
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4. Uncertainty
The agency recognizes that the data
and assumptions relied upon in our
analysis have inherent limitations that
do not permit precise estimates of
benefits and costs. NHTSA performed a
probabilistic uncertainty analysis to
examine the degree of uncertainty in its
costs and benefits estimates. Factors
examined included technology costs,
technology effectiveness in improving
fuel economy, fuel prices, the value of
oil import externalities, and the rebound
effect. This analysis employed Monte
Carlo simulation techniques to examine
the range of possible variation in these
factors. As a result of this analysis, the
agency thinks it very likely that the
benefits of the Unreformed CAFE
standards will exceed their costs for all
three model years. A detailed discussion
of the uncertainty analysis is provided
in Chapter X of the FRIA.
G. Unreformed Standards for MYs
2008–2010
We believe the standards established
today are challenging enough to
encourage the further development and
implementation of fuel-efficient
technologies and are achievable within
the applicable timeframe. Accordingly,
we have concluded that the standards
for the Unreformed CAFE system are
technologically feasible and
economically practicable for those
manufacturers with a substantial share
of the light truck market (General
Motors, Ford, and DaimlerChrysler), and
are capable of being met without
substantial product restrictions, and
will enhance the ability of the nation to
conserve fuel and reduce its
dependence on foreign oil. As noted
above, we have concluded that the
standards set through this final rule
represent the best overall balance of the
statutory factors, and in addition, are
consistent with the protection of motor
vehicle safety and American jobs.
The Unreformed CAFE light truck
standards for MYs 2008–2010 are as
follows:
MY 2008: 22.5 mpg
MY 2009: 23.1 mpg
MY 2010: 23.5 mpg
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VI. The Reformed CAFE Standards for
MYs 2008–2011
A. Overview of Reformed CAFE
The structure of Reformed CAFE for
each model year, as adopted in today’s
final rule, has two basic elements—
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(1) a function that sets the target fuel
economy levels for each value of vehicle
footprint; 59 and
(2) a Reformed CAFE standard based
on each manufacturer’s productionweighted harmonic average of the fuel
economy targets for footprint value.
Unlike the proposed Reformed CAFE
system, which relied on a step function
and associated categories, the final
Reformed CAFE system relies on a
continuous mathematical function
relating fuel economy targets to vehicle
footprint.
The required level of CAFE for a
particular manufacturer for a given
model year is calculated using the
target-setting function for that model
year in conjunction with that
manufacturer’s actual total production
and its production at each footprint
value for that model year.60 The
manufacturer’s required CAFE level is
calculated by dividing its total
production for the model year by the
sum of the values obtained by dividing
the manufacturer’s production of each
vehicle model included in its fleet by
the fuel economy target for that model.
B. Authority for Reformed CAFE
In the same manner as we explained
the step function proposal to be
consistent with EPCA,61 the continuous
function Reformed CAFE standard
similarly conforms to the mandate to
establish maximum feasible fuel
economy standards. The continuous
function standard is applicable on a
fleet average basis and reflects the
agency’s balancing of the nation’s need
to conserve energy, the effect of other
standards on fuel economy,
technological feasibility, economic
practicability and other public policy
considerations. Further, like the
proposed step function standard, the
continuous function achieves the
congressional policy objectives
embedded in EPCA.
The continuous function standard
retains the fleetwide compliance aspect
mandated by the CAFE statute. By
maintaining reliance on harmonic
averaging, the continuous function
standard promotes the CAFE statute’s
overriding goal of conserving energy in
59 Footprint is an aspect of vehicle size—the
product of multiplying a vehicle’s wheelbase by its
average track width
60 Since the calculation of a manufacturer’s
required level of average fuel economy for a
particular model year would require knowing the
final production figures for that model year, the
final formal calculation of that level would not
occur until after those figures are submitted by the
manufacturer to EPA. That submission would not,
of course, be made until after the end of that model
year.
61 See 70 FR 51415, 51445.
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a manner that preserves manufacturer
flexibility and consumer choice. (H. Rpt.
94–340, p. 87; S. Rpt. 94–179, p. 6.)
The discretion provided to the agency
by Congress to determine whether to
establish a single fuel economy level
applicable to all manufacturers or to set
a series of fuel economy levels
applicable to individual manufacturers
equally supports using a step function
or a continuous function to establish
fuel economy targets for vehicles of
different sizes.62 Under either type of
function, a manufacturer’s required fuel
economy level is dependent on the
manufacturer’s fleet mix. Moreover, just
as the category targets described in the
NPRM are equally applicable to all
manufacturers, the fuel economy targets
defined by a continuous function are
equally applicable to all manufacturers
for a given model year.
A continuous function standard is
based on similar technological and
economic considerations employed in
establishing the proposed step function
standard, and which we believe ensure
the technological feasibility and
economic practicability of the proposed
MY 2011 standard. Moreover, a
continuous function is defined based on
the modeled capabilities of the same
percentage of the fleet as in the step
function proposal (i.e., 97 percent of the
light truck fleet). Reliance on 97 percent
of the fleet better reflects industry-wide
considerations than the primary focus
on the ‘‘least capable manufacturer with
a substantial share of the market’’ in the
Unreformed CAFE structure.
In the NPRM we recognized the
financial challenges facing the motor
vehicle industry and that a substantial
number of job losses had been
announced by large full-line
manufacturers. Since publication of the
NPRM, two manufacturers of light
trucks, each with a significant share of
the market, have continued to report
financial difficulties. The financial risks
faced by these companies, including
their workers and suppliers,
underscored the importance to full-line
vehicle manufacturers of establishing an
equitable CAFE regulatory framework.
Compared to Unreformed CAFE, the
Reformed CAFE will enhance overall
fuel savings while providing
manufacturers the flexibility they need
to respond to changing market
conditions. The reforms adopted today
will provide a more equitable regulatory
framework by creating a level playing
field for manufacturers, regardless of
63 For a discussion of the technology costs and
determination of the social benefits of improved
fuel economy, refer to the FRIA.
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whether they are full-line or limited-line
manufacturers.
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C. Legal Issues Related to Reformed
CAFE
1. Maximum feasible
EPCA requires that the light truck
CAFE levels be established at the
‘‘maximum feasible average fuel
economy level’’ achievable by the
manufacturers in that model year (49
U.S.C. 32902(a)). When deciding on the
maximum feasible level, the agency
must consider technological feasibility,
economic practicability, the effect of
other motor vehicle standards of the
Federal government on fuel economy,
and the need of the nation to conserve
energy (49 U.S.C. 32902(f)). The agency
must balance these considerations,
along with other factors such as safety,
when determining the level of CAFE
standards.
As indicated above, and described in
greater detail below, the Reformed
CAFE system uses incremental costbenefit analysis (as implemented within
the Volpe model) to establish standards.
The technology cost and benefit
assumptions employed by the model are
based on those presented in the NAS
report. However, consideration is given
to manufacturers’ critiques of the
technology assumptions employed by
NAS. The agency also relies on the
product plans provided by
manufacturers when projecting
potential technology applications. The
standard arrived at through this process
is then evaluated to determine potential
sales and employment impacts. As
explained in the following discussion,
the totality of this analysis results in a
standard that is both technologically
feasible and economically practicable.
As discussed elsewhere in this notice,
the standard reflects consideration of
the impact of other Federal motor
vehicle standards on fuel economy, and
as evidenced by our estimates that the
resulting standard for MY 2011 will
save approximately 2.8 billion gallons of
fuel, also addresses the nation’s need to
conserve energy.
Vehicle manufacturers and the
Alliance expressed concern that the
agency’s new methodology for setting
CAFE standards (i.e., using cost-benefit
analysis to identify the pattern and
stringency of fuel economy targets)
risked losing the key economic
practicability check that was previously
provided by assessing a proposed
standard’s effect on the least capable
manufacturer, an approach that had
proven reasonable and workable in
many prior CAFE rulemakings. In
general, these commenters argued that
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the agency must continue to consider
the ‘‘least capable manufacturer’’ to
ensure that standards set under the
Reformed CAFE system do not result in
adverse economic impacts on any
individual manufacturer. General
Motors and Ford argued that NHTSA’s
proposed methodology does not
sufficiently consider the capabilities of
the ‘‘least capable manufacturer,’’ and
thus violates its statutory duty to set
standards that are ‘‘economically
practicable.’’
We noted in the NPRM that the term
‘‘least capable’’ manufacturer is
something of a misnomer under the
Reformed system, since each
manufacturer’s projected level of CAFE
is determined by two factors: (1) The
extent to which small or large vehicles
predominate in its planned production
mix, and (2) the type and amount of
fuel-saving technologies the
manufacturer is deemed capable of
applying. Two manufacturers may apply
the same type and amount of fuel-saving
technologies to their fleets, yet have
differing CAFE levels, if their fleet
mixes are not identical. Thus, a full-line
manufacturer could have a lower overall
CAFE than a manufacturer
concentrating its production in the
smaller footprint range, even though the
former manufacturer has applied as
much (or more) technology to the
models it produces as has the latter
manufacturer. The manufacturer
concentrating its production in smaller
vehicles would have a higher CAFE
level due to the higher fuel economies
of smaller vehicles. Thus, ‘‘large
manufacturer with the lowest fuel
economy average’’ might better describe
the former than ‘‘least capable
manufacturer.’’
The Reformed CAFE system
establishes standards with regard to the
capabilities of a wider range of
manufacturers than just the ‘‘least
capable manufacturer.’’ The fuel
economy capabilities of an individual
manufacturer are projected based on
each of the seven largest manufacturers’
specific product plans. Consideration of
what specific technologies each
manufacturer can apply and at what rate
each technology can be applied is also
made at the individual manufacturer
level. Further, a manufacturer’s required
fuel economy level reflects that
manufacturer’s actual fleet mix.
Instead of requiring a uniform level of
CAFE—which is inherently more
challenging for manufacturers whose
fleets have high percentages of larger
vehicles to meet than for those whose
product lines emphasize smaller
models—the Reformed system specifies
fuel economy targets that vary according
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to vehicle footprint; these targets are
higher for smaller light trucks and lower
for large ones. It uses these targets to
determine a required CAFE level for
each manufacturer that reflects the size
distribution and production volumes of
its light truck models. By setting each
manufacturer’s required fleet-wide
CAFE level to reflect its size mix, the
Reformed system requires some effort by
each manufacturer to improve the fuel
efficiency of its individual models,
regardless of their size distribution.
As stated above, the Volpe model
applies technologies to a manufacturer’s
fleet until the cost of an additional
technology application equals the
benefits of the resulting improvement in
fuel economy. Because these benefits
include the value of reducing economic
and environmental externalities from
producing fuel, this process results in a
‘‘socially optimal’’ level of fuel
economy. Before we arrive at the level
of optimal economic efficiency, it is
important to understand the
assumptions relied on by the model
when applying technology.
As with the Stage analysis, the Volpe
model’s assumptions about technology
cost and effectiveness are based on
estimates provided in the NAS report,
and incorporate information provided
by manufacturers. The agency continues
to rely on the NAS report to determine
technology costs and effectiveness
because the estimates developed in the
NAS study were developed by
recognized experts in vehicle
technology, and were widely peer
reviewed. This study is the most up to
date peer reviewed study available.
While the agency is working to update
the NAS data, in a study conducted
through an interagency agreement with
the Department of Energy, this update
requires additional work. To that end,
the agency continues to rely on the NAS
report.
Because the alternative estimates
submitted by vehicle manufacturers and
others as part of their comments on the
NPRM have not been subjected to the
same review process, the agency
continues to view those reported in the
NAS study as the most reliable
estimates available. Further, because the
Volpe model applies these technologies
to individual vehicle models described
in the product plans provided by
manufacturers, this ensures that
technologies are not added to vehicles
already employing them, and that the
model reliably projects potential fuel
economy improvements for actual
vehicle models that manufacturers plan
to produce during each future model
year. As such, the standard is based on
actual characteristics of specific vehicle
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models and fleet mixes from
manufacturers’ product plans.
The agency has also responded to
information provided by manufacturers
concerning the practicability of
applying various technologies. As
explained in greater detail below in
Section XIII. Comparison of the final
and proposed standards, the revised
assumptions and constraints include:
extending lead times provided for
implementing certain technologies,
reducing annual phase-in percentages
for certain technologies, and reducing
instances of mid-product cycle
technology applications. The model
then relies on these revised assumptions
in conjunction with the NAS study’s
original estimates of technology costs
and effectiveness, to determine the
‘‘socially optimal’’ fuel economy level.
Ford stated that by focusing on
‘‘optimal economic efficiency,’’ NHTSA
has adopted a surrogate measure of
economic practicability that (as
contrasted with its traditional
assessment whose starting point is the
‘‘least capable manufacturer’’) does not
consider many of the effects that the
higher standards would have on
individual manufacturers.
DaimlerChrysler noted that Congress
specifically directed NHTSA to consider
industry-wide capabilities in setting
CAFE standards, not just costeffectiveness for consumers. As such,
DaimlerChrysler argued that retaining a
‘‘least capable manufacturer’’ analysis
would help ensure that the standard
continues to be within the industry’s
ability to afford in terms of capital costs
and annual expenditures.
In response to these comments, the
agency notes that determining the
socially optimal level of fuel economy
targets under the assumptions inputted
into the Volpe model provides a
benchmark for assessing the economic
practicability of the resulting standard.
Because these socially optimal targets
are determined by equalizing the
monetized social benefits of improved
fuel economy further to the costs of the
technologies that would produce such
benefits,63 this process avoids the
application of technologies whose
benefits are insufficient to justify their
costs when the agency determines a
manufacturer’s capability. In other
words, this approach ensures that each
identified private technology
investment projected by the model
produces marginal benefits at least
equal to marginal cost.
63 For a discussion of the technology costs and
determination of the social benefits of improved
fuel economy, refer to the FRIA.
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The agency did identify and consider
a variety of benefits and costs that either
could not be monetized or could not be
quantified. On the benefit side, for
example, there is a significant reduction
in carbon dioxide emissions, which can
not be monetized. There is no agreement
in the literature on values or range of
values for monetizing such a benefit to
the United States. On the cost side, for
example, there is a risk of adverse safety
impacts from downweighting, which
cannot be quantified. This is because
the agency is unable to predict to what
extent manufacturers may rely on
downweighting, and therefore cannot
quantify the number of additional
deaths and injuries that may occur as a
result. Overall, the agency determined
that there is no compelling evidence
that these unmonetized benefits and
costs would, taken together, alter its
assessment of the level of the standard
for MY 2011 that would maximize net
benefits. Thus, the agency determined
the stringency of that standard on the
basis of monetized net benefits.
Standards set at a level more stringent
than those set at the socially optimal
level would not be economically
efficient for society. Standards more
stringent than those established under
the Reformed CAFE system adopted in
this document would require the
industry to continue applying
technology past the point at which
doing so increases net social benefits.
Standards set at a level less stringent
than those set at the socially optimal
level would result in a lost opportunity
for applying cost-beneficial
technologies. Under less stringent
standards, technologies that provide
benefits at least equal to their costs
would not be projected onto
manufacturers’ product plans. As such,
the standards would not capture fuel
savings that are cost-effective to achieve.
In considering manufacturers’ costs
for applying technology, the agency’s
analysis accounts for the opportunity
costs associated with investing in that
technology. When a manufacturer
invests its capital in additional
technology, those resources are
unavailable for other investment
opportunities, and the returns the
manufacturer could have earned on
alternative investments or other uses of
its capital resources (such as application
to safety or performance attributes of a
vehicle, or retiring existing debt)
represent an additional cost of
improving fuel economy. To ensure that
this additional cost of using capital
resources is reflected in its assessment
of the economic practicability of
improving fuel economy, the agency
discounts the future fuel savings and
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other benefits that result from higher
fuel economy using a 7 percent discount
rate.
The agency is relying on a 7 percent
discount rate partly because this rate
reflects the economy-wide opportunity
cost of capital. The agency believes that
a substantial portion of the cost of this
regulation may come at the expense of
other investments the auto
manufacturers might otherwise make.
Several large manufacturers are
resource-constrained with respect to
their engineering and productdevelopment capabilities. As a result,
other uses of these resources will be
foregone while they are required to be
applied to technologies that improve
fuel economy.
If a manufacturer were able to capture
all of the benefits to both vehicle buyers
and society as a whole that result from
improved fuel savings, it would apply
technology to the level where the
present value of increased future
benefits when discounted at 7 percent
just equaled the costs of applying
additional technology.64 Applying
technology to improve fuel economy
beyond this level would entail costs—
including the opportunity cost of the
additional capital resources devoted to
improving fuel economy—that would
exceed the resulting benefits. Failing to
improve fuel economy to this level
would leave opportunities to obtain fuel
savings and related benefits that
exceeded the associated costs of the
technologies necessary to obtain them.
In commenting on the Reformed
CAFE system, the Alliance stated that
standards should not be set so high as
the cost of the added technology
outweighs the societal benefits of the
improved fuel economy. Because the
social optimal level of fuel economy
ensures that the marginal benefit (either
to the consumer or to society) of an
increase in fuel economy is equal to cost
of the technology producing the
additional benefit, the social optimum
level is economically practicable for
society.
Ford suggested NHTSA’s cost-benefit
analysis has not properly considered
costs to manufacturers for making
64 The main benefit of improving fuel economy is
the savings in fuel costs experienced by vehicle
buyers, since as a light truck’s fuel economy
increases, the amount and cost of the fuel required
to operate it decreases. At the same time, reducing
the amount of fuel light trucks consume also
generates benefits to society and the economy as a
whole, including reduced emissions of some
criteria pollutants that occur during fuel refining
and reduced economic costs from importing and
consuming petroleum. Because these benefits
accrue to individuals and firms other than those
who purchase new vehicles, they are referred to as
external benefits.
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necessary investments and for
increasing employment levels, or
competitive forces that may cause
domestic manufacturers to absorb
CAFE-related costs rather than passing
them on to buyers. Ford argued that the
potential inability of producers to
recoup such costs from buyers (in the
form of higher prices) must be taken
into account explicitly, not solely
through its effect on sales.
DaimlerChrysler also argued that not all
of the costs associated with improved
fuel economy can be passed on to
consumers in the form of higher vehicle
prices.
As stated above, a cost-benefit
analysis is not the sole factor in the
agency’s consideration of economic
practicability. The agency also performs
a sales impact analysis. In determining
the sales impact of higher prices from
improved fuel economy, the agency
assumes that consumers will value
improved fuel economy. However, the
analysis does not rely on the value of
fuel savings realized over the life of the
vehicle. Our analysis considers the
value of fuel savings realized in the first
4.5 years of the vehicle’s life. The 4.5
year period is the average ownership
period for new cars. We determined that
the fuel savings during this period will
be recognized and valued by light truck
purchasers. Based on our analysis,
which assumes that consumers value
fuel savings over 4.5 years, there are net
benefits for the average light truck
purchasers. Thus, the average consumer
will be willing to pay higher prices for
improved fuel economy, and
manufacturers will be able to raise
prices to recoup their investments.
DaimlerChrysler further argued that
the agency must explain how it will
decide whether a standard set at a
‘‘maximum net benefits’’ level would
exceed the level that is economically
practicable if it does not take into
account the capabilities of the ‘‘least
capable manufacturer’’ with a
substantial market share.
DaimlerChrysler argued that the agency
has not provided sufficient detail as to
its methodology, as would permit
informed public comment. This
commenter stated that in certain
situations, economic practicability
might require the agency to set a lower
standard than the maximum net benefits
methodology might otherwise dictate.
For example, DaimlerChrysler, along
with the Alliance and Ford, stated that
if gas prices were to rise high enough,
every technology would theoretically be
‘‘cost-beneficial.’’
Gas prices are but one factor relied on
in the agency’s analysis for setting fuel
economy targets. As stated, the Volpe
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model also takes into account other
factors closely associated with economic
practicability, such as lead time and
phase-in rates. While higher fuel prices
increase the benefits associated with
improved fuel economy, the marginal
cost-benefit analysis is still bounded by
the technological and economic
assumptions employed by the model.
The agency has relied on technologies
determined by the NAS report to be
‘‘currently in the production, product
planning, or continued development
stage, or are planned for introduction.
* * * The feasibility of production is
therefore well known, as are the
estimated production costs’’ (NAS p.
40).65
Additionally, the model relies on
assumptions that reflect manufacturers’
comments regarding the applicability of
technology. Manufacturers provided
detailed critiques of the agency’s
application of technology in the NPRM,
most of which were provided
confidentially. Manufacturers provided
alternative assumptions that they
deemed more reasonable. Presumably,
in providing comment on what were
reasonable assumptions for the agency
to apply, the manufacturers’
recommendations inherently accounted
for their capabilities, both technological
and economic.
Many of these assumptions are closely
tied to the economic capabilities of the
manufacturers. For example, in
response to commenters, the agency
employed longer lead time and longer
phase-ins for various technologies.
These adjustments reduce the economic
impact of applying technology by
providing greater flexibility as to when
fuel economy improvements are
expected. Additionally, we limited the
number of mid-product cycle
applications. Mid-product cycle changes
typically are more costly than changes
at the beginning of a product cycle, as
mid-product cycle changes may
necessitate changes to an established
manufacturing line. By limiting the
availability of technologies using these
assumptions, the cost-benefit does not
assume that manufacturers will make
improvements that would be
unjustifiably costly.
The socially optimum level of fuel
economy, as determined under the
Volpe analysis, is thus indicative of the
fuel economy level that is economically
practical for both individual
manufacturers and the light truck
industry as a whole, and provides a
process for careful balancing of the
‘‘competing factors of EPCA’’ (CEI v.
65 Complete documentation of the Volpe fuel
economy model is available in the CAFE docket.
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NHTSA, 901 F.2d 107, 121 (DC Cir.
1990)). Further, the agency conducts an
analysis of the estimated sales and
employment impacts on individual
manufacturers from a standard set at the
level derived from the analysis applied
through the Volpe model to ensure the
economic practicability of that standard.
We recognize the financial difficulties
facing several light truck manufacturers.
It has been widely reported that General
Motors and Ford are facing financial
difficulties. In 2005, gasoline prices
rapidly increased, causing a shift in
consumer demand away from larger,
more profitable SUVs and toward
smaller, more fuel-efficient cars and
light trucks, a segment of the market
long dominated by Asian automobile
manufacturers. Sales of sport utility
vehicles have fallen slightly in each of
the last few years, with the trend
accelerated by a jump in gas prices late
in 2005. The increase in gasoline prices
particularly curbed sales of the biggest
SUVs. In response, U.S. automakers
increased sales during the 2005 summer
with discounts that let consumers pay
what was called the ‘‘employee’’ price.
While this marketing led to near-record
sales, sales again dropped off in October
when the incentives ended. By
December of 2005, General Motors and
Ford sales were down 10.2 percent and
8.7 percent respectively.
Aside from the recent sales losses,
General Motors and Ford have
experienced erosion in their respective
market shares. General Motors, and to a
lesser extent Ford, have seen their
market share fall drastically over the last
several years in the last year, which has
resulted in operating losses. General
Motors’ market share dropped from 28.1
percent in 2003 to 26.9 in 2004, and to
24.7 percent in 2005. This is compared
to General Motors’ market share of 35
percent in the early 1990’s. Ford has
experienced a drop from 19.3 percent in
2003 to 17.8 in 2005.66
These losses in market share have
coupled with operating losses. General
Motors had an operating loss of $11.5
billion for its North American
operations in calendar year 2005, with
automotive cash flows related to
operations at a negative $7.9 billion.67
During that same year, Ford Motor
Company experienced an operating loss
of $1.5 billion, with negative cash flows
66 The market share values are from
wardssuto.com. The 2005 values are estimates.
67 Source: SEC FORM 8–K submitted to the SEC
on January 26, 2006, and General Motors’ March 16,
2006 press release as reported by Automotive
Business Review (https://www.automotive-businessreview.com/article_news.asp?guid=FE50808D–
4915-4A6F-949F-7532C6F5CE75).
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from operations at $4.1 billion.68 In
November 2005, General Motors
announced that it would cut 30,000 jobs
and close 12 manufacturing facilities by
2008. In January 2006, Ford announced
that it would cut up to 30,000 jobs by
closing 14 manufacturing facilities over
the next six years. The financial
difficulties facing these manufacturers
was given due consideration.
In their comments to the NPRM,
several commenters, including General
Motors and Ford, expressed concern
that the marginal cost-benefit analysis
would not appropriately consider the
capabilities of individual manufacturers
and may result in standards that impose
harsh economic impacts on an
individual manufacturer. Ford
specifically noted that if standards
increased further then the costs may be
too high and unrecoverable, further
compounding the current economic
hardship facing the industry. According
to Ford, when determining the
economic practicability of its CAFE
standards, the agency must determine
whether technologically-feasible levels
would lead to adverse economic
consequences, such as a significant loss
of sales or the unreasonable elimination
of consumer choice, a determination
that Ford claimed the agency has not
made in selecting its proposed
Reformed CAFE targets.
The agency recognizes that we must
consider the potential economic and
financial impacts of the CAFE standards
on individual manufacturers. Aside
from incorporating manufacturers’
comments regarding the feasibility of
technology applications, the agency has
also performed a sales and employment
impact analysis. The sales analysis
looks at a purchasing decision from the
eyes of a knowledgeable and rational
consumer, comparing the estimated cost
increases versus the payback in fuel
savings over 4.5 years (the average new
vehicle loan) for each manufacturer.
This relationship depends on the cost
effectiveness of technologies available to
each manufacturer. Some manufacturers
are estimated to increase sales and
others to lose sales. Overall, based on a
7 percent discount rate for future fuel
savings, the maximum sales loss is less
than 11,000 vehicles per year for the
industry. We believe this will have a
minor impact on employment.
Further, we note that the regulatory
philosophy set forth in Executive Order
12866, ‘‘Regulatory Planning and
Review,’’ is that a rulemaking agency
should set its regulatory requirements at
the level that maximizes net benefits
68 Source: Ford’s SEC Form 8–K submitted to the
SEC January 23, 2006.
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unless its statute prohibits doing so.
EPCA neither requires nor prohibits the
consideration of the fuel economy level
at which net benefits are maximized.
Additionally, EPCA does not require the
agency to rely on the ‘‘least capable
manufacturer’’ analysis as we have
traditionally used. Reliance on the
‘‘least capable’’ manufacturer analysis
was in response to the direction in the
conference report on the CAFE statute
language to consider industry-wide
considerations, but not necessarily base
the standards on the manufacturer with
the greatest compliance difficulties.
Moreover, the very structure of
Reformed CAFE standards makes it
unnecessary to continue to use the
‘‘least capable manufacturer’’ approach
in order to be responsive to guidance
contained in the EPCA conference
report. Instead of specifying a common
level of CAFE, a Reformed CAFE
standard specifies a variable level of
CAFE that varies based on the
production mix of each manufacturer.
By basing the level required for an
individual manufacturer on that
manufacturer’s own mix, a Reformed
CAFE standard in effect recognizes and
accommodates differences in
production mix between full- and partline manufacturers, and between
manufacturers that concentrate on small
vehicles and those that concentrate on
large ones. A Reformed standard is also
responsive to changes in fleet-mix that
result from changes in the market.
In contrast to comments from the
manufacturers, environmental
commenters argued that the marginal
cost-benefit analysis is contrary to EPCA
because it results in a standard that is
lower than what they deemed to be
‘‘maximum feasible.’’ The Union of
Concerned Scientists stated that the
social optimum level is below
‘‘maximum feasible’’ because of the
uncertainty surrounding many of the
assumptions relied on in the model. The
Union of Concerned Scientists stated
that the model undervalues the benefits
because not all externalities are
monetized (e.g., reduction in CO2
emissions). The Union of Concerned
Scientists recommends the agency rely
on a break-even approach, i.e., set fuel
economy levels at the point at which
total costs equal total benefits. This
commenter stated that the break-even
approach would result in targets an
average of 6 mpg higher than those in
the proposed rule.
The agency considered an approach
under which technology was applied to
the point of total cost equaling total
benefit, but determined that such a
standard would violate the maximum
feasible requirement. The Volpe model
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was unable to achieve a level of total
cost equaling total benefit before
running out of technologies to apply.
While the Union of Concerned
Scientists stated that it performed a
‘‘break-even’’ analysis, it did not explain
the technologies it relied upon in its
analysis. In any event, the ‘‘break even’’
approach necessitates adding
technologies that cost more than the
benefit they provide.
ACEEE commented that NHTSA’s
approach of setting CAFE standards that
maximize net benefits is flawed because
it is inconsistent with the requirements
of EPCA. ACEEE stated that under the
statute, NHTSA must set ‘‘maximum
feasible’’ fuel economy standards after
considering the ‘‘technological
feasibility, economic practicability, the
effect of other motor vehicle standards
of the Government on fuel economy,
and the need of the United States to
conserve energy.’’ 69 According to
ACEEE, there is a range of fuel economy
values that are technologically feasible
and another range of values that are
economically practicable, and the
statute requires NHTSA to set the CAFE
standard at the highest value within the
intersection of those ranges. ACEEE
stated that NHTSA’s proposed
maximum benefits approach would not
yield the same level of fuel economy, so
the agency’s current methodology is
therefore impermissible. Accordingly,
ACEEE urged NHTSA to adopt an
approach whereby CAFE standards
would be set at the maximum
technically-feasible level that has
positive net total economic benefits,
rather than a level at which the added
benefits from improving fuel economy
further are offset by the costs for doing
so.
NRDC similarly stated that the
agency’s methodology ‘‘falls short of
statutory compliance’’ and argued that a
cost-benefit analysis is inappropriate
because key benefits of the fuel
economy standards are ‘‘impossible to
reduce to monetized quantities,’’ such
as ‘‘the national security benefits of
reduced oil dependence and
environmental and societal benefits of
reducing the severity of global
warming.’’ NRDC stated that the
agency’s rationale for relying on a costbenefit methodology was ‘‘arbitrary and
insupportable,’’ in part because EPCA
provides for NHTSA to engage in
‘‘technology-forcing.’’ The Union of
Concerned Scientists argued that to
account for undervaluing of societal
benefits, fuel economy targets should be
established at the level where total
benefits exceed total costs.
69 49
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As suggested by ACEEE, the agency
establishes the standard at the
maximum feasible fuel economy level
that is economically practicable. The
agency is not permitted to establish
higher standards simply because they
might be technologically feasible. When
such standards would impose cost
burdens on certain manufacturers that
are not economically practicable, such
standards would violate EPCA.
Conversely, our statutory responsibility
does not allow us to set lower standards
than those it has established using this
process, because the standards adopted
today are demonstrably technologically
feasible, and more lenient standards
would not represent the maximum
feasible levels that could be attained
while remaining economically
practicable.
NRDC commented that the marginal
cost-benefit analysis is inconsistent with
a ‘‘technology forcing standard’’ 70 and,
further that it is inappropriate for the
purposes of CAFE because the benefits
are ‘‘impossible to reduce to monetized
quantities.’’ NRDC stated that the
enhancement of national security and
the reduction of potential effects from
reduced CO2 emissions may not fully be
quantifiable and monetizable.
We disagree with NRDC with regard
to the degree of technology forcing
permitted under EPCA. The statute
permits the imposition of reasonable,
‘‘technology forcing’’ challenges on any
individual manufacturer, but does not
contemplate standards that will result in
severe economic hardship by forcing
reductions in employment affecting the
overall motor vehicle industry.71 A fuel
economy standard ‘‘with harsh
economic consequences for the auto
industry * * * would represent an
unreasonable balancing of EPCA’s
policies’’ (CAS, 793 F.2d at 1340).
In response to arguments by the
Union of Concerned Scientists and
70 We assume NRDC is using the phrase
‘‘technology forcing’’ to indicate a level of a
standard that would require manufacturers to apply
technologies beyond that assumed technologically
feasible under the Volpe model.
71 In the past, the agency has set CAFE standards
above its estimate of the capabilities of a
manufacturer with less than a substantial, but more
than a de minimus, share of the market. See, e.g.,
CAS, 793 F.2d at 1326 (noting that the agency set
the MY 1982 light truck standard at a level that
might be above the capabilities of Chrysler, based
on the conclusion that the energy benefits
associated with the higher standard would
outweigh the harm to Chrysler, and further noting
that Chrysler had 10–15 percent market share while
Ford had 35 percent market share). On other
occasions, the agency reduced an established CAFE
standard to address unanticipated market
conditions that rendered the standard unreasonable
and likely to lead to severe economic consequences.
49 FR 41250, 50 FR 40528, 53 FR 39275; see Public
Citizen, 848 F.2d at 264.
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ACEEE, NHTSA does not agree that the
EPCA requires it to set CAFE standards
at the highest technically feasible level
that would result in positive net
economic benefits. Although EPCA does
not specify a method for identifying
standards that are economically
practicable, Executive Order No. 12866
establishes an overall goal of achieving
the highest net benefits, which occurs at
the point where the additional benefits
from further increasing the standards
(marginal benefits) just equal the
increase in costs for complying with a
stricter standard (marginal costs).72
NRDC also stated that the agency
should use its authority to set standards
to be ‘‘technology forcing.’’ While NRDC
did not define ‘‘technology forcing’’ we
took their comment to mean that the
agency should establish standards that
require investment in developing new
technologies. However, the agency
would not be able to ensure that
standards set at such a level would be
technologically feasible, as these levels
would require the use of technologies
not yet proven.
The standards that result from the
continuous function CAFE system are
technology-forcing in that the standards
require manufacturers to employ
technologies beyond those in their
product plans, to the extent practicable
within the lead time available. This is
evidenced by the fact that both the Stage
and benefit-cost analyses for
determining the level of standards
envision extensive application of fuel
economy technologies that are currently
in their early stages of deployment, but
are not already included in
manufacturers’ product plans for the
model years to which the adopted
standards apply.
Moreover, our cost-benefit analysis
carefully considers and weighs all of the
benefits of improved fuel savings. The
main source of benefits from the
standards is the fuel savings
experienced by consumers. With regard
to the value of increased energy
security, the agency has estimated a
monetized value of this security
associated with improved fuel savings.
We have also determined that there is
no compelling evidence that the
unmonetized benefits would alter our
assessment of the level of the standard
for MY 2011. A discussion of the benefit
assumptions is provided in Chapter VIII
of the FRIA. Further, the marginal costbenefit analysis ensures that we do not
set standards beyond what is
economically optimal for society.
72 White House Office of Management and
Budget, Circular A–4, September 17, 2003, p. 10.
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2. Backstop
Consistent with our proposal, the
Reformed CAFE system adopted today
does not include a backstop or similar
such mechanism. Several commenters,
ACEE, NRDC, the Union of Concerned
Scientists, and Environmental Defense,
argued that EPCA requires the agency to
incorporate such measures under the
Reformed CAFE system. However, a
backstop or similar mechanism as
recommended by commenters would
not be consistent with the objectives of
EPCA, and in some instances could
violate the statute.
‘‘Backstop’’ refers to a required fuel
economy level that would be applicable
to an individual manufacturer (or to the
industry) if the required fuel economy
level calculated under the Reformed
CAFE system for a manufacturer (or
industry) was below a predetermined
minimum. The concept of a backstop is
to prevent or minimize the loss of fuel
savings from one model year to the next.
Such a requirement would essentially
be the same as an Unreformed CAFE
standard. Stated another way, the
Reformed CAFE standard with a
backstop would require compliance
with the greater of the following fleetwide requirements: (1) An average fuel
economy level calculated under the
Reformed CAFE standard, or (2) an
equal-cost fuel economy level calculated
under the Unreformed CAFE standard.
Under the Reformed CAFE system a
manufacturer’s required fuel economy is
reflective of that manufacturer’s product
mix. Fuel economy targets are based on
vehicle footprint; vehicles with a larger
footprint are compared to less stringent
targets than vehicles with a smaller
footprint. As such, commenters stated
that upsizing 73 of manufacturers’ fleets
through increased sales of larger
vehicles would reduce required fuel
levels and fuel savings would decrease.
It is this potential for reduced fuel
savings that these commenters assert
necessitates a backstop or fuel economy
ratcheting mechanism.74
As previously explained, EPCA
requires the agency to establish fuel
economy standards with consideration
given to four statutory criteria, one of
which is the Nation’s need to conserve
73 ‘‘Upsizing’’ of a fleet refers to the increase in
average footprint that occurs through either an
increase to the footprint value of individual
vehicles, an increase in the production of vehicles
with larger footprint values, or a combination of
both.
74 As described by commenters, a ‘‘ratcheting
mechanism’’ is a regulatory mechanism that would
automatically increase the stringency of the
required fuel economy level for a manufacturer or
the industry if fuel savings dropped below a
predetermined level.
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energy. However, the agency has in the
past reduced established fuel economy
standards because the previous balance
of the four criteria no longer gave
sufficient consideration to the criteria of
economic practicability. This course of
action was upheld by the U.S. Circuit
Court of Appeals for the District of
Columbia, once with respect to light
trucks, and the other time with respect
to passenger cars. See, CAS, 793 F.2d
1322; Public Citizen, 848 F.2d 256. With
regard to the reduction of the light truck
standard, the agency determined that
manufacturers had made reasonable
efforts to comply with the standard, but
it was a shift in market demand that was
hindering compliance. Consumers were
demanding larger vehicles with lower
fuel economy performance than
manufacturers or the agency had
projected. The Court in CAS specifically
held that EPCA permits the agency to
consider consumer demand and the
resulting market shifts in setting fuel
economy standards. See, CAS at 1323.
This precedent is contrary to the
commenters’ assertion that a backstop or
ratcheting mechanism is statutorily
required. The Courts have said that
none of the four criteria are preeminent.
Instead the agency must balance the
four criteria in establishing fuel
economy standards.
NRDC and the Union of Concerned
Scientists stated that historic rates of
vehicle upsizing and the potential for
fleet upsizing through shifts in
production towards vehicles with larger
footprints necessitate a backstop or
ratcheting mechanism. These
commenters stated that historic
increases in light truck foot print and a
shift in production of nameplates
offered with longer wheelbases could
result in a 30 percent and one percent
reduction in the projected fuel savings,
respectively. As such, commenters
suggested that the agency adopt a
backstop or ratcheting mechanism that
would apply if the light truck fleet
increased in size beyond some
threshold, but did not identify what
such a threshold should be.
The regulatory mechanisms suggested
by commenters would essentially limit
the ability of manufacturers to respond
to market shifts arising from changes in
consumer demand. If consumer demand
shifted towards larger vehicles, a
manufacturer potentially could be faced
with a situation in which it must choose
between limiting its production of the
demanded vehicles, and failing to
comply with the CAFE light truck
standard. Forcing such a choice would
be contrary to the congressional intent
for establishing EPCA.
Congress directed that:
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[A]ny regulatory program must be carefully
drafted so as to require of the industry what
is attainable without either imposing
impossible burdens on it or unduly limiting
consumer choice as to the capacity and
performance of motor vehicles.
H. Rep. 94–340 (p. 87). The Court’s
determination in CAS reflects this
congressional directive. These
comments, on the other hand, seem
unaware of it. Consideration of
consumer demand is a permissible one
under EPCA.
A backstop could also have the
unintended consequence of resulting in
downsizing by manufacturers, which
could have negative safety implications.
A manufacturer facing the potential of
failing to comply with a backstop might
shift its production to smaller, lighter
vehicles.
Furthermore, a ratcheting mechanism
could result in a manufacturer required
to comply with a fuel economy level
that violates EPCA. Under the Reformed
CAFE system, a manufacturer’s required
fuel economy level is based on targets
that represent the fuel savings
capabilities of vehicles with a given
footprint value. Targets are set with
consideration of the technological
feasibility of improving the fuel
economy of vehicles given their
footprint. As such, the Reformed CAFE
system encourages manufacturers to
undertake reasonable efforts to improve
the fuel economy of all its light trucks.
If the stringency of targets were
automatically increased due to a
predetermined trigger, the resulting
changes to required fuel economy levels
would be beyond what was established
after careful consideration of the
statutory criteria, including the
technological and economic capabilities
of the industry. This result would
violate EPCA.
Commenters also presented additional
scenarios (i.e., upsizing at category
boundaries and upweighting to remove
vehicles from the light truck CAFE
program) that they argued would likely
result in some loss of fuel savings.
These additional scenarios are
addressed below. As discussed further
below, concerns raised by these
additional scenarios are addressed
through the Reformed CAFE system
adopted today.
3. Transition Period
The agency is providing a transition
period during MYs 2008–2010, during
which manufacturers may choose to
comply with the Unreformed CAFE
standard or the Reformed CAFE
standard. This transition period will
minimize the potential for unintended
compliance burdens that may be
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experienced by a manufacturer as the
result of shifting to a new regulatory
structure. The transition period is
critical given that this is the first
comprehensive reform of the light truck
CAFE program since its inception.
The transition period is consistent
with the recommendation of the NAS
report. The NAS report stated that a
restructuring of the CAFE system should
include a phase-in period in order to
provide manufacturers an opportunity
to analyze the implications of the new
standards and to redo their product
plans (see NAS Report at 108). The
Reformed CAFE standard will require
certain manufacturers to improve their
fleets, when in the past these
manufacturers did not need to be
concerned with the light truck CAFE
program. These manufacturers are those
that produce fleets predominately
comprised of small light trucks, which
by virtue of their small size have high
fuel economies. These manufacturers
traditionally had high fleet wide fuel
economies that were above the standard.
However, the Reformed CAFE system,
by comparing vehicles to footprint
specific targets will require more
manufacturers to improve their fleets’
fuel economy performance beyond the
baseline of the manufacturers’ product
plans.
Furthermore, the structure of the
Reformed CAFE might require some
manufacturers to revise their
compliance strategies. For example and
as explained below, the Reformed CAFE
system minimizes the ability of
manufacturers to offset the low fuel
economy performance of larger vehicles
by increasing the production of smaller
vehicles with higher fuel economies.
Manufacturers that relied on such a
compliance strategy in the past might
need to revise their product plans in
order to comply with the Reformed
CAFE standard. The transition period is
an opportunity for manufacturers to
gain experience with how the Reformed
CAFE system impact their fleets and
compliance strategies, while still
providing manufacturers the option to
comply under the more familiar
Unreformed CAFE system.
Several commenters questioned
whether the agency had authority to
establish a transition period during
which manufacturers could choose to
comply with one of two standards. The
Union of Concerned Scientists stated
that the transition period would lead to
a ‘‘worst of both worlds’’ scenario; each
manufacturer would comply with the
CAFE system that provided the lower of
the two required fuel economy levels.
The Union of Concerned Scientists
estimated that under this scenario, the
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actual light truck fuel economy in the
transition years would be as much as 0.4
mpg lower than it would be under either
the Reformed CAFE system or the
Unreformed CAFE system.
First, we are unable to predict how
manufacturers will choose to comply
during the transition period. Some
manufacturers might choose to continue
to comply under the Unreformed CAFE
system, given that it is a regulatory
structure with which they are familiar.
Some manufacturers might plan to
comply with the Unreformed CAFE
program, but determine that they
comply with the Reformed CAFE, and
therefore to gain experience with the
new system switch to the Reformed
system. Other manufacturers may
choose to gain early experience with the
Reformed CAFE system and choose to
comply with the Reformed CAFE system
for all 3 years of the transition. We have
concluded that it is prudent to provide
manufacturers this flexibility in order to
provide for a more orderly transition to
Reformed CAFE.
Second, this is not the first time that
the CAFE program provided
manufacturers a choice of standards
under which to comply. In 1979,
manufacturers were given the option of
complying with the 4x4 and 4x2
standards separately or combining all
their trucks into one fleet and
complying with the 4x2 numerical level.
In 1983–1991, manufacturers were
provided the option of complying with
standards applicable to their 4x4 light
truck fleet and 4x2 light truck fleet
separately, or complying with a single
combined standard applicable to their
entire fleet. In establishing the later
option, we stated that it provides
manufacturers additional flexibility in
complying (45 FR 81593, 81594
(December 11, 1980)). We also noted
that such a compliance mechanism
provides a degree of stability in the
standard setting structure of CAFE (see,
id.). Although the substance of the
compliance options adopted in this
document differs from those that gave
rise to compliance options in previous
model years, the rationale is the same.
Manufacturers commented that the
flexibility of a transition period is
necessary for manufacturers to
understand the new system and avoid
unintended consequences when
revising compliance strategies and
product plans. Toyota noted that the
current system has been in place for
over 25 years, and therefore, a 3-year
transition is appropriate for
manufacturers to better understand how
to plan for and implement the Reformed
CAFE system. The Alliance, General
Motors, and Mitsubishi stated that 3
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years of lead-time is the minimum
necessary to comply with the required
fuel economy levels under the Reformed
CAFE structure. Nissan stated that the
stringency of the required fuel economy
levels that results from the Reformed
CAFE system will be extremely
challenging, given the significant
changes to the CAFE system that must
be incorporated into a manufacturer’s
product planning process. Nissan
suggested that because the proposed
regulatory changes are so much more
extensive than merely setting new CAFE
levels, which Nissan claims the agency
has stated requires at least 30–36
months lead time, an even longer phasein may be appropriate.
General Motors stated that the
availability of the traditional standards
during MY 2008–2010 would provide a
safety net against unintended
consequences from the reform process.
However, General Motors stated that the
agency need not establish the MY 2011
Reformed CAFE standards in the current
rulemaking. Instead, General Motors
urged, NHTSA should await the
experience and data that the transition
period will produce. General Motors
expressed concern that if the Reformed
CAFE targets begin to increase
significantly because of new analytical
methodologies, time to fully address all
of the relevant issues may not be
available due to statutory deadlines. In
such an instance, General Motors
commented that a standard grounded in
the ‘‘least capable manufacturer’’ might
be preferable.
Manufacturers develop product plans
for their fleets at least 5 years in
advance, plans which incorporate
consideration of CAFE compliance. As
such, manufacturers have already begun
investing in their fleets for some of the
model years that are subject to today’s
final rule. Some manufacturers may
determine that it will be necessary to
adjust their product plans based on the
new CAFE structure. Given the
uncertainty associated with how a
manufacturer will perform under
Reformed CAFE, we are providing a
transition period.
In addition to providing
manufacturers the option of complying
under either CAFE system during the
transition period, we adjusted the
Reformed CAFE standard such that the
industry wide compliance costs are
approximately equal between the two
systems. Cost equalization has an
important advantage. Since the
Unreformed CAFE standards were
judged to be economically practicable
and since the Reformed CAFE standards
spread the cost burden across the
industry to a greater extent, equalizing
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the costs between the two systems
provides the agency with confidence
that the Reformed CAFE standards are
also economically practicable.75
Further, this approach promotes an
orderly and effective transition to the
Reformed CAFE system since
experience with the new system will be
gained prior to full implementation in
MY 2011.
Several commenters questioned
whether the agency had the authority to
equalize compliance costs during the
transition period. The Union of
Concerned Scientists and ACEEE stated
that equalizing costs during the
transition years and not setting them at
a level at which marginal costs equaled
marginal benefits, resulted in Reformed
CAFE standards are not set at the
‘‘maximum feasible’’ level. Therefore,
these commenters concluded that the
Reformed CAFE standards during the
transition period would not comply
with EPCA.76
With regard to the agency’s authority
for establishing standards under EPCA,
the agency is not limited to the
considerations provided for in the
statute when determining what fuel
economy levels will be maximum
feasible. For example, the agency also
considers the effect that the CAFE
standards will have on safety.77 Just as
safety is an appropriate consideration in
determining maximum feasible fuel
economy levels, so is the need for an
orderly transition to a CAFE system that
provides greater fuel savings than the
current system.
Because we equalized aggregate
industry costs between Reformed and
Unreformed CAFE, the costs are not
borne by manufacturers in the same way
and costs for individual manufacturers
may differ between the two systems.
Therefore, some manufacturers may
have a cost incentive to comply under
the Reformed CAFE system beginning in
MY 2008. This will provide both the
industry and the agency with
75 We equalized aggregate industry costs between
Reformed and Unreformed CAFE. The costs are not
borne by manufacturers in the same way and costs
for individual manufacturers may differ between
the two systems.
76 Additionally, the ACEEE recommended that
the transition period be structured so that all
manufacturers pay compliance costs equal to the
least capable manufacturer, but did not provide
details as to how the standards would be set, or
whether such standards would be technologically
feasible.
77 The United States Court of Appeals pointed out
in upholding NHTSA’s exercise of judgment in
setting the 1987–1989 passenger car standards,
‘‘NHTSA has always examined the safety
consequences of the CAFE standards in its overall
consideration of relevant factors since its earliest
rulemaking under the CAFE program.’’ Competitive
Enterprise Institute v. NHTSA (CEI I), 901 F.2d 107,
120 at n.11 (D.C. Cir. 1990).
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experience in compliance with and the
administration of the new system.
Further, some manufacturers may chose
to comply under the Reformed CAFE in
order to gain a familiarity with the new
system. As such, the cost equalization
will promote an orderly and effective
transition to the Reformed system.
The equalization of costs provides the
industry greater flexibility in adjusting
to the Reformed CAFE system. The
three-year transition period as adopted
encourages experimentation by
manufacturers, which we conclude will
effect a quicker transition than would
result by either implementing an abrupt
change after providing appropriate lead
time or maintaining the status quo. The
Reformed CAFE program provides for
greater fuel savings. By effecting a
quicker transition period, greater fuel
savings will be realized over time,
thereby furthering EPCA’s goal of
improving fuel savings.
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D. Structure of Reformed CAFE
1. Footprint Based Function
The proposed Reformed CAFE system
was premised on using vehicle footprint
to establish fuel economy targets for
light trucks of different sizes. We noted
that vehicle weight and shadow 78 were
discussed in the ANPRM, but along
with commenters to the ANPRM, we
had concerns that weight and shadow
could more easily be tailored for the
sole purpose of subjecting a vehicle to
a less stringent target (70 FR 51440). As
a result, both of those attributes, if used
as the foundation of our program, could
fail to achieve our goal of enhancing
fuel economy with a Reformed CAFE
program, and use of weight could fail to
achieve our goal of improving the safety
of the program.
Vehicle footprint is more integral to a
vehicle’s design than either vehicle
weight or shadow and cannot easily be
altered between model years in order to
move a vehicle into a different category
with a lower fuel economy target.
Footprint is dictated by the vehicle
platform, which is typically used for a
multi-year model lifecycle. Short-term
changes to a vehicle’s platform would
be expensive and difficult to accomplish
without disrupting multi-year product
planning. In some cases, several models
share a common platform, thus adding
to the cost, difficulty, and, therefore,
unlikelihood of short-term changes.
Vehicle footprint is the area defined
by vehicle wheelbase multiplied by
vehicle track width. The proposal
defined wheelbase as the longitudinal
distance between front- and rear-wheel
78 ‘‘Shadow’’ is the area defined as the vehicle’s
length multiplied by the vehicle’s width.
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centerlines. The proposed track width
definition was based on the Society of
Automotive Engineers (SAE) definition
in W101 of SAE J1100, Surface Vehicle
Recommended Practice, revised July
2002, which reads as follows:
The lateral distance between the
centerlines of the base tires at ground,
including the camber angle.79 However,
the agency was concerned that a
vehicle’s track width could be increased
by off-setting its wheels,80 at minimal
expense, and thus subjecting the vehicle
to a less stringent target. Therefore, the
agency modified the W101 definition for
the proposal to read as follows:
[T]rack width is the lateral distance
between the centerlines of the tires at ground
when the tires are mounted on rims with zero
offset.
Commenters generally supported the
use of footprint as a metric to categorize
light trucks. However, manufacturers
raised a variety of concerns with the
proposed definition of track width. The
Alliance disagreed with the agency’s
concern regarding the potential for
changes made to wheel offset. The
Alliance stated that manufacturers
determine wheel offsets based on
suspension geometry, ride, and
handling characteristics, weight and
vehicle drivability. As such, the
Alliance asserted that it would be
unlikely for a manufacturer would alter
a vehicle’s wheel offset in response to
the light truck CAFE program.
The Alliance, Ford, General Motors,
and BMW suggested that the agency
should define track width in accordance
with W113 in SAE J1100, which defines
track width as:
[T]he lateral distance between the wheel
mounting faces,81 measured along the
spindle axis.82
Conversely, Honda opposed use of
W113, stating that W113 and wheel
offset are related to packaging issues
79 Camber angle is the angle between the vertical
axis of the wheel of an automobile and the vertical
axis of the vehicle when viewed from the front or
rear. It is used in the design of steering and
suspension.
80 Wheel offset is the distance from where a wheel
is mounted to an axis to the centerline of the wheel.
The offset can be one of three types.
Zero Offset—The hub mounting surface is even
with the centerline of the wheel.
Positive—The hub mounting surface is toward the
front or wheel side of the wheel. Positive offset
wheels are generally found on front wheel drive
cars and newer rear drive cars.
Negative—The hub mounting surface is toward
the back or brake side of the wheels centerline.
‘‘Deep dish’’ wheels are typically a negative offset.
81 A spindle axis is the rotating arm, or axis, unto
which the wheels are attached.
82 W113 was added to SAE J1100 in September
of 2005, after the agency published the NPRM. (A
spindle axis is the rotating arm, or axis, unto which
the wheels are attached.)
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inside the wheel area, but not relevant
to issues such as wear and dynamic
performance. Honda stated that the
W113 measurement could be increased
without any change to vehicle size or
dynamic performance by using wheels
with a larger positive offset.
Nissan recommended using SAE
J1100 W101, which is based on the
centerline of a vehicle’s tires at the
ground. Nissan stated that it relies on
the W101 measurement for handling
performance design considerations as
well as safety performance design.
Nissan stated that there is little
incentive to manipulate the W101
measurement because even minor
adjustments affect handling. Honda
added that use of the tire centerline has
more relevance to rollover risk.
The definition of footprint adopted in
today’s final rule incorporates the
definition of track width as defined in
W101. The agency has reviewed the
three different definitions of track width
and has determined that there is the
potential to affect the measurements
under each definition. The definition
proposed by the agency can be affected
through changes to a wheel’s camber
angle and the thickness of the wheel
mounting face (e.g., through the
addition of washers). The measurement
under W113 could be affected by the
thickness of the wheel mounting face.
The measurement under W101 can be
affected by changes to wheel offset
(positive or negative offset), camber
angle, and the thickness of the wheel
mounting face.
However, W101 is most directly
linked to safety in terms of rollover risk,
as stated by Honda. The W101
measurement is taken where a vehicle’s
tires touch the ground and is used by
NHTSA in calculating a vehicle’s Static
Stability Factor. If a manufacturer were
to increase a vehicle’s footprint through
increasing its track width, there likely
would be a positive safety effect.
We also believe that use of the vehicle
footprint attribute helps us achieve
greater fuel economy without having a
potential negative impact on safety.
While past analytic work 83 focused on
the relationship between vehicle weight
and safety, weight was understood to
encompass a constellation of sizerelated factors, not just weight. More
recent studies 84 have begun to consider
83 See, Kahane (2003) and Van Auken, R.M. and
J.W. Zellner, An Assessment of the Effects of
Vehicle Weight on Fatality Risk in Model Year
1985–98 Passenger Cars and 1985–97 Light Trucks,
Dynamic Research, Inc. February 2002. Docket No.
NHTSA 2003–16318–2.
84 See, Van Auken, R.M. and J.W. Zellner,
Supplemental Results on the Independent Effects of
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whether the relationship between
vehicle size and safety differs. To the
extent that mass reduction has
historically been associated with
reductions in many other size attributes
and given the construct of the current
fleet, we believe that the relationship
between size or weight (on the one
hand) and safety (on the other) has been
similar, except for rollover risks.
Developing CAFE standards based on
vehicle footprint encourages compliance
strategies that decrease rollover risk.
Manufacturers are encouraged to
maintain track width because reducing
it would subject the vehicle to a more
stringent fuel economy target.
Maintaining track width potentially
would allow some degree of weight
reduction without a decrease in overall
safety. Moreover, by setting fuel
economy targets for light trucks with the
smallest footprints that approach (or
exceed) 27.5 mpg, the agency is
providing little incentive, or even a
disincentive, to design vehicles to be
classified as light trucks in order to
comply or offset the fuel economy of
larger light trucks.
The influence of Reformed CAFE on
track width is reinforced by our New
Car Assessment Program (NCAP)
rollover ratings. As stated above, track
width as defined by SAE J100 W101 is
one of the elements of our Static
Stability Factor, which constitutes a
significant part of our NCAP rollover
ratings and which correlates closely
with real world rollover risk. The
rollover NCAP program (as well as real
world rollover risk) reinforces Reformed
CAFE by a separate disincentive to
decrease track width.
Overall, use of vehicle footprint is
‘‘weight-neutral’’ and thus does not
exacerbate the vehicle compatibility
problem. A footprint-based system does
not encourage manufacturers to add
weight to move vehicles to a higher
footprint category. Nor would the
system penalize manufacturers for
making limited weight reductions. By
using vehicle footprint in lieu of a
weight-based metric, we are facilitating
the use of promising lightweight
materials that, although perhaps not
cost-effective in mass production today,
may ultimately achieve wider use in the
fleet, become less expensive, and
enhance both vehicle safety and fuel
economy.85 In Reformed CAFE,
Curb Weight, Wheelbase, and Track on Fatality Risk
in 1985–1997 Model Year LTVs, Dynamic Research,
Inc. May 2005. Docket No. NHTSA 2003–16318–17.
85 The Aluminum Association commented that
using aluminum to decrease a vehicle’s weight by
10 percent could improve its fuel economy by 5–
8 percent. The commenter noted that the Honda
Insight, an all aluminum vehicle, is 40 percent
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lightweight materials can be
incorporated into vehicle design
without moving a vehicle into a
footprint category with a more stringent
average fuel economy target.
2. Continuous Function
In the NPRM, we proposed a
Reformed CAFE structure utilizing a
step function that established fuel
economy targets for vehicles within
specified ranges of footprint values. We
also discussed and sought comments on
an alternative structure that would use
a continuous function to establish a
different fuel economy target for each
discrete footprint value. In today’s final
rule, we are adopting a Reformed CAFE
structure that employs such a
continuous function.
The process for establishing a
continuous function is similar to that for
establishing a step function, which was
described in detail in the NPRM.
Moreover, a CAFE system based on a
continuous function will provide fuelsaving benefits equivalent to those of
the proposed step function. By varying
a vehicle’s fuel economy target
continuously but gradually as its
footprint changes, a continuous function
will reduce the incentive created by a
step function to upsize a vehicle whose
footprint is near a category boundary.
By comparison, the proposed step
function would have relaxed fuel
economy targets significantly for any
vehicle that could be upsized so that it
moves from one category up to the next.
At the same time, the continuous
function will also minimize the
incentive to downsize a vehicle to
improve its fuel economy since, unlike
under the proposed category system,
any reduction of footprint will raise a
vehicle’s fuel economy target. A
continuous function also provides
manufacturers with greater regulatory
certainty because there are no category
boundaries that could be redefined in
future rulemaking. These points are
discussed in greater detail below.
a. Overview of Establishing the
Continuous Function Standard
The continuous function standard is
developed using a three-phrase process
substantially similar to that used to
develop the step function standard
described in the NPRM. In ‘‘phase one,’’
the agency adds fuel saving technologies
to each manufacturer’s fleet until the
incremental cost of improving its fuel
lighter than a comparable steel vehicle. It also
provided data to demonstrate that all aluminum
vehicles have comparable performance in frontal
barrier crash tests as comparable steel vehicles. See
comments provided by the Aluminum Association,
Inc. (Docket No. 2003–16128–1120, pp. 5 and 12).
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economy further just equals the
incremental value of fuel savings and
other benefits from doing so. This is
done for each of the seven largest
manufacturers. Data points representing
each vehicle’s size and ‘‘optimized’’ fuel
economy from the light truck fleets of
those manufacturers are then plotted on
a graph.
In ‘‘phase two,’’ a preliminary
continuous function is statistically fitted
through these data points, subject to
constraints at the upper and lower ends
of the footprint range. This contrasts
with the proposed step function
standard, in which the vehicle models
of the improved fleets were placed in
the pre-defined footprint categories and
the harmonic average fuel economy of
the models assigned to each category
was used to determine the preliminary
target for that category. With a
continuous function, the agency sets
different fuel economy targets for each
increment or value of vehicle footprint,
rather than setting targets, that would
each apply to a range of footprint
values.
However, establishing fuel economy
targets that vary gradually by vehicle
footprint does not differ fundamentally
from the proposal to set different targets
for specific footprint ranges. If the
number of footprint categories in a step
function were steadily increased, the
relationship of fuel economy targets to
vehicle footprint would increasingly
resemble that under a continuous
function. In fact, as the number of
footprint categories in a step function
increased, the fuel economy targets it
established would apply to
progressively smaller footprint ranges,
until each category consisted of a single
value of footprint just as under the
continuous function.
Once a preliminary continuous
function has been statistically fitted to
the data for a model year, the level of
the function is then adjusted just as the
step function is adjusted in ‘‘phase
three’’ of the proposed rule. That is, the
preliminary continuous function is then
raised or lowered until industry-wide
net benefits are maximized.
Maximization occurs when the
incremental change in industry-wide
compliance costs from adjusting it
further would be exactly offset by the
resulting incremental change in
benefits.
Under a continuous function, the
level of CAFE required for each
manufacturer (and its compliance with
that level) is determined in exactly the
same fashion as under the proposed step
function. Each manufacturer’s required
CAFE level is the sales-weighted
harmonic average of the fuel economy
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targets corresponding to the footprint of
each of its light truck models. Its
compliance with that CAFE level is
assessed by comparing the salesweighted harmonic average of each of
its model’s actual fuel economy to this
required level. The key difference is that
under the continuous function, any
change in a vehicle’s footprint subjects
it to a slightly different fuel economy
target, thus changing a manufacturer’s
required CAFE level slightly.
Conversely, under the step function,
changing a vehicle’s footprint would
subject it to a new target—and thus
change a manufacturer’s required CAFE
level—only if that change moved it to a
smaller or larger footprint category.
B. Industry-Wide Considerations in
Defining the Stringency of the Standard
In setting standards under the
proposed Reformed CAFE system, we
focused on the seven largest
manufacturers of light trucks in
selecting the targets. This differs from
the traditional focus on the
manufacturer with the lowest projected
level of CAFE that also has a significant
share of the market (i.e., the ‘‘least
capable’’ manufacturer). We have
traditionally set the Unreformed CAFE
standards with particular regard to the
‘‘least capable’’ manufacturer with a
significant market share in response to
language in the conference report on the
CAFE statute directing the agency to
consider industry-wide factors, but not
necessarily to base the standards on the
manufacturer with the greatest
compliance difficulties. As the NPRM
indicated, this ‘‘least capable’’
manufacturer approach was simply a
way of implementing the guidance in
the conference report in the specific
context of Unreformed CAFE. While this
approach has ensured that the standards
are technologically feasible and
economically practicable for all
manufacturers with significant market
shares, it limits the amount of fuel
saving possible under Unreformed
CAFE.
As previously explained, by basing a
manufacturer’s required fuel economy
level on that manufacturer’s individual
product mix, the Reformed CAFE
system provides for a more
individualized assessment of the
capabilities of each of the
manufacturers. Thus, Reformed CAFE
permits the agency to carefully assess
the capabilities of the ‘‘least capable
manufacturer,’’ as well as the
capabilities of the other manufacturers
that comprise nearly all of the light
truck market. Instead of requiring a
uniform level of CAFE—which is
inherently more challenging for
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manufacturers whose fleets have
relatively high percentages of larger
vehicles to meet than for those whose
product lines emphasize smaller
models—the Reformed system specifies
fuel economy targets that vary according
to vehicle footprint. These targets are
higher for smaller light trucks and lower
for large ones. By setting each
manufacturer’s required fleet-wide
CAFE level to reflect its size mix, the
Reformed system requires each
manufacturer to ensure the fuel
efficiency of its individual models,
regardless of their size distribution.
Porsche expressed disagreement with
NHTSA’s decision to consider only the
performance and capabilities of the
seven largest manufacturers, while not
considering the other four
manufacturers of light trucks
(Volkswagen, BMW, Porsche, and
Subaru). Porsche stated that the
Reformed CAFE standards do not truly
represent industry-wide considerations
if they do not consider this remaining
several percent of the light truck market,
particularly where many of these
manufacturers serve niche markets not
served by the seven largest
manufacturers.
With regard to Porsche’s suggestion
that the agency consider all
manufacturers in setting the targets, we
previously have addressed the degree to
which we consider manufacturers with
small shares of the light truck market. In
our 1996 rulemaking setting light truck
CAFE standard for MY 1998, NHTSA
faced a substantially similar argument
from Mercedes-Benz asserting that there
is a need to set the CAFE standards at
a level achievable by all light truck
manufacturers (i.e., even those
manufacturers with a very small market
share). In rejecting that suggestion, we
cited the language from the Conference
Report accompanying EPCA that directs
us to consider industry-wide
considerations and to not base the
standards on the manufacturer with the
greatest difficulties. Even under
Reformed CAFE, this aspect of CAFE
standard-setting has not changed since
that time.
The target setting process in this
rulemaking focuses on roughly 97
percent of the light truck market, a
figure that reflects industry-wide
considerations. Inclusion of all
manufacturers, even those with a very
small market share, has the potential to
skew the resulting CAFE targets so as to
decrease the overall stringency of the
standards. Such an approach would
depress the CAFE levels below the
maximum feasible capability of the rest
of the industry and reduce overall fuel
savings. We recognize that under the
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Reformed CAFE system, the degree to
which the standard would be depressed
by including the remaining very small
manufacturers likely would not be more
than 0.1 mpg on any given target.
However, this reduction would result in
a reduction in fuel savings. Balancing
the need of the Nation to conserve
energy, we have concluded to rely on
the largest seven manufacturers as
discussed.
c. Improving the Light Truck Fleet
The first phase in determining the
footprint targets was to determine
separately for each of the seven largest
manufacturers the overall level of CAFE
that would maximize the net benefits for
that manufacturer’s vehicles.
To find the socially optimal point for
each of these seven manufacturers (i.e.,
the point at which the incremental or
marginal change in costs equals the
incremental or marginal change in
benefits for that manufacturer), we used
the Volpe model to compute the total
costs and total benefits of exceeding the
baseline 86 CAFE by progressively larger
increments. We began by exceeding the
baseline by 0.1 mpg. We then used the
model to calculate the total costs and
total benefits of exceeding the baseline
by 0.2 mpg. The marginal costs and
benefits were then computed as the
difference between the total costs and
total benefits resulting from exceeding
the baseline by 0.1 mpg and the total
costs and benefits resulting from
exceeding the baseline by 0.2 mpg. We
then used the Volpe model to calculate
the total costs and total benefits of
exceeding the baseline by 0.3 mpg and
computed the difference between the
total costs and benefits between 0.2 mpg
and 0.3 mpg to determine the marginal
costs and benefits.
We continued making similar
iterations until marginal costs equaled
marginal benefits for that manufacturer.
Performing this iterative process
individually for each manufacturer
pushed each of the seven largest
86 An important distinction needs to be made
between the baseline and the manufacturer’s
product plan mpg. As discussed earlier, ‘‘baseline’’
is defined as the fuel economy that would exist
absent of the rulemaking (i.e., the model year 2007
standard of 22.2 mpg). The 22.2 mpg baseline
differs from the mpg level reported in a
manufacturer’s product plan. Some manufacturers
report fuel economy levels that are below 22.2 mpg.
In that case, the cost and benefits of going from the
product plan mpg to the baseline (22.2) mpg are not
counted as costs and benefits of the rulemaking, as
they were already counted in the MY 2005–2007
final rule. Only costs and benefits associated with
going from baseline mpg to a higher standard are
counted. It is important to note that since
technology is applied on a cost effective basis, the
most cost effective technologies will be used to get
a manufacturer from the product plan mpg to the
baseline mpg.
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manufacturers to a point at which net
benefits are maximized for each
manufacturer’s vehicles.
As a general concept, Toyota
expressed support for the agency’s use
of cost-benefit analysis in establishing
proposed CAFE standards, although it
asserted that NHTSA may have
underestimated costs and overestimated
potential benefits in developing its
proposal. Toyota also suggested that the
agency had relied too heavily on its
approach of using cost-benefit analysis
to determine a maximum feasible
standard, and in doing so had not
considered other relevant factors. Thus,
Toyota recommended that NHTSA
carefully review the assumptions in its
model in order to ensure that the
economically efficient fuel economy
targets it identifies nevertheless fall
within the practical constraints and
limitations of technology deployment.
Finally, Toyota also urged caution in
assessing any potential changes to the
CAFE targets resulting from increased
fuel prices.
As discussed previously,
DaimlerChrysler argued that in order to
ensure the economic practicability of
CAFE standards, NHTSA’s procedure of
establishing standards that maximize
net benefits must always be tempered by
considering the industry’s ability to
afford the required technologies.
DaimlerChrysler also argued that the
agency’s methodology for determining
‘‘maximum feasible’’ fuel economy
levels overestimates the potential of
technology to improve fuel economy,
while underestimating its costs. The
commenter suggested that setting
standards based upon ‘‘maximum
feasible’’ and ‘‘maximum net benefits’’
approaches will not necessarily yield
identical results in all cases.
As discussed above, the marginal
cost-benefit analysis is part of the
agency’s consideration of economic
practicability. Our analysis also
considered the financial condition of
the industry in determining technology
applications. The marginal cost-benefit
analysis, taken in conjunction with
these technology considerations,
provided fuel economy requirements
that were then subject to a sales and job
impact analysis. The totality of this
process, in conjunction with
consideration of the nation’s need to
conserve energy, the impacts of other
Federal standards, and societal impacts
such as safety, provides us with a
determination of ‘‘maximum feasible.’’
The Alliance cautioned that while it
is probably permissible for NHTSA to
use cost-benefit analysis in setting CAFE
standards, the agency should not rely
solely on this tool in determining their
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economic practicability. However, the
Alliance provided no ‘‘tool’’ to
determine economic practicability or an
individual manufacturer’s capability.
The Alliance argued that the proposed
CAFE standards pose significant
technical challenges and may be beyond
manufacturers’ capabilities, and thus
that NHTSA should not finalize
standards any higher than those
proposed in the NPRM, because higher
targets would be unlikely to comply
with the statutory criteria of
technological feasibility and economic
practicability.87 The Alliance also noted
that the fuel economy improvements
required by the proposed standard
would come at a time when vehicles are
already significantly more fuel-efficient
than in recent years, thereby making
such fuel economy improvement much
more difficult and costly to achieve.
Finally, the Alliance also commented
that use of cost-benefit analysis makes
the agency’s estimates of the costs,
benefits, and applicability of certain
technologies more important than in
setting previous rules, and these
assumptions should therefore be fully
explained and documented.
Similarly, NADA commented that the
success of NHTSA’s CAFE reform
hinges upon the application of
appropriate information and
assumptions. For example, NADA stated
that because the cost-benefit analysis is
so critical to the establishment of CAFE
targets under the agency’s proposal,
there must be an accurate assessment of
real costs and real benefits. NADA
argued that applying cost-benefit
analysis to determine the level of CAFE
standards should be only one step in a
rigorous examination of their economic
practicability.
Honda requested confirmation that
once CAFE standards are set using
NHTSA’s proposed benefit-cost
approach, they will not be revised
simply because updated information
affecting the benefit or cost estimates
becomes available (e.g., new fuel prices
estimates), unless overwhelming need
can be demonstrated. According to
Honda, such changes would be
extremely disruptive to manufacturers’
product planning. Thus, Honda argued
that updated data should be considered
only for setting CAFE requirements that
87 According to the Alliance, once finalized, the
CAFE rule would mark seven consecutive years of
light truck fuel economy increases. The Alliance
argued that combined with previous increases for
MY 2005–2007, the current proposal would match
the highest seven-year rate of increase (2.2 percent
per year, the average from 1982–1989) in the history
of the light truck CAFE program, and it would be
more than 1.5 times the historical trend of fuel
efficiency improvements.
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would apply to model years beyond
those covered by the current rule.
Environmental Defense raised specific
objections to some of the assumptions
relied upon in the agency’s analysis, but
stated that the Reformed CAFE
standard-setting methodology itself is
reasonable. Environmental Defense
stated that the Reformed CAFE
approach provides greater transparency
than the Stage analysis relied upon in
the Unreformed CAFE system.
In response to the manufacturers’
reservations about equating ‘‘maximum
feasible’’ fuel economy standards with
those that produce maximum net
benefits, the agency is aware of its
continuing statutory responsibility to
establish maximum feasible fuel
economy standards at levels that
simultaneously reflect consideration of
technological feasibility, economic
practicability, the effects of other
Federal vehicle standards, and the need
of the nation to conserve energy. The
approach for determining the
continuous function sets the fuel
economy targets just below the level
where the increased cost of technologies
that could be adopted by manufacturers
to improve fuel economy would first
outweigh the added benefits that would
result from such technology.
These targets translate into required
levels of average fuel economy that are
technologically feasible because
manufacturers can achieve them using
available technologies. Those levels also
reflect the need of the nation to
conserve energy because they reflect the
economic value of the savings in
resources, as well as of the reductions
in economic and environmental
externalities that result from producing
and using less fuel. We note that our
assumptions for each technology, its
cost, and its effectiveness are in the
FRIA (see FRIA Table VI–4). (However,
the application to each manufacturer is
confidential and therefore not included
in the docketed FRIA.)
In answer to comments from various
commenters that NHTSA’s process for
establishing fuel economy targets
overstates the fuel economy
improvements likely to result from
specific technologies and
underestimates manufacturers’ costs for
adopting those fuel economy
technologies, the agency again notes
that we have relied on the technology
cost and effectiveness estimates from
the NAS report. The estimates of fuel
economy technology effectiveness and
costs developed by NAS represent the
most reliable estimates that are
available. The alternative estimates of
technology costs and effectiveness
recommended by some commenters
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In the second phase, we plotted the
results of phase one (i.e., the light truck
fleets of the seven largest manufacturers,
each separately ‘‘socially optimized’’).
Then, we calculated a statistical
relationship through the plotted data
points (using production-weighted
nonlinear least squares regression). This
relationship defines a preliminary
continuous function (a ‘‘curve’’) that,
upon being adjusted, determines the
fuel economy targets for light trucks
based on vehicle footprint. Although
adjusted, the shape of the curve remains
unchanged throughout the equalincrement adjustments in phase three
below, because the absolute differences
(on a gallon-per-mile basis) between the
targets are unaffected by those
adjustments.
In its report, NAS illustrated a
function that set fuel economy targets
for vehicle based on weight. See Figure
2 below. Under the NAS function, fuel
consumption increased in a linear
manner as vehicle weight increased up
to 4,000 lbs. At 4,000 lbs, the function
leveled-off. The leveling of the function
at 4,000 lbs represented a ‘‘safety
threshold,’’ i.e., the NAS report
determined that there was a safety
benefit in minimizing the incentive to
up-weight vehicles beyond 4,000 lbs.
Under the NAS function, increasing a
vehicles weight beyond 4,000 lbs did
not subject a vehicle to a less stringent
fuel consumption value.
The agency considered relying on a
function as illustrated by NAS, but
determined that the NAS function
presented several problems. First, the
flattening of the function would be
expected to produce a milder form of
the ‘‘edge effects’’ that are of concern
under the step function. At the ‘‘safety
threshold’’ there would be an abrupt
change in the rate at which size
increases are rewarded. This abrupt
change could distort the production of
vehicles located near the threshold and
encourage manufacturers to potentially
downsize some vehicles to the threshold
point. Second, it is not clear whether
and, if so, where, in terms of footprint,
a true ‘‘safety threshold’’ occurs.
Without a ‘‘safety threshold’’ the NAS
function would be a simple linear
function, which as discussed below
introduces several potential problems.
Finally, there is a possibility that a
function based on the NAS illustration
could extrapolate to unreasonably high
levels for small vehicles.
As discussed below, the agency has
decided to use a constrained logistic
function to set the targets. We have
determined that a constrained logistic
function provides a good fit to the
optimized light truck fleet data, while
not resulting in potentially
impracticable high targets for very small
vehicles, or unreasonably low targets for
very large vehicles.
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d. Defining the Function and the
Preliminary Shape of the Curve
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have not been subjected to the same
level of expert review and public
scrutiny as those developed by NAS,
and are thus not suitable for use by
NHTSA in establishing fuel economy
standards.
In response to Honda’s request for
clarification regarding our position on
updating the standards when new data
become available, new data will be
relied upon for consideration of
standards beyond MY 2011. If the
agency were to consider increasing the
established standards for MY 20082011, we would need to be mindful of
lead time constraints and the need for
regulatory certainty (i.e., the need for
manufacturers to be able to rely on
today’s final rule to adjust their product
plans).
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The agency evaluated a variety of
mathematical forms to estimate the
relationship between vehicle footprint
and fuel economy. The agency
considered a simple linear function, a
quadratic function, an exponential
function, and an unconstrained logistic
function. Each of these relationships
was estimated in gallons per mile (gpm)
rather than miles per gallon (mpg). As
explained in the NPRM, the relationship
between fuel economy measured in mpg
and fuel savings is not linear. An
increase in one mpg in a vehicle with
low fuel economy (e.g., 20 mpg to 21
mpg) results in higher fuel savings than
if the change occurs in a vehicle with
high fuel economy (e.g., 30 mpg to 31
mpg). Increasing fuel economy by equal
increments of gallons per mile provides
equal fuel savings regardless of the fuel
economy of a vehicle. Increasing the
fuel economy of a vehicle from 0.06
gpm to 0.05 gpm saves exactly the same
amount of fuel as increasing the fuel
economy of a vehicle from 0.03 gpm to
0.02 gpm.88
Given that the agency is concerned
with fuel savings, gpm is a more
appropriate metric for evaluating the
functions. Therefore, we plotted the
‘‘socially optimized’’ fleets in terms of
footprint versus gpm. Once a shape of
a function was determined in terms of
‘‘gallons per mile,’’ the agency then
converted the function to mpg for the
purpose of evaluating the potential
target values. Figures 3A through 6B
below illustrate each of the functions as
sales weighted estimates of the
relationship between fuel economy of
the ‘‘socially optimized’’ fleets and foot
print, which were considered by the
agency.
BILLING CODE 4910–59–U
88 Lower fuel consumption represents a more
stringent value (i.e., a low gpm value equates to a
high mpg value)
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BILLING CODE 4910–59–C
After evaluating the functions above,
we determined that none of the
functions as presented would be
appropriate for the CAFE program. Each
of the four forms fit the data relatively
well within the footprint range observed
in the manufacturers’ product plans
(from about 40 square feet to about 85
square feet). However, at slightly
beyond the endpoints of the observed
range, the functional forms tended
towards excessively high stringency
levels at the smaller end of the footprint
range, excessively low stringency levels
at the higher end of the footprint end,
or both. Excessively high stringency
levels at the smaller end of the footprint
range potentially could result in target
values beyond the technological
capabilities of manufacturers.
Excessively low stringency levels at the
higher end of the footprint range
standards would reduce fuel savings
below that of the socially optimized
fleet.
As Figure 3A shows, a simple linear
functional form provides a reasonably
good fit for small vehicles, but results in
very low stringency for vehicles above
80 square feet would correspond to fuel
consumption values for very large
vehicles greater than the fuel
consumption for those vehicles under
the optimized fleet. Reliance on a linear
function would result in targets for large
light trucks that are well below the
optimized fuel economy, in terms of
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mpg, for those vehicles. These low
target values would reduce fuel savings
and provide a fuel economy incentive
for upsizing. Additionally, depending
on the distribution of the fleet, a simple
linear relationship could also produce
targets for very small vehicles well
above the corresponding data points.
Polynomial relationships between
footprint and fuel economy, such as a
quadratic function, result in fuel
consumption values that deviate
substantially from the data points at
either end of the footprint range.
Further, because of their inherent
curvature, polynomial functions often
result in less stringent mpg targets for
the smallest models than for slightly
larger vehicles, or mpg targets for the
largest models that are more stringent
than those for slightly smaller models.
As illustrated in Figure 4B, the convex
curvature of the function results in
increases in stringency for vehicles with
a footprint larger than about 70 square
feet. This increase is contrary to the data
points of the socially optimized fleet.
Under an exponential relationship,
the fuel economy targets tend towards
very high levels of stringency as
footprint declines below 40 square feet
(see Figure 5B). Under the exponential
function for footprint values smaller
than the smallest vehicle in the planned
fleet are more a characteristic of the
function, as opposed to representing the
technological capabilities of such
vehicles. A similar increase in targets
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occurs under a logistic function,
although not to the extent as with an
exponential function (see Figure 6B).
Under either an unconstrained
exponential or an unconstrained logistic
function, if a manufacturer were to
introduce a vehicle with a footprint
smaller than that considered in the
optimized fleet, that vehicle would be
compared to a fuel economy target
potentially beyond the level that would
be achieved had the agency ‘‘optimized’’
that vehicle. Such a target likely would
be difficult to achieve using available
technology. If a market demand were to
develop for light trucks smaller than the
smallest light truck currently planned
by manufacturers, targets based on an
exponential relationship or a logistic
relationship could be technologically
infeasible and limit consumer choice.
To address this issue the agency
determined that it is necessary to
constrain the chosen function at the end
points of the footprint range. However,
imposing a constraint on an exponential
function prevents the curve from closely
fitting the actual relationship between
vehicle footprint and fuel economy
across much of the size spectrum. In
addition, exponential functions
constrained to reach a maximum mpg
value tended to have inconsistent
shapes when fitted to light truck data for
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the data points. The constrained logistic
function is illustrated below in gallons
per mile and inverted in miles per
gallon:
89 That is, the targets they established for models
for some footprint values declined rather than
increased between successive model years.
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different model years.89 Therefore, the
agency decided to use a constrained
logistic function to fit the target curve to
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or near this footprint value causes
associated fuel consumption values to
sharply decrease. This translates to
rapidly increasing targets as footprint
decreases below 40 square feet.
Constraining the function also
minimizes the potential for a
disproportionate influence from a single
vehicle model on the curve, the agency
has constrained the target values at the
ends of the range.
Constraining the upper and lower
bounds in this manner has the
additional benefit of generating a curve
that closely tracks the shape of the
proposed step-function. We have
constrained this function so that the
smallest/largest vehicles face similar
stringency that was found in the
smallest/largest categories in the step
function.
The constrained logistic function
selected by the agency is defined by four
parameters. Two parameters establish
the function’s upper and lower bounds
(i.e., asymptotes), respectively. A third
parameter specifies the footprint at
which the function is halfway between
the upper and lower bounds. The last
parameter establishes the rate or
‘‘steepness’’ of the function’s transition
between the upper (at low footprint) and
lower (at high footprint) boundaries.
The agency determined the values of
the parameters establishing the
function’s upper and lower bounds by
calculating the sales-weighted harmonic
average values of optimized fuel
economy levels for light trucks with
footprints below 43 square feet and
above 65 square feet, respectively.
Because these ranges respectively
include the smallest and largest models
represented in the current light truck
fleet, the agency determined that these
two segments of the light truck fleet are
appropriate for establishing the upper
and lower fuel economy bounds of a
continuous function.
The remaining two parameters (i.e.,
the ‘‘midpoint’’ and ‘‘curvature’’
parameters) were estimated using
production-weighted nonlinear leastsquares regression to achieve the closest
fit to data on footprint and optimized
fuel economy for all light truck models
expected to be produced during each of
model years 2008–2011.90 Described
mathematically, the logistic function is
as follows:
90 More precisely, these two parameters
determine the range between the vehicle footprints
where the upper and lower limits of fuel economy
are reached, and the value of footprint for which
the value of fuel economy is midway between its
upper and lower bounds.
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The constrained logistic function
provides a relatively good fit to the data
points without creating excessively high
targets for small vehicles, excessively
low targets for large vehicles, or regions
in which targets for large vehicles
exceed those for small vehicles. The
constrained logistic function also
produces a curve that provides an
acceptable fit to the light truck data
across all four model years.
Further, by constraining the function
at the ends of the footprint range, we
limit the potential for the curve to be
disproportionately influenced by a
single vehicle model located at either
end of the range. The vehicle population
decreases as the curve moves away from
the middle of the footprint range. The
low vehicle population levels provide
for a single vehicle model located at
either end of the range to have a greater
influence on its target, than a vehicle
with comparable production numbers
located in the middle of the range. This
greater influence translates to greater
influence on the shape of the curve. As
demonstrated in the unconstrained
logistic function, at a footprint value of
40 square feet a single model produced
in larger numbers than other vehicles at
Federal Register / Vol. 71, No. 66 / Thursday, April 6, 2006 / Rules and Regulations
Where,
T = the fuel economy target (in mpg)
a = the maximum fuel economy target
(in mpg)
b = the minimum fuel economy target
(in mpg)
c = the footprint value (in square feet)
at which the fuel economy target is
midway between a and b
d = the parameter (in square feet)
defining the rate at which the value
of targets decline from the largest to
smallest values
e = 2.718 91
x = footprint (in square feet, rounded to
the nearest tenth) of the vehicle
model
The resulting curve is an elongated ‘‘S’’shape, with fuel economy targets
decreasing as footprint increases.
e. Final Level of the Curve (and Targets)
The final step in the target setting
process is to adjust the level of the
preliminary curve defined in step two to
a level ‘‘optimized’’ for the entire fleet
produced by the seven largest
manufacturers. The preliminary curve is
gradually adjusted, by changing the
values of parameters (a) and (b) by equal
increments of fuel savings 92 until the
incremental change in total costs
incurred by all manufacturers for
complying with their respective CAFE
requirements (the sales-weighted
harmonic averages of the mpg targets for
their individual models specified by the
function) from a further adjustment
equals (within precision limits of the
analysis) the incremental change in the
benefits. Each light truck model’s final
fuel economy target can be determined
by entering its footprint (in square feet)
into the function with these revised
parameter values appropriate for its
model year, and calculating the
resulting value of fuel economy in miles
per gallon.
Once targets are calculated for each
vehicle in a manufacturer’s fleet under
the continuous function, the corporate
average fuel economy level required of
the manufacturer is calculated using a
harmonic average, as under the
proposed step function. A
manufacturer’s actual fuel economy is
calculated according to the procedure
used in the current CAFE system, and
compared to its required CAFE level in
order to assess whether it has complied
with the standard. Penalties and credits
are also determined and applied as
under the current and proposed CAFE
systems.
MYs 2008–2010. In each of the
transition years, we did not adjust the
17607
curve to the optimal level. Instead, we
adjusted the curve until the total
industry costs under the Reformed
CAFE program approximately equaled
the total industry costs under the
Unreformed CAFE program. Cost
equalization has several important
advantages, as explained above in the
discussion of the transition period.
Since the Unreformed CAFE standards
were judged to be economically
practicable and since the Reformed
CAFE standards spread the cost burden
across the industry to a greater extent,
equalizing the costs between the two
systems ensures that the Reformed
CAFE standards are within the realm of
economic practicability.93 Also, cost
equalization promotes an orderly and
effective transition to the Reformed
CAFE system by minimizing the cost
differences between the two choices.
MY 2011. The Reformed CAFE
standard for MY 2011 is set at the social
optimal level as described above, and is
not constrained by the costs of an
Unreformed standard. As previously
stated, all manufacturers are required to
comply with the Reformed CAFE
standard in MY 2011.
The parameter values for MYs 2008–
2011 are as follows:
TABLE 4.—PARAMETER VALUES FOR LOGISTIC FUNCTION
Model year
Parameter
2008
a
b
c
d
.......................................................................................................................
.......................................................................................................................
.......................................................................................................................
.......................................................................................................................
28.56
19.99
49.30
5.58
30.07
20.87
48.00
5.81
2010
29.96
21.20
48.49
5.50
2011
30.42
21.79
47.74
4.65
year. While individual manufacturers
may face different requirements for their
overall CAFE levels depending on the
distribution of footprint values for the
models making up their respective
product lines, each manufacturer is
subject to identical fuel economy target
for light truck models with the same
footprint value. Moreover, the same
91 For the purpose of the Reformed CAFE
standard, we are carrying e out to only three
decimal places.
92 Equal increments of mpg have differing energy
values. A 0.1 mpg increment added to a vehicle
with a higher mpg performance will have a lower
fuel savings value than an equal mpg increment
added to a vehicle with a lower mpg performance.
As such, we adjust the curve by equal increments
of fuel savings as opposed to mpg.
93 We equalized aggregate industry costs between
Reformed and Unreformed CAFE. The costs are not
borne by manufacturers in the same way and costs
for individual manufacturers may differ between
the two systems.
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The Reformed CAFE standard
establishes a relationship between
vehicle footprint and the fuel economy
target for light trucks with different
footprint values. In effect, today’s final
rule establishes a category system like
that proposed in the NPRM, in which
each footprint value is its own category,
and has an associated fuel economy
target.
The required level of CAFE for each
manufacturer during a model year is the
production-weighted harmonic average
of the fuel economy targets for each
model in its product line for that model
3. Application of the Continuous
Function Based Standard
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formula is used to determine each
manufacturer’s required level of CAFE
using the fuel economy targets for
different footprint values, footprint
values for its individual models, and the
production levels of each of its models.
Individual manufacturers face different
required CAFE levels only to the extent
that they produce different size mixes of
vehicle models.
To determine whether it has achieved
its required overall CAFE level, each
manufacturer’s production-weighted
harmonic average of the actual fuel
economy levels for each model in its
entire product line is compared to this
required CAFE level. If the weighted
average of its models’ actual fuel
economy levels is at least equal to the
manufacturer’s required level of average
fuel economy, then it has complied with
the Reformed CAFE standard. If its
actual fleet-wide average fuel economy
level is greater than its required CAFE
level, the manufacturer earns credits
equal to that difference that can be used
in any of the three preceding or
following model years.
More specifically, the manner in
which a manufacturer’s required overall
CAFE for a model year under the
Reformed system is computed is similar
to the way in which its actual CAFE for
a model year has always been
calculated. Its required CAFE level is
computed on the basis of the production
and the footprint target as follows:
Manufacturer X’s Total Production of Light Trucks
= X’s required level of CAFE
X’s production at footprint m X’s production at footprint n
c
+
+ etc
Target for footprint m
Target for footprint n
This formula can be restated as
follows:
Where:
N is the total number (sum) of light
trucks produced by a manufacturer,
Ni is the number (sum) of the ith model
light truck produced by the
manufacturer, and
Ti is fuel economy target of the ith model
light truck.
The required level is then compared
to the CAFE that the manufacturer
actually achieves in the model year in
question:
Where,
N is the total number (sum) of light
trucks produced by the
manufacturer,
Ni is the number (sum) of the ith model
light trucks produced by the
manufacturer,
mpgj is the fuel economy of the ith
model light truck.
A manufacturer is in compliance if
the actual CAFE meets or exceeds the
required CAFE.
The method of assessing compliance
under Reformed CAFE can be further
explained using an illustrative example
of a manufacturer that produces four
models in two footprint categories with
fuel economy targets assumed for the
purposes of the example shown in Table
3:
TABLE 5.—ILLUSTRATIVE EXAMPLE OF METHOD OF ASSESSING COMPLIANCE UNDER A CONTINUOUS FUNCTION APPROACH
Fuel economy
(mpg)
Model
.......................................................................................................................
.......................................................................................................................
......................................................................................................................
......................................................................................................................
100,000
100,000
100,000
100,000
achieve an average fuel economy level
of:
43.00
42.00
52.00
54.00
Footprint
(mpg)
27.5
27.8
23.7
23.2
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Under Reformed CAFE, the
manufacturer would be required to
27.0
24.0
22.0
19.0
Footprint
(sq. ft.)
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A
B
C
D
Production
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17609
This fuel economy figure would be
compared with the manufacturer’s
actual CAFE for its entire fleet (i.e., the
production-weighted harmonic mean
fuel economy level for four models in its
fleet):
In the illustrative example, the
manufacturer’s actual CAFE (22.6 mpg)
is less than the required level (25.4
mpg), indicating that the manufacturer
is not in compliance.
some important advantages over a
stepwise function. However, we did not
propose a specific mathematical form
for a continuous function.
As explained above, the agency has
elected to adopt a Reformed CAFE
system that employs a continuous
function to set fuel economy targets. Use
of a continuous function addresses three
major concerns raised by commenters
with regard to the proposed Reformed
CAFE structure. Reliance on a
continuous function (1) eliminates
potential problems associated with the
need to redefine category boundaries in
future rulemakings; (2) substantially
reduces the incentive for manufacturers
to ‘‘upsize’’ vehicles; and (3)
substantially reduces the incentive for
manufacturers to respond to the CAFE
requirements through downsizing, a
compliance option that can reduce a
vehicle’s safety. The following explains
these three benefits in detail.
First, reliance on a continuous
function eliminates the footprint based
categories. By eliminating categories, we
eliminate the need to redefine categories
as the light truck distribution changes.
In the NPRM, we prescribed a method
for determining category boundaries.
The method was intended to reduce the
potential for ‘‘edge effects.’’ We noted
that when the distribution of light
trucks was graphed such that footprint
increased from left to right, vehicles just
to the left of a boundary faced the
greatest incentive for upsizing. These
vehicles could be moved into a less
stringent category with relatively minor
increases in size.
In order to minimize this potential,
we defined the proposed boundaries
generally at points on the graph where
there was relatively low vehicle volume
immediately to the left and high vehicle
volume immediately to the right.
Identification of points between low and
high volume was based on the
distribution of vehicles from the
product plans provided to the agency in
response to the 2003 ANPRM. Based on
this distribution, the agency was able to
readily identify appropriate boundary
locations, as illustrated in Figure 9
below.
4. Why This Approach To Reform and
Not Another?
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a. Continuous Function vs. the Proposed
Step-Function (Categories)
The NPRM proposed a Reformed
CAFE system that would establish a
system of six size categories based on
vehicle footprint, and specify a target
fuel economy level for the vehicles in
each category. The categories and their
respective targets were incorporated
into a step function (see Figure 1,
above). The CAFE level required of each
manufacturer then would be determined
by computing the sales-weighted
harmonic average of the fuel economy
targets for each light truck category in
which it produces light trucks.
The NPRM also discussed and sought
comment upon the alternative of
incorporating the fuel economy targets
into a continuous function based on
vehicle footprint, which could have
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A variety of commenters also
recognized the potential for ‘‘edge
effects.’’ The Alliance asserted that the
agency’s selection of boundaries under
the step function effectively addressed
this potential problem, noting that it
‘‘agrees with the agency’s assessment
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that both the number and the location
of the boundaries for the footprint
categories would likely minimize any
such edge effects.’’
As previously indicated,
manufacturers provided updated
product plans in response to the NPRM
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and RFC. The new product plans
reflected a new distribution of vehicles.
When the proposed boundaries were
applied to the updated manufacturer
plans, the boundaries did not align with
low and high volume points, as in the
NPRM.
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updated fleet has a more uniform
distribution of vehicles across the
footprint range, there are multiple
potential boundary assignments that
would segment the light truck fleet into
six categories, and there is less
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opportunity to find boundaries that
would minimize ‘‘edge effects’’ to the
same extent as in the NPRM. Figures 11
and 12 illustrate potential ways by
which the agency might have attempted
to redefine the boundaries.
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As illustrated in Figure 10 above, the
distribution of the updated light truck
fleet does not provide clear points of
low volume adjacent to high volume as
was the case with the older fleet that
was the basis for the NPRM. Because the
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However, it was clear that because of
the distribution of the light truck fleet
in the revised product plans, there was
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not the opportunity to provide category
divisions that similarly minimize ‘‘edge
effects’’ to the same degree as in the
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NPRM. Moreover, Toyota was
concerned that changes to boundaries
could significantly alter a
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manufacturer’s compliance
responsibility, and urged the agency to
rely on the proposed boundaries for the
final rule.
As recognized by Toyota, the required
fuel economy level of individual
manufacturers is highly influenced by
boundary location. Table 6 below
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illustrates the required fuel economy for
a sampling of manufacturers if
boundaries were set according to the
figures above.
TABLE 6.—REQUIRED FUEL ECONOMY LEVELS UNDER VARIOUS BOUNDARY LOCATIONS
Required fuel economy (mpg)—boundaries set according
to figure 11
Manufacturer
Required fuel economy (mpg)—boundaries set according
to figure 12
23.3
23.8
24.2
23.2
23.8
23.7
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General Motors ........................................................................................................................................
Toyota ......................................................................................................................................................
Nissan ......................................................................................................................................................
The potential need to redefine
category boundaries from one model
year to the next and one rulemaking to
the next would create uncertainty for
manufacturers. Manufacturers would
face not only the potential of a vehicle
facing a higher target resulting from
shifts in the function, but would also
face the potential of a vehicle being
compared to a much more stringent
target as the result of a boundary shift.
By utilizing a continuous function, the
agency eliminates boundaries and thus
the potential difficulties associated with
defining and redefining category
boundaries.
Second, reliance on a continuous
function substantially reduces the
incentive for manufacturers to respond
to Reformed CAFE by ‘‘upsizing’’
vehicles. IIHS said that although the
boundaries in the proposed categorical
system were carefully chosen to
minimize the number of models that
were just below them, the differences
between fuel economy targets for some
adjacent categories were nevertheless
large enough to make upsizing an
important potential concern. For
vehicles just below boundaries, small
increases in footprint could produce a
significant reduction in fuel economy
target. As an example, IIHS stated that
based on the proposed categories,
General Motors could reduce the fuel
economy target applicable to the 2005
Chevrolet Trailblazer EXT by 1.5 mpg
by increasing that model’s track width
by 1.5 inches. The Mercatus Center
echoed this concern, citing calculations
showing that 14 of 55 light truck models
could be moved to the next larger
footprint category with an increase in
footprint of less than 2 percent.
Conversely, under a continuous
function, significant reductions in fuel
economy targets cannot be achieved
through small increases in footprint.
Fuel economy targets decrease gradually
as vehicle size increases, as compared to
the punctuated changes under a stepfunction. Again, using the Chevrolet
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Trailblazer as an example, IIHS noted
that in order to gain a 1.5 mpg
difference in its fuel economy target,
‘‘the Trailblazer’s footprint would have
to change by about the entire range of
one of the proposed footprint
categories.’’ Natural Resources Canada
stated that although any erosion of fuel
savings resulting from upsizing is
unlikely to be significant under a
stepwise function, ‘‘it is our opinion
that setting fuel economy targets using
a continuous function, based on
footprint, would eliminate any concern
in this regard.’’
In contrast to IIHS’s assertions, Toyota
argued that because a continuous
function relaxes a vehicle’s fuel
economy target for any increase in size,
a continuous function provides a greater
incentive for vehicle ‘‘upsizing.’’ Toyota
stated that under a continuous function,
manufacturers have a small incentive to
increase the size of every vehicle model
they produce, instead of a stronger
incentive to upsize only a few models.
The agency disagrees with Toyota.
While the agency acknowledges
Toyota’s argument that a continuous
function reduces a model’s fuel
economy target in response to any
increase in its size, this feature need not
provide an incentive for manufacturers
to upsize their vehicles if the form of the
function reflects the underlying
engineering relationship between size
and fuel economy.
Under the continuous function, as a
vehicle’s footprint increases, its
applicable target decreases. However,
the rate at which target levels decrease
is gradual. Further, an increase in a
vehicle’s footprint is not without cost.
Generally, as vehicle size increases, its
fuel economy performance decreases.
The decrease in fuel economy
performance can result from additional
weight added to achieve increased size
or result from design implications of
upsizing the vehicle (e.g., an increase
drag resistance from increased frontal
area). As such, increasing footprint can
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decrease a vehicle’s fuel economy,
further reducing the incentive to upsize.
Under the step function approach,
some vehicles were located near the
upper boundaries of the categories
despite agency efforts to minimize the
number. Under the step function
approach, a small change to the
footprint of these vehicles would result
in a substantial decrease in their targets,
as much as 1.2 mpg. The continuous
function approach does not provide an
opportunity for substantial decreases in
a vehicle’s target based on slight
increases to footprint.
This point can be illustrated by
comparing the proposed boundaries and
the adopted continuous function. When
the agency plotted the revised product
plans against the proposed boundaries,
we found that there were approximately
1.25 million vehicles that could move to
a less stringent category with changes in
footprint of less than one square foot.
These minor changes would reduce
applicable target values by 1.0–3.3 mpg.
Under a continuous function, footprint
increases of similar magnitude would
reduce applicable targets by no more
than 0.2 mpg.
Third, reliance on a continuous
function substantially reduces an
incentive present in the proposed stepfunction standard for manufacturers to
‘‘downsize’’ vehicles. IIHS raised
concern that under the proposed step
function system, manufacturers might
reduce the sizes of models within the
limits of the footprint range for a
category to make it easier to comply
with their required fuel economy levels.
The IIHS commented that there ‘‘is
room within NHTSA’s proposed system
of footprint categories to retain the same
fuel economy target but reduce size
* * *’’ and that ‘‘the safety of the
resulting vehicle would be
compromised.’’ General Motors also
acknowledged this possibility, stating
that the category structure of the
Reformed CAFE system:
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[S]till may incentivize manufacturers to
use reductions in track width and/or
wheelbase (to create a smaller and/or lighter
vehicle) to meet CAFE targets within a
category or overall. While changes in vehicle
dimensions may not be the first choice for
manufacturers, they remain an option-one
that can adversely affect safety.
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In contrast, IIHS stated that any
downsizing under a continuous
function would subject a vehicle to a
more stringent target. As such, IIHS
stated that a continuous function would
better minimize the potential for
manufacturers to respond to the CAFE
program through unsafe downsizing.
With respect to minimizing the
incentive to downsize, the agency agrees
with IIHS. We concur with IIHS’s
concern over the potential to downsize
within a step function category,
particularly within the smallest size
categories, where reducing vehicles’ size
or weight likely would have the largest
impact on occupant safety.
Commenters raised a variety of other
procedural and administrative concerns
that the agency should take into account
in choosing between stepwise and
continuous functions. General Motors
and Nissan expressed concern that
setting fuel economy targets using a
continuous function could present an
even greater challenge to public
understanding of the Reformed CAFE
program than relying on a category
system to set vehicles’ fuel economy
targets. Neither commenter explained
why they believed a stepwise function
would be more readily understood.
Honda commented that it would be
easier for manufacturers of high fuel
economy vehicles to demonstrate the
‘‘superiority of their products’’ to
potential buyers under a stepwise
function than under a continuous
function.
We do not believe that a standard
based on a continuous function is
harder to understand than one based on
a step function. The main difference is
that instead of identifying an
appropriate category to determine a
vehicle’s target, a target under a
continuous function standard is located
along a curve. Calculating a
manufacturer’s required fuel economy is
done in a similar manner under both
systems and calculating a
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manufacturer’s compliance is performed
in exactly the same manner.
While manufacturers may not be able
to advertise ‘‘best in CAFE category’’
under a continuous function, the
Reformed CAFE does not prevent such
comparisons from being made under
non-CAFE classifications.
Manufacturers currently promote ‘‘best
in class’’ claims based on industry and
marketing classifications. For example,
Honda advertises that its Ridgeline is
the ‘‘only 4-door pickup to achieve the
highest government crash test rating (5
stars) for both frontal and side-impact
tests.’’94 Under the current CAFE
program, light trucks are all within a
single fleet, yet manufacturers still
advertise ‘‘best in class.’’ Presumably,
such claims could continue to be made
under Reformed CAFE.
Nissan asserted that compliance
calculations would be ‘‘unduly
cumbersome’’ under a continuous
function. Nissan also stated that the
agency’s administration and
enforcement process would be more
burdensome under a continuous
function than under a stepwise function
because NHTSA would need to review
complex compliance calculations
submitted by each manufacturer.
In the NPRM, we proposed requiring
manufacturers to submit a vehicle’s
footprint along with the CAFE data
currently collected. Manufacturers and
the agency would rely on this data to
determine required fuel economy levels
and compliance. An additional
calculation would be required to
determine a vehicle’s target, as opposed
to determining the appropriate category
and corresponding target. However, we
do not believe that the additional
calculation—one easily performed using
a programmable hand calculator or
spreadsheet program—will be overly
cumbersome.
Ford indicated that the use of a
harmonic average to calculate a
manufacturer’s compliance obligation,
combined with the use of categories,
would provide manufacturers the
greater flexibility to make improvements
in an appropriate manner as opposed to
94 https://automobiles.honda.com/models/
model_overview.asp?ModelName=Ridgeline (last
visited January 15, 2006).
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use of a harmonic average with a
continuous function.
The standard adopted in this
document retains the flexibility
provided by use of a harmonic average
to determine a manufacturer’s
compliance requirement and a
manufacturer’s actual fuel economy
level. Additional flexibility is provided
by the fact that fuel economy targets are
more specific to a vehicle. As opposed
to being compared to a target
representative of the capabilities of
vehicles within a range of footprint
values, the final rule compares a vehicle
to the potential fuel economy achievable
by vehicles of equal size. A
manufacturer still has the ability to
compensate for a vehicle that performs
below its set fuel economy target by
exceeding the target for one or more of
its other models.
Toyota argued that because the NPRM
did not propose a specific continuous
function for review, ‘‘additional notice
and comment would be necessary
should NHTSA wish to pursue a
continuous line function in place of
size-based targets, since it is simply not
possible for manufacturers or the public
to determine the implications of such a
system in the context of new standards
for model years 2008 through 2011.’’ In
contrast, Nissan asserted that switching
to a continuous function would ‘‘result
in little to no difference in fuel economy
compliance levels,’’ suggesting that the
NPRM’s discussion of a continuous
function was sufficiently detailed to
allow a manufacturer to assess the costs
and other challenges of complying with
a Reformed CAFE standard that uses a
continuous function.
Although the agency is not adopting
the category system as proposed, the
targets under today’s final rule are
consistent with the category targets
proposed in the NPRM. Figure 13 below
shows the resulting relationship
between vehicle footprint and target fuel
economy level for 2011 described by the
logistic function with parameter values
statistically calibrated for that model
year and subsequently optimized. The
figure also compares its curved shape to
that stair step shape of the fuel economy
targets established in the previously
proposed category system for that model
year.
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RMI favored a step-function, because
its ‘‘size neutrality’’ provides a better
foundation for replacing fuel economy
standards with a ‘‘feebate’’ system. In
context of fuel economy, ‘‘feebate’’
refers to a transportation initiative in
which consumers of low-fuel economy
vehicles would pay into a fund from
which payments would be made to
purchasers of high-fuel economy
vehicles. In response to RMI’s comment,
we note that EPCA does not provide for
a feebate system, but instead requires
the agency to establish average fuel
economy standards. However, as
discussed above, the continuous
function adopted today provides greater
‘‘size neutrality’’ than a step function
(i.e., a continuous function reduces
incentives to downsize or upsize a
vehicle).
Although the continuous function
standard adopted in today’s final rule
eliminates the abrupt changes in fuel
economy targets present in a stepfunction standard, it is important to
recognize that the function does not
‘‘smooth’’ the targets as requested by
some commenters. Toyota, Porsche,
BMW, and the Alliance questioned why
the stringency in Category 3 increased at
a higher rate than the stringency levels
of other categories. Toyota stated that
vehicles in this size category tend to be
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fairly fuel-efficient unibody SUVs and
minivans. Toyota also noted that the
proposed Category 3 target experienced
a 5.4 percent increase between 2008 and
2009, while the target for Category 6
actually went down from 2009 to 2010.
Toyota suggested that the agency
consider ‘‘smoothing’’ the target levels
for the interim model years by linearly
increasing the target levels between
2008 and 2011. Similarly, Honda
questioned the increases in stringency
proposed for the smaller footprint
vehicles. Honda stated that, at least in
theory, the agency’s methodology (i.e.,
adding technology to each vehicle until
the marginal cost exceeds the marginal
benefits) should result in more stringent
standards for larger vehicles, since the
higher baseline fuel consumption would
justify the addition of more technology.
Honda observed that under the
proposed step function light trucks in
the smallest footprint category were
projected to achieve an increase in fuel
economy of 22 percent, while the
increase for light trucks in the largest
footprint category was only 16 percent.
Honda questioned whether technologies
have been applied uniformly and fairly
to all vehicles.
As explained above, the stringency of
the targets is based on the opportunity
to apply fuel savings technology to
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vehicles within the light truck fleet.
Differences in increases in stringency
between vehicles of different sizes
reflect differences in the potential
improvements for those vehicles, and
the costs and benefits of those
improvements. While larger vehicles
typically have low fuel economy
performance, that does not mean that
such vehicles are not equipped with
fuel saving technologies. Conversely,
the higher fuel economy performance of
smaller vehicles is not necessarily
reflective of fuel savings technologies,
but may be more indicative of the
vehicles small size. The reformed CAFE
system recognizes variations in the
baseline fuel economy levels between
vehicles, in the costs of improving fuel
economy, and in the resulting fuel
savings and related benefits.
Manufacturers’ efforts to improve fuel
economy are reflected in the degree of
projected improvement across the range
of footprint values. Increases in
stringency above a manufacturer’s
baseline are consequences of the
agency’s improving the overall fuel
efficiency of the light truck fleet to a
maximum feasible level.95
95 Additionally with regard to Honda’s comment,
it is also important to distinguish between
improvements in fuel economy (which is measured
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b. Continuous Function and Targets vs.
Classes and Standards
As explained in the NPRM, we
considered an approach under which
we would establish separate classes
based on footprint and establish a
standard for each class. However, there
were two primary shortcomings that led
us to evaluate other approaches for our
Reformed CAFE. Nothing provided by
the commenters caused us to re-evaluate
our decision not to establish a multiclass system based on footprint.
First, transfers of credits earned in a
footprint class in a model year to a
different footprint class in a different
model year would have required a
complicated process of adjustments to
ensure that fuel savings are
maintained.96 This is because credits
(denominated in mpg) earned under the
multiple classes and standards approach
would have differing energy value.
Credits earned for exceeding the higher
fuel economy standard for the smaller
footprint vehicles would have less
energy value than exceeding the lower
fuel economy standard for the larger
footprint vehicles by an equal
increment. In fact, if credits were
generated in a class with relatively high
CAFE standards and transferred to
another class with relatively low CAFE
standards, total fuel use by all vehicles
in the two classes might increase. That
result would undermine the entire
reform effort by producing lessened
energy security.
One can calculate the appropriate
adjustments for such a credit transfer
system to ensure no loss of fuel savings.
This would ensure equivalent energy
savings. However, instituting a
complicated new process of credit
adjustments would detract from the
benefits of reforming the CAFE program
by making it more difficult to plan for
and determine compliance. Further,
taking this step would not cure another
problem associated with credits. Credits
earned by exceeding a standard in a
model year may be used in any of the
three model years preceding that model
year and, to the extent not so used, in
any of the three model years following
that model year (49 U.S.C. 32903(a)).
They may not, however, be used within
the model year in which they were
earned (Id.).
Second, establishing separate
standards for each class would
needlessly restrict manufacturer
flexibility in complying with the CAFE
program. A requirement for
manufacturers to comply with separate
standards, combined with the inability
either to apply credits within the same
model year or to average performance
across the classes during a model year,
could increase costs without saving fuel.
This would happen by forcing the use
of technologies that might not be costeffective. Further, Congressional
dialogue when considering the
enactment of the EPCA and
amendments to it has repeatedly
expressed the view that manufacturers
should have flexibility in complying
with a CAFE program so that they can
ensure fuel savings, while still
responding to other external factors.
Reliance on a continuous function
avoids these shortcomings just as the
proposed step function would have
avoided these shortcomings. Instead of
establishing distinct standards for
multiple classes, our proposal
establishes targets across the range of
footprint values and applies them
through a harmonically weighted
formula to derive regulatory obligations.
Credits are earned and applied under
today’s final rule in the same way as
they are earned and applied under
Unreformed CAFE and in a manner
fully consistent with the statute. Thus,
no complicated new provisions for
credits are needed. Further, the use of
targets instead of standards allows us to
retain the benefits of a harmonically
weighted fleet average for compliance.
This ensures that manufacturers must
provide the requisite fuel economy in
their light truck fleet, while giving the
manufacturers the ability to average
performance across their entire fleet and
thus the flexibility to provide that level
of fuel economy in the most appropriate
manner.
in miles per gallon) and reductions in fuel
consumption (which is measured in gallons per
mile). Because of differences between their initial
fuel economy levels, the improvements in fuel
economy that would be required by the proposed
targets for the smallest and largest categories of light
trucks cited by Honda (22 and 16 percent,
respectively) actually correspond to reductions in
fuel consumption of 18% and 14% percent,
respectively.
96 The 2003 ANPRM on reforming CAFE noted
that the agency had previously concluded that the
credits earned in one class could not be transferred
to another class, but re-examined the legislative
history of the CAFE statute and called that
interpretation into question.
c. Consideration of Additional
Attributes
In the NPRM, the agency sought
comment on whether Reformed CAFE
should be based on vehicle size
(footprint) alone, or whether other
attributes, such as towing capability
and/or cargo-hauling capability, should
be considered. The comments received
in response to our request were either
strongly supportive or strongly opposed
to including additional attributes.
Commenters supporting consideration
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of additional attributes (General Motors,
Nissan, DaimlerChrysler, Ford, Alliance,
Sierra Research, NADA, and SUVOA)
stated that such consideration is
necessary to account for the varying
degrees of utility among vehicles with
similar footprint values. Commenters
opposed to including additional
attributes (NRDC, Environmental
Defense, ACEEE, NESCAUM, and Rocky
Mountain Institute) stressed the
potential of using these attributes to
manipulate vehicles into categories with
less stringent targets.
The most frequently mentioned
attribute was towing capability.
However, Nissan stated that NHTSA
should incorporate a mechanism
providing fuel economy credits for all
optional safety and utility features. The
Alliance suggested 4WD/AWD
capability in addition to towing.
Among the commenters supporting a
modification for towing ability, the
criteria for that classification differed.
General Motors defined ‘‘heavy-tow
capable’’ vehicles as a vehicle with a
maximum towing capacity that is equal
to or greater than 8,000 pounds. The
Alliance suggested that the definition
should be based on towing capacity
equal to or greater than a set percentage
of the vehicle’s curb weight. That
association argued that extra towing
capacity means different things for
different size vehicles.
Among those supporting
consideration of additional attributes,
the means suggested for providing credit
for those attributes also differed. Nissan
presented a method for calculating
credits based on weight differences
between a vehicle’s base model and
versions with optional safety and utility
enhancing equipment, such that each
additional 3 pounds of weight would
provide a 0.01 mpg credit. Some
commenters suggested a set percentage
reduction; 5 percent with respect to
towing capacity or 10 percent for 4WD/
AWD. DaimlerChrysler suggested a
provision which essentially created a
second category for any MY 2005
product that is at least 25 percent below
the 2008 MY target for its size class,
rather than considering specific
attributes. Under DaimlerChrysler’s
provision, the fuel economy target for
such a vehicle would be set at its 2005
level plus 5 percent and would then
increase 1.5 percent per year.
NRDC, Environmental Defense,
ACEEE, NESCAUM, and Rocky
Mountain Institute opposed
consideration of additional attributes in
determining a vehicle’s target fuel
economy. These commenters, along
with Honda and Toyota, were
concerned with the potential for
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manufacturers to ‘‘game’’ such
considerations. These commenters
argued that manufacturers might find it
more cost-effective to include whatever
attribute was relied upon for
adjustment, even if not requested or
required by customers, rather than
redesigning the vehicle for increase fuel
efficiency.
Toyota raised specific concern with
the attribute of tow rating, stating that
there is not an objective method for
quantifying this metric. Toyota also
opposed adjustments for attributes,
arguing that the targets already reflect
the presence of such designs in the
vehicles. Toyota stated that if these
vehicles were permitted adjustments,
the agency would essentially be ‘‘double
counting’’ the effect of the attribute
considered. Toyota further stated that
depending on the attribute relied upon
for adjustment, some manufacturers
might be provided a competitive
advantage based on their current fleet
mix.
After reviewing these comments,
NHTSA has decided not to consider any
additional attributes for MYs 2008–
2011. First, NHTSA notes that even
some manufacturers noted the potential
for abuse of a system that provided
credits or lower targets for vehicles with
certain attributes. Second, NHTSA
believes the ‘‘list of eligible features’’
suggested by Nissan would be very
confusing for both manufacturers and
the agency.
With regard to the suggestion that the
agency consider 4WD/AWD capability,
the agency notes that it discontinued the
option of a separate standard for 2WD
vs. 4WD light trucks beginning with the
standard for the 1992 model year.97 The
agency noted that separate standards
were originally intended to provide an
alternative means of compliance for
manufacturers that manufactured
primarily 4WD vehicles, and that these
intended beneficiaries had disappeared.
The agency noted that most
manufacturers were choosing to comply
with the combined standard. The
agency also expressed concerns that
separate standards could decrease fuel
economy by encouraging the production
of less fuel-efficient 4WD vehicles.
Since there are no specialized
manufacturers that need relief to
comply with the standard, NHTSA is
not reversing this decision.
With regard to towing capacity, in
addition to the above concerns the
agency notes that manufacturers
suggested different approaches on how
to define vehicles which would qualify
for consideration. The agency is aware
97 55
FR 12487, April 4, 1990.
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that the SAE is working on a uniform
metric to rate towing capacity, and this
may provide at least some of the
information NHTSA would need to
reconsider this issue with regard to
towing capacity in the future.
d. Backstop and ‘‘Fuel Saving’’
Mechanisms
The agency is not establishing a
backstop or fuel economy ‘‘ratcheting’’
mechanism under the Reformed CAFE
system. As explained above,
incorporating a backstop or fuel
economy ratcheting system would be
contrary to the intent of EPCA. The
intent of the CAFE program is not to
preclude future mix shifts and design
changes in response to consumer
demand. A backstop would likely have
this influence. As discussed, a backstop
or a ratcheting mechanism would limit
the ability of a manufacturer to respond
to market shifts arising from changes
consumer demand. Such a system
would be in opposition to congressional
intent to establish a regulatory system
that does not unduly limit consumer
choice.
Additionally, supplementing the
Reformed CAFE standards with a
backstop would negate the value of
establishing the attribute-based
standards for some manufacturers and
perpetuate the shortcomings of
Unreformed CAFE. A backstop would
essentially be a required fuel economy
level akin to the Unreformed CAFE
standard that would apply to a
manufacturer if the required fuel
economy for that manufacturer as
determined under the Reformed CAFE
system was below some determined
threshold. For example, if consumer
demand shifted to larger light trucks
such that a manufacturer’s required fuel
economy level under the Reformed
CAFE system was below the backstop
fuel economy level, that manufacturer
would be required to comply with the
backstop. By requiring such a
manufacturer to comply with the
backstop, there would be a risk that the
backstop would not be economically
practicable given the change in the
market, as occurred under the
Unreformed CAFE standards in the mid1980s. With regard to a ‘‘ratcheting’’
mechanism, an ‘‘automatic’’ increase in
the stringency of targets or requirements
could potentially subject manufacturers
to required levels of average fuel
economy level that are not
technologically feasible.
Furthermore, the structure of the
Reformed CAFE system addresses
concerns commenters cited as the
rationale for establishing a backstop,
i.e., concerns with manufacturers’
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upsizing vehicles and their fleets for the
sole purpose of reducing the stringency
of their light truck CAFE requirement.
First, the structure of the Reformed
CAFE system minimizes the incentive
for manufacturers to upsize vehicles,
more so under the continuous function
approach. Second, manufacturers are
limited in their ability to increase the
size of their vehicles beyond that extent
demanded by consumers. Finally,
making vehicles larger for CAFE
compliance purposes is not cost-free.
Market forces or fuel price increases
will restrain consumer demand for large
light trucks with low fuel economy.
These reasons lead us to the conclusion,
more so given the structure of the
adopted reform, not to establish a
backstop. These points apply equally to
determination not to adopt a fuel
economy ‘‘ratcheting’’ mechanism as
recommended by several commenters.
With regard to the first point, reliance
on a continuous function minimizes the
incentive for manufacturers to increase
vehicle size solely for the purpose of
subjecting that vehicle to a less stringent
target. As explained in the discussion of
continuous function versus step
function above, we explained that
increases in vehicle size will more
likely be accompanied by a decrease in
fuel economy performance that offsets
the reduction in target stringency. This
is a result of targets decreasing gradually
as vehicle size increases across the
footprint continuum. This offset reduces
the incentive for manufacturers to
increase vehicle size solely in response
to the CAFE program. The decrease in
a vehicle’s fuel economy performance
from increasing its footprint will offset,
to a degree, the advantage of the lower
target.
With regard to the second point,
manufacturers are limited in what
changes they can make based on what
will be accepted by the market. Changes
in footprint result in perceptible
changes in performance and design (e.g.,
a longer and/or wider vehicle). As noted
above, the track-width component of
footprint, as defined in today’s final
rule, directly affects vehicle handling
and stability. The connection between
footprint and vehicle performance limits
the ability of manufacturers to increase
footprint in a manner not perceptible to
the consumer. As stated by IIHS, under
a continuous based function, customers
would be more likely to notice any
design changes that achieved a
substantial CAFE benefit, as opposed to
small changes that would move a
vehicle into a less stringent category
under the step-function approach.
Finally, making vehicles larger for
CAFE compliance purposes is not cost-
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free. All else being equal, larger vehicles
are more costly to build and operate.
Market forces or fuel price increases
will restrain consumer demand for large
light trucks with low fuel economy,
unless the need for utility justifies the
expense to the manufacturers of
producing and to the consumers of
operating large trucks.
The agency did a preliminary
evaluation of the cost associated with
increasing a vehicle’s footprint. We
relied on the databases provided by
manufacturers in which the
manufacturers included a vehicle’s
manufacturer’s suggested retail price
(MSRP). We identified 22 nameplate
vehicles that had data indicating more
than one footprint value, either from a
manufacturer offering different
configurations of a nameplate or as a
result of changes between model years.
We then separated out the 22
nameplates into 44 pairs and compared
MSRP. Some of the price differences
within the pairs appeared to represent
differences in levels of options as well
as footprint. The costs per square foot
for these changes were in excess of
$1000. These data point pairs were
excluded.
The remaining pairs were evaluated.
The average cost per square foot
increase of the remaining 25 pairs was
$119; the median cost was $46. Deleting
the 5 percent highest and lowest costs
resulted in a mean cost per square foot
increase of $85. We note that this is a
preliminary evaluation and that these
costs represent those associated with
increases in footprint that occur as part
of a planned model redesign. We expect
that the costs associated outside a
planned redesign would be substantially
higher.
We believe that the costs associated
with increasing a vehicle’s wheelbase
would be even greater than those
associated with an increase in track
width. Based on a review of confidential
information provided by a
manufacturer, we estimate that the cost
of redesigning a vehicle mid-product
cycle such that the vehicle has a longer
wheelbase would be at least equal to 50
percent of the costs associated with
introducing the original vehicle design.
Given this high estimate, it would be
unlikely that a manufacturer would
extend a vehicle’s wheelbase solely in
response to the CAFE program. The
agency intends to further explore the
costs associated with changes in
footprint.
Comments from the environmental
organizations raised a number of
concerns, which they stated
necessitated a back stop or ratcheting
mechanism. These concerns can be
categorized into three areas: (1)
Increases in fleet size based on historic
trends and potential market shift, (2)
increases in a vehicle’s footprint to take
advantage of a less stringent category,
and (3) upweighting of a vehicle to
remove it form the light truck CAFE
program.
With regard to the environmental
organizations’ first concern, we
explained above that the light truck
CAFE program is not intended to
constrain consumer choice. Any historic
upsizing of manufacturers’ fleets
occurred under Unreformed CAFE in
response to market demands, and
market demands will continue to
influence the size of the light truck fleet.
Moreover, the agency established the
MYs 2008–2011 standards after
evaluating the product plans provided
by manufacturers. Planned shifts in fleet
mix have been taken into consideration
in establishing the final rule. Future
standards will also rely, in part, on
product plans provided by
manufacturers. As such, projected
trends in fleet mix and fleet size will
continue to be a consideration in
establishing future CAFE standards.
With regard to the second concern,
both NRDC and Union of Concerned
Scientists stated that a number of
vehicles would need only changes
ranging from one-tenth of an inch to 1.5
inches in wheelbase and track width to
become subject to a less stringent
category. The Union of Concerned
Scientists stated that an increase in
vehicle size of 1–10 percent would be
equivalent to a 0.05 to 1.18 mpg
decrease in the fleet wide average fuel
economy, respectively. This concern
was also echoed by IIHS.
Again, as explained above, the agency
is adopting a standard based on a
continuous function as opposed to the
step function. Under the continuous
function small changes in vehicle
footprint are not rewarded with large
decreases in target values. Target values
decrease gradually, as opposed the
larger decreases that occur as a vehicle
moves between categories under the
proposed system. As such, the incentive
for upsizing has been further minimized
by adopting a continuous function
approach.
Environmental groups’ third major
concern was that of uprating, i.e.,
manufacturers increasing the GVWR of
vehicles beyond the 8,500 lbs GVWR
boundary for the light truck CAFE
98 With MDPVs included in the definition of light
truck, only approximately 50,000 vehicles could be
program. As explained in greater detail
below, the agency is extending the
definition of light truck to MDPVs. By
including MDPVs, we are capturing
essentially all SUVs with a GVWR less
than 10,000 lbs.98
Aside from our concerns with the
legality of a backstop, the agency has
concluded that the potential for fuel loss
from manufacturers increasing the
footprint values of vehicles or through
shifting their fleet mix has been
substantially reduced by the structure of
the final rule. By gradually decreasing
the value of targets as footprint increase,
minor increases to footprint do not
result in significant decreases in
applicable target values. Further,
increases to footprint come at a cost in
terms of fuel economy performance,
vehicle handling, and consumer
acceptance.
removed from the light truck CAFE program with
an uprating of 1,000 lbs or less.
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5. Benefits of reform
a. Increased Energy Savings
The Reformed CAFE system increases
the energy savings of the CAFE program
over the longer term because fuel saving
technologies will be required to be
applied to light trucks throughout the
entire industry, not just by a limited
number of manufacturers. The energysaving potential of Unreformed CAFE is
limited because it requires only a few
full-line manufacturers to make
improvements. In effect, the capabilities
of these full-line manufacturers, whose
offerings include larger and heavier
light trucks, constrain the stringency of
the uniform, industry-wide standard.
The Unreformed CAFE standard is
generally set below the capabilities of
limited-line manufacturers, who sell
predominantly lighter and smaller light
trucks. Under Reformed CAFE, which
accounts for fuel economy potential of
the fleets of individual manufacturers,
virtually all light-truck manufacturers
will be required to improve the fuel
economy of their vehicles. Thus,
Reformed CAFE continues to require
full-line manufacturers to improve the
overall fuel economy of their fleets,
while also requiring limited-line
manufacturers to enhance the fuel
economy of the vehicles they sell.
Our estimates indicate that the
Reformed CAFE system will result in
greater fuel savings than the
Unreformed CAFE system during the
transition period, even though the
industry-wide compliance costs were
equalized for those model years:
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17619
TABLE 7.—ESTIMATED FUEL SAVINGS FROM REFORMED AND UNREFORMED CAFE SYSTEMS FOR MYS 2008–2010
[in billions of gallons]
MY 2008
Reformed CAFE system ..............................................................................................................
Unreformed CAFE system ...........................................................................................................
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The improvement in fuel savings
made possible by the switch to the
Reformed CAFE system will be even
greater beginning MY 2011. By requiring
improvements across the entire
industry, the Reformed CAFE system
produces greater fuel savings at levels
that remain economically practicable.
For comparison, the agency performed a
cursory Stage analysis for MY 2011. On
the basis of that cursory analysis, the
agency determined that, under the
Unreformed CAFE system, the fleet
wide (including MDPVs) fuel economy
standard would be 23.3 mpg. We note
that the Stage Analysis for MY 2011
results in a lower Unreformed standard
for that year than the Unreformed
standard for MY 2010. This is due to the
inclusion of MDPVs in MY 2011.
MDPVs, which have low fuel
economies, are produced primarily by
General Motors. Under the Unreformed
CAFE system, General Motors would be
the least capable manufacturer. Because
of this, and because including the
MDPVs lowers the CAFE level projected
for General Motors, the inclusion of
MDPVs would depress the Unreformed
CAFE standard. Table 8 below
illustrates the difference in fuel savings
between the Unreformed CAFE system
and the fully implemented Reformed
CAFE system in MY 2011.
$2.5 billion, this cost is distributed
across a greater number of
manufacturers. Additional discussion of
the Reformed CAFE costs is provided
below.
b. Reduced Incentive To Respond to the
CAFE Program in Ways Harmful to
Safety
In the NPRM, we noted the key trends
in the light vehicle population and in
the crashes that produce serious and
fatal injuries to highlight the safety
impacts of reforming CAFE.
Specifically, we identified rollovers and
crash compatibility. Both are related to
reforming CAFE.
Pickups and SUVs have a higher
center of gravity than passenger cars and
thus are more susceptible to rolling
over, if all other variables are identical.
Their rate of involvement in fatal
rollovers is higher than that for
passenger cars—the rate of fatal
rollovers for pickups and SUVs is twice
that for passenger cars. Rollovers are a
particularly dangerous type of crash.
Overall, rollover affects about three
percent of light vehicles involved in
crashes, but accounts for 33 percent of
light vehicle occupant fatalities. Single
vehicle rollover crashes account for
nearly 8,500 fatalities annually. Rollover
crashes involving more than one vehicle
account for another 1,900 fatalities,
bringing the total annual rollover
TABLE 8.—COMPARISON OF THE ESTI- fatality count to more than 10,000.
MATED FUEL SAVINGS FROM RECrash compatibility is the other
FORMED IN MY 2011 AND AN prominent issue. Light trucks are
UNREFORMED STANDARD OF 23.3 involved in about half of all fatal twovehicle crashes involving passenger
MPG IN MY 2011
cars. In the crashes between light trucks
[in billions of gallons]
and passenger cars, over 80 percent of
the fatally injured people are occupants
MY
of the passenger cars.
2011
In regard to reducing regulatory
Reformed CAFE system .................
2.8 incentives for design changes adversely
Unreformed CAFE system .............
2.1 affecting safety, commenters generally
supported the proposed reliance on
As illustrated above, the Reformed
footprint, recognizing the safety
CAFE system saves an additional 700
concerns that led the agency to base the
million gallons of fuel over the
Reformed CAFE system on a size metric.
Unreformed CAFE system over the
Both General Motors and Nissan stated
lifetime of the vehicles in the MY 2011
that weight provides the best correlation
fleet. Further, we estimate that the fuel
to fuel economy, but given the safety
savings under a 23.3 mpg Unreformed
concerns about downsizing and the
standard in MY 2011 would have come
concerns about creating a potential for
at a cost of approximately $ 1.9 billion.
upsizing, these commenters support the
While the cost of the Reformed fuel
use of footprint. RVIA stated that
savings in MY 2011 is approximately
vehicle weight does have a direct
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0.7
0.6
MY 2009
1.9
1.8
MY 2010
2.2
2.0
impact on overall fuel economy, but the
proposed reliance on footprint is
reasonable.
The Alliance also supported the sizesafety correlation and stated that use of
footprint and the structure of Reformed
CAFE would reduce the incentive to
produce small vehicles in order to offset
larger light trucks. However, the
Alliance stated that the agency did not
acknowledge improvements made by
manufacturers in the static stability
factor and industry’s commitment to
address the compatibility issue.
The Rocky Mountain Institute
supported the use of footprint, stating
that the proposal would create an
incentive for decoupling size from
weight by adopting lighter-but-stronger
materials and would encourage
manufacturers to make vehicles that are
‘‘big, hence protective and comfortable,
without also making them heavy, hence
hostile and inefficient.’’ The Aluminum
Association stated that use of footprint
would provide opportunities to increase
safety while saving fuel by substituting
aluminum for steel.
The agency continues to believe that
the manner in which fuel economy is
regulated can have substantial effects on
vehicle design and the composition of
the light vehicle fleet. Reforming CAFE
is important for vehicle safety because
the current structure of the CAFE
system provides an incentive to
manufacturers to reduce the weight and
size of vehicles, and to increase the
production of vehicle types (particularly
pickup trucks and SUVs) that are more
susceptible to rollover crashes and are
less compatible with other light
vehicles. For these reasons, reforming
CAFE is a critical part of the agency’s
effort to address the vehicle rollover and
compatibility problems.
The final rule based on footprint
substantially reduces the incentive to
introduce smaller vehicles or to reduce
vehicle size to offset the lower fuel
economy of larger vehicles. Adding the
continuous function concept to
footprint eliminates the opportunity that
existed under the proposal to
downweight by reducing vehicle size to
the lower edge of a category (which
would have increased vehicle fuel
economy without subjecting the vehicle
to a higher target). It does this by
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eliminating the categories that covered a
range of footprint sizes. Thus, under the
final rule, each change in footprint
results in a different target.
i. Reduces Incentive To Reduce Vehicle
Size and To Offer Smaller Vehicles
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Without CAFE reform, significant
increases in Unreformed light truck
CAFE standards, especially if
accompanied by high fuel prices, would
likely induce a wave of shifting
production mix toward smaller light
trucks and reducing the size and/or
weight of light trucks. Such a shift
occurred in the 1970’s and early 1980’s
when fuel price increases and
competitive pressures induced vehicle
manufacturers to shift their production
mix toward their smaller and lighter
vehicles to offset the lower fuel
economy of larger and heavier vehicles
and to redesign their vehicles by
reducing their size and/or weight.99 The
need for manufacturers to make rapid
and substantial increases in passenger
car and light truck CAFE in response to
the CAFE standards in late 1970’s and
early 1980’s provided an added
incentive for them to take those actions.
The shift in production mix and
reduction in vehicle size/weight that
occurred in the 1970’s and early 1980’s
contributed to many additional deaths
and injuries.100 While the adoption of
additional safety performance
requirements for those vehicles has
saved lives, even more lives would have
been saved if the shifting of production
mix toward smaller vehicles and the
reduction in size and/or weight had not
occurred.
By relying on vehicle size to
determine required fuel economy levels,
the agency will minimize the incentive
for manufacturers to comply through
downsizing vehicles or by increasing
the production of smaller vehicles
solely to offset the sales of larger
vehicles. These compliance strategies
reduce safety by reducing the
crashworthiness of individual vehicles,
and compound the problem of fleet
compatibility.
Reforming CAFE such that required
fuel levels are determined through the
use of footprint-based fuel economy
targets discourages reductions in vehicle
size. As a vehicle decreases in size, the
fuel economy target against which that
vehicle is compared increases.
99 Shifting production mix down toward smaller
vehicles involves decreasing the production
volumes of vehicles that are heavier or larger and
thus have relatively low fuel economy and
increasing the production volumes of lighter or
smaller vehicles.
100 NAS Report, p. 3.
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Several commenters raised concern
that the structure as proposed (i.e., a
category-based system) would still
reward downsizing. IIHS stated that a
manufacturer could rely on limited
reduction in size as a method to reduce
weight, without moving a vehicle into a
different category.
The agency recognizes the potential
for limited downsizing being rewarded
in a category based system. However,
this potential reward is substantially
reduced and possibly eliminated under
the continuous function adopted today.
Under the continuous function, any
reduction in size will result in a vehicle
becoming subject to higher target.
Where a step-function would permit
limited reduction in footprint within a
category, under a continuous function
any reduction in footprint will subject a
vehicle to a more stringent target.
IIHS further stated that even if a
manufacturer maintained a vehicle’s
size, the manufacturer still could reduce
a vehicle’s weight in order to improve
the vehicle’s fuel economy. IIHS
cautioned that such weight reduction
would likely reduce a vehicle’s
crashworthiness because decreased size
and weight have separate effects on a
vehicle’s ability to protect its occupants.
IIHS, citing the NAS report and Kahane
study, stated that although the potential
safety cost is greater when both
decrease, a decrease in mass alone will,
on average, reduce the crashworthiness
of the light truck fleet.
The potential for downweighting
through limited reductions in footprint
is minimized under the Reformed CAFE
structure adopted in this document.
Reliance on a continuous function
further discourages footprint reduction
because as a vehicle model’s footprint is
reduced, the vehicle is subject to a
higher target. Reformed CAFE, as
adopted today, links the level of the
average fuel economy targets to the size
of footprint so that there is an incentive
to reduce weight only to the extent one
can do so while also preserving size.
Thus, we have minimized the incentive
for a compliance strategy that could
increase rollover propensity and cause
further divergence in the size of the
light truck fleet.
By basing Reformed CAFE on a
measure of vehicle size (footprint)
instead of weight, the agency is aware
that the CAFE program will continue to
permit and to some extent reward
weight reduction as a compliance
strategy. The safety ramifications of
downweighting—especially
downweighting that is not achieved
through downsizing—will need to be
examined on a case-by-case basis in
future rulemakings. Historically, the
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size and weight of light-duty vehicles
have been so highly correlated that it
has not been technically feasible to fully
disentangle their independent effects on
safety.101 The agency remains
concerned about compliance strategies
that might have adverse safety
consequences.
As explained in more detail below in
Section VIII, Technology issues, in
determining the fuel saving potential of
a manufacturer’s fleet, the agency
employed weight reduction as a
compliance strategy only in limited
instances. The agency only considered
weight reduction for vehicles with a
curb weight greater than 5,000 lbs. This
limitation was based on the Kahane
study, which indicated that weight
reduction of the heaviest vehicles would
not negatively impact safety. If
downweighting were concentrated
among the heaviest of the light trucks,
any extra risk to the occupants of those
vehicles might be more than offset by
lessened risk in multi-vehicle crashes to
occupants of smaller light trucks and
cars. IIHS agreed with the agency that
downweighting of the heaviest vehicles
would likely not harm safety.
Additionally, it is possible that some
of the lightweight materials used in a
downweighting strategy may have the
strength and flexibility to retain or even
improve the crashworthiness of vehicles
and the safety of occupants. General
Motors expressed some concern with
the practicality of using lightweight
materials, stating that it does not
intentionally reduce mass by replacing
it with advanced materials. However,
General Motors did state that it seeks to
use advanced materials and
technologies in new generation vehicles.
As stated above, the agency used limited
weight reduction in our modeling;
101 Kahane, C.J., Response to Docket Comments
on NHTSA Technical Report, Vehicle Weight,
Fatality Risk and Crash Compatibility of Model
Year 1991–99 Passenger Cars and Light Trucks,
Docket No. NHTSA–2003–16318–16, 2004
discusses the historic correlation and difficulty of
disaggregating weight and ‘‘size.’’ Except for a
strong correlation of track width with rollover risk,
it shows weak and inconsistent relationships
between fatality risk and two specific ‘‘size’’
measures, track width and wheelbase, when these
are included with weight in the analyses. See also
Kahane, C.J., Vehicle Weight, Fatality Risk and
Crash Compatibility of Model Year 1991–99
Passenger Cars and Light Trucks, NHTSA Technical
Report No. DOT HS 809 662, Washington, 2003, pp.
2–6. Evans, L. and Frick, M.C., Car Size or Car
Mass—Which Has Greater Influence on Fatality
Risk? American Journal of Public Health 82:1009–
1112, 1992, discusses the intense historical
correlation of mass and wheelbase and finds that
relative mass, not relative wheelbase is the
principal determinant of relative fatality risk in
two-car collisions. See also, Evans, L. ‘‘Causal
Influence of Car Mass and Size on Driver Fatality
Risk,’’ American Journal of Public Health, 91:1076–
81, 2001.
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however, we cannot dictate which
technologies a manufacturer must
employ in order to comply with the
standards. The stringency of today’s
standards should not make it necessary
for any manufacturers to rely on unsafe
or unproven compliance strategies.
Reformed CAFE also reduces the
incentive for manufacturers to comply
through increasing the number of
smaller vehicles, with higher fuel
economies, to offset larger vehicles,
with lower fuel economies. The way in
which Reformed CAFE dilutes the effect
of this action as compliance strategy can
be seen by looking at a Reformed CAFE
standard. The fuel economy targets, as
determined by the continuous function,
are constants. Regardless of what
compliance strategy is chosen by a
manufacturer, nothing that the
manufacturer does will change those
values.
The distribution of vehicle models
along the continuous function and the
production volume of each model,
however, are variables under the control
of the manufacturers. Further, they are
variables not only in the formula for
calculating a manufacturer’s actual level
of CAFE for a model year, but also in the
formula for calculating a manufacturer’s
required level of CAFE for that model
year.
Thus, by changing the distribution of
its production across the footprint
based-function, a manufacturer will
change not only its actual level of CAFE,
but also its required level of CAFE. For
example, all other things being equal, if
a manufacturer were to increase the
production of one of its higher fuel
economy models and decrease the
production of one of its lower fuel
economy models, both its actual level of
CAFE and its required level of CAFE
would increase.
Likewise, again all other things being
equal, if a manufacturer were to
redesign a model so as to decrease its
footprint (thereby presumably also
decreasing its weight), the model will
become subject to a higher target. Again,
as a result, both the manufacturer’s
actual CAFE and required CAFE would
increase. Thus, we have substantially
reduced the incentive for a compliance
strategy that could cause further
divergence in the size of the light truck
fleet and increase rollover propensity.
The reduced effectiveness of those
actions as compliance strategies under
Reformed CAFE increase the likelihood
that manufacturers will choose two
other actions as the primary means of
closing the gap between those two
levels: (1) Reducing vehicle weight
while keeping footprint constant, and
(2) adding fuel-saving technologies.
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Both of those actions would increase a
manufacturer’s actual CAFE without
changing its required CAFE.
Nevertheless, since a change in a
vehicle’s footprint will result in a
change in both actual and required
CAFE, manufacturers will have more
flexibility to respond to consumer
demand for vehicles with different
footprint values without harming their
ability to comply with CAFE standards
or adversely affecting safety.
ii. Reduces the Difference Between Car
and Light Truck CAFE Standards
In discussing the proposed stepfunction CAFE standard, we stated that
the Reformed CAFE system would
reduce the disparity between car and
light truck standards—the so called
‘‘SUV loophole’’—which in turn would
promote increased safety because the
disparity has created an incentive
(beyond that provided by the market by
itself) to design vehicles to be classified
as light trucks instead of cars.102 The
continuous function standard adopted
today will operate in the same manner.
The fuel economy targets along the
continuous function for the smaller
footprint categories of light trucks
would, by MY 2011, be at or near (and
for the smallest light trucks above) the
level of the current 27.5 mpg CAFE
standard for cars.
One way to design vehicles so that
they are classified as light trucks instead
of passenger cars is to design them so
that they have higher ground clearance
and higher approach angles.103
Designing vehicles so that they have
higher ground clearance results in their
also having a higher center of gravity.
Generally speaking, light trucks have a
higher center of gravity than cars, and
thus are more likely than cars to
rollover. Moreover, in order to create a
higher approach angle, it is necessary to
raise or minimize the front structure
below the front bumper, which
increases the likelihood that a light
truck will override a car’s body in a
front or rear end crash. It also increases
the likelihood that when a light truck
crashes into the side of a car, its front
end will pass over the car’s door sill and
intrude farther into the car’s occupant
compartment. In addition to not being
structurally aligned with cars, light
102 NAS Report (p. 88) noted that that gap created
an incentive to design vehicles as light trucks
instead of cars.
103 The term ‘‘approach angle’’ is defined by
NHTSA in 49 CFR 523.2 as meaning ‘‘the smallest
angle, in a plane side view of an automobile,
formed by the level surface on which the
automobile is standing and a line tangent to the
front tire static loaded radius arc and touching the
underside of the automobile forward of the front
tire.’’
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trucks are generally heavier than
passenger cars, which add to their
compatibility problems with cars.
Both NRDC and the Union of
Concerned Scientists questioned the
effectiveness of the proposed Reformed
CAFE system in limiting the incentive
to produce light trucks as opposed to
passenger cars. The Union of Concerned
Scientists stated that not all passenger
car-like light trucks would be in the first
two of the proposed categories. The
Union of Concerned Scientists listed the
Ford Freestyle and the Dodge Magnum
as examples of passenger car-like light
trucks that have footprint values larger
than proposed categories one and two,
and thus would be subject to fuel
economy targets lower that the
passenger car standard. NRDC cited a
forecast from The Planning Edge
forecast which suggested that 27 new
models of small and crossover vehicles
would be added to the light truck fleet
between MY 2005 and MY 2010, some
of which would not be in the first
category of the proposed CAFE
structure. NRDC stated that the
Reformed CAFE structure would still
provide an incentive for automakers to
classify vehicles as light trucks.
As stated above, the Reformed CAFE
system will compare smaller light trucks
to fuel economy levels more comparable
to the passenger car standard. A vehicle
such as the Ford Escape, with a
footprint of 43.5 square feet, will be
compared to a fuel economy target of
27.3 mpg in MY 2011. This significantly
minimizes the incentive to
manufacturer a vehicle as a light truck
as opposed to a passenger car, solely for
CAFE purposes.
c. More Equitable Regulatory
Framework
The Reformed CAFE system adopted
today provides a more equitable
regulatory framework for full-line
vehicle manufacturers and creates a
level playing field for all manufacturers.
The Unreformed CAFE system cannot
match the Reformed CAFE system in
terms of providing an equitable
regulatory framework for different
vehicle manufacturers. Under
Unreformed CAFE, all vehicle
manufacturers are required to comply
with the same fleet-wide average CAFE
requirement, regardless of their product
mix. For full-line manufacturers, this
creates an especially burdensome task.
We note that these manufacturers often
offer vehicles that have high fuel
economy performance relative to others
in the same size class, yet because they
sell many vehicles in the larger end of
the light truck market, their overall
CAFE is low relative to those
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manufacturers that concentrate in
offering smaller light trucks. As a result,
Unreformed CAFE is binding for such
full-line manufacturers, but not for
limited-line manufacturers who sell
predominantly smaller light trucks. The
full-line vehicle manufacturers have
expressed a legitimate competitive
concern that the part-line vehicle
manufacturers are entering the larger
end of the light-truck market with an
accumulation of CAFE credits. While
this concern has merit, it is also the case
that some part-line manufacturers (e.g.,
Toyota and Honda) have been industry
innovators in certain technological
aspects of fuel-economy improvement.
As with the proposed step-function,
the Reformed CAFE program adopted
today requires manufacturers to comply
with a fuel economy level that is
representative of that manufacturer’s
actual production mix. Under both
functions, vehicles are compared to fuel
economy targets more representative of
a vehicle’s fuel saving capabilities than
comparison to a single flat standard. In
fact, a required fuel economy level
under the continuous function is more
representative of a manufacturer’s
capabilities, because a target is
established for each specific vehicle
footprint, as opposed to the proposed
step function for which a target would
have been established for a range of
footprint values.
d. More Responsive to Market Changes
Reformed CAFE is more marketoriented because it respects economic
conditions and consumer choice.
Reformed CAFE does not force vehicle
manufacturers to adjust fleet mix toward
smaller vehicles unless that is what
consumers are demanding. As the
industry’s sales volume and product
mix changes in response to economic
conditions (e.g., gasoline prices and
household income) and consumer
preferences (e.g., desire for seating
capacity or hauling capability), the
expectations of manufacturers under
Reformed CAFE will, at least partially,
adjust automatically to these changes.
Accordingly, Reformed CAFE may
reduce the need for the agency to revisit
previously established standards in light
of changed market conditions, a difficult
process that undermines regulatory
certainty for the industry. In the mid1980’s, for example, the agency relaxed
several Unreformed CAFE standards
because fuel prices fell more than
expected when those standards were
established and, as a result, consumer
demand for small vehicles with high
fuel economy did not materialize as
expected. By moving to a marketoriented system, the agency may also be
able to pursue more multi-year
rulemakings that span larger time
frames than the agency has attempted in
the past.
E. Comparison of Estimated Costs To
Estimated Benefits
1. Costs
In order to comply with the Reformed
CAFE standards, we estimate the
average incremental cost per vehicle to
be $66 for MY 2008, $201 for MY 2009,
$213 for MY 2010, and $271 for MY
2011. Under the Reformed CAFE
system, a greater number of
manufacturers will be required to
improve their fleets and make
additional expenditures than under the
Unreformed CAFE system. The level of
additional expenditure that would be
necessary beyond already planned
investment varies for each individual
manufacturer. These individual
expenditures are discussed in more
detail in Chapter VII of the FRIA. As
stated above, these costs are distributed
across a greater share of the industry.
The total incremental costs (the costs
necessary to bring industry from 22.2
mpg, the level required by the standard
for MY 2007, to the final rule levels) are
estimated to be $553 million for MY
2008, $1,724 million for MY 2009,
$1,903 million for MY 2010, and $2,531
million for MY 2011. A comparison
between the Reformed and Unreformed
CAFE system costs is shown in Table 9.
By policy design, the mpg levels under
Reformed CAFE were set so that the
industry-wide costs of Reformed CAFE
are roughly equal to the industry-wide
costs of Unreformed CAFE for MY
2008–2010.
TABLE 9.—ESTIMATED COST FROM REFORMED AND UNREFORMED CAFE SYSTEMS FOR MYS 2008–2010
[in millions of year 2003 dollars]
MY 2008
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Reformed CAFE system ..............................................................................................................
Unreformed CAFE system ...........................................................................................................
2. Benefits
The benefits analysis applied to the
final standards under the Unreformed
CAFE system was also applied to the
standards under the final Reformed
CAFE system. Benefit estimates include
both the benefits from fuel savings and
other economic benefits from reduced
petroleum use. A more detailed
discussion of the application of this
analysis to the required fuel economy
levels under the Reformed CAFE system
can be located in Chapter VIII of the
FRIA.
Adding benefits from fuel savings to
other economic benefits from reduced
petroleum use as a result of the
Reformed CAFE standards produced an
estimated incremental benefit to society.
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The total value of these benefits is
estimated to be $782 million for MY
2008, $2,015 million for MY 2009,
$2,336 million for MY 2010, and $2,992
million for MY 2011, based on fuel
prices ranging from $1.96 to $2.39 per
gallon. These estimates are provided as
present values determined by applying
a 7 percent discount rate to the future
impacts. We translated impacts other
than fuel savings into dollar values,
where possible, and then factored them
into our total benefit estimates. The
benefits analysis for Reformed CAFE is
based on the same assumptions as the
benefits analysis for Unreformed CAFE.
Based on the forecasted light truck
sales from AEO 2005 and an assumed
baseline fuel economy (i.e., the industry
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553
536
MY 2009
1,724
1,621
MY 2010
1,903
1,752
wide fuel economy level if the MY 2007
standard were to remain in effect), we
estimated the fuel savings from the
Reformed CAFE program. This analysis
resulted in estimated lifetime fuel
savings of 746 million, 1,940 million,
2,230 million, and 2,834 million gallons
under the Reformed CAFE standards for
MY 2008, 2009, 2010, and 2011
respectively.
NHTSA estimates that the direct fuelsavings to consumers account for the
majority of the total benefits, and by
themselves exceed the estimated costs
of adopting more fuel-efficient
technologies. In sum, the total
incremental costs by model year
compared to the incremental societal
benefits by model year are as follows:
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TABLE 10.—COMPARISON OF INCREMENTAL COSTS AND BENEFITS FOR THE REFORMED CAFE STANDARDS
[In millions]
MY 2008
Total Incremental Costs* .................................................................................
Total Incremental Benefits* .............................................................................
MY 2009
$553
782
MY 2010
$1,724
2,015
MY 2011
$1,903
2,336
$2,531
2,992
* Relative to the 22.2 mpg standard for MY 2007
These estimates are provided as present
values determined by applying a 7
percent discount rate to the future
impacts.
In light of these figures, we have
concluded that the standards
established under the Reformed CAFE
system serve the overall interests of the
American people and are consistent
with the balancing that Congress has
directed us to do when establishing
CAFE standards. For all the reasons
stated above, we believe the Reformed
CAFE standards represent fuel economy
levels that are economically practicable
and, independently, that are a cost
beneficial advancement for American
society. A more detailed explanation of
our analysis is provided in Chapter IX
of the FRIA.
3. Uncertainty
Where:
Ni is the number (sum) of the ith model
light truck produced by the
manufacturer, and
Ti is fuel economy target of the ith
model light truck, which is
N is the total number (sum) of light
trucks produced by a manufacturer,
a = the maximum fuel economy target
(in mpg)
b = the minimum fuel economy target
(in mpg)
As with the Unreformed CAFE
standards, the agency recognizes that
the data and assumptions relied upon in
our analysis have inherent limitations
that do not permit precise estimates of
benefits and costs. NHTSA performed a
probabilistic uncertainty analysis on the
Reformed CAFE standards to examine
the degree of uncertainty in its costs and
benefits estimates. Factors examined
included technology costs, technology
effectiveness in improving fuel
economy, fuel prices, the value of oil
import externalities, and the rebound
effect. This analysis employed Monte
Carlo simulation techniques to examine
the range of possible variation in these
factors. As a result of this analysis, the
c = the footprint value (in square feet)
at which the fuel economy target is
midway between a and b
d = the parameter (in square feet)
defining the rate at which the value
agency thinks it very likely that the
benefits of the Reformed CAFE
standards will exceed their costs for all
four model years. A detailed discussion
of the uncertainty analysis is provided
in Chapter X of the FRIA.
F. MY 2008–2011 Reformed CAFE
standards
The manner in which a
manufacturer’s required overall CAFE
for a model year under the Reformed
system is computed is similar to the
way in which its actual CAFE for a
model year has always been calculated.
Its required CAFE level is computed on
the basis of the production and the
footprint target as follows.
determined according to the
following formula, rounded to the
nearest hundredth: where,
of targets decline from the largest to
smallest values
e = 2.718
x = footprint (in square feet, rounded to
the nearest tenth) of the vehicle
model
2008
a .......................................................................................................................
b .......................................................................................................................
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2009
28.56
19.99
E:\FR\FM\06APR2.SGM
30.07
20.87
06APR2
2010
29.96
21.20
2011
30.42
21.79
ER06AP06.025</GPH>
Model year
Parameter
ER06AP06.024</GPH>
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TABLE 11.—CALIBRATED PARAMETER VALUES FOR TARGET
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TABLE 11.—CALIBRATED PARAMETER VALUES FOR TARGET—Continued
Model year
Parameter
2008
c .......................................................................................................................
d .......................................................................................................................
The following is a representative
sample of footprint values for MY 2005
2009
49.30
5.58
2010
48.00
5.81
2011
48.49
5.50
47.74
4.65
light trucks and their associated targets
for MY 2011:
TABLE 12.—REPRESENTATIVE VEHICLES AND THEIR APPLICABLE FUEL ECONOMY TARGETS FOR MY 2011
Footprint
(square feet)
Representative vehicle(s)
Ford F–150 Super Cab ............................................................................................................................................
GM Silverado Extended Cab ...................................................................................................................................
Lincoln Navigator .....................................................................................................................................................
Honda Odyssey .......................................................................................................................................................
Hummer H3 .............................................................................................................................................................
GM Equinox .............................................................................................................................................................
Saturn Vue ...............................................................................................................................................................
Ford Escape ............................................................................................................................................................
Based on the product plans provided
by the manufacturers, we project that
manufacturers will be required to
comply with fuel economy levels in
75.8
65.3
55.4
54.7
50.7
48.2
45.2
43.5
Target (mpg)
21.81
21.93
22.84
22.98
24.16
25.19
26.56
27.32
MYs 2008–2011 under the Reformed
CAFE system as follows:
TABLE 13.—PROJECTED REQUIRED FUEL ECONOMY LEVELS BY MANUFACTURER
MY 2008
(mpg)
Manufacturer
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General Motors ................................................................................................
Ford ..................................................................................................................
DaimlerChrysler ...............................................................................................
Nissan ..............................................................................................................
Mitsubishi .........................................................................................................
Subaru .............................................................................................................
Toyota ..............................................................................................................
Hyundai ............................................................................................................
BMW ................................................................................................................
Porsche ............................................................................................................
VW ...................................................................................................................
Isuzu ................................................................................................................
Honda ..............................................................................................................
Suzuki ..............................................................................................................
The projected required industry wide
fleet fuel economy levels for MY 2008–
2010 are 22.7 mpg, 23.4 mpg, and 23.7
mpg, respectively. These levels are more
stringent than those in the NPRM. The
projected required fleet wide required
fuel economy levels in the NPRM for
MYs 2008–2010 were 22.6 mpg, 23.1
mpg, and 23.4 mpg, respectively. The
increase in stringency is a result of
higher compliance costs associated with
the Unreformed CAFE standards. Even
though the Unreformed CAFE standards
are the same as those proposed in the
NPRM, the associated compliance costs
have increased because the updated
product plans reflect the fact that
manufacturers have already planned to
apply several of the lower cost fuel
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21.9
22.7
23.2
22.3
25.1
25.4
22.6
23.9
24.5
23.0
23.1
22.2
23.3
25.5
improvement technologies. As a result,
the Stage analysis applies technologies
with higher costs in order to achieve the
same fuel economy level under the
proposed Unreformed CAFE system.
Because the Reformed CAFE system is
constrained by costs of the Unreformed
CAFE system in the transition period,
the Volpe model has more to ‘‘spend’’
(and spend more efficiently than under
an Unreformed standard) when
applying technologies in the Reformed
CAFE system. The result is Reformed
CAFE standards with higher stringency
than in the NPRM.
We estimate that the industry wide
fleet fuel economy average in MY 2011
will be 24.0 mpg. Based on the product
plans submitted in response to the
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MY 2009
(mpg)
22.6
23.2
23.7
23.3
25.8
26.4
23.0
25.0
25.1
23.7
23.7
22.9
24.0
26.3
MY 2010
(mpg)
22.9
23.8
24.1
23.7
26.3
26.3
23.2
25.0
25.5
24.0
24.1
23.2
24.4
26.6
MY 2011
(mpg)
23.2
23.9
24.3
23.9
27.0
26.8
23.8
25.4
25.8
24.2
24.2
23.4
24.6
27.1
ANPRM, we estimated that
manufacturers intended to achieve an
industry wide fuel economy level of
approximately 22.0 mpg. In the NPRM
the proposed Reformed standard for MY
2011 would have been 23.9 mpg, with
MDPVs remaining unregulated. As a
result of today’s final rule, we project a
required industry wide fuel economy of
24.0 in MY 2011, with MDPVs included
in the light truck fleet.
While the reformed standards adopted
today are more stringent than those
proposed, and we are regulating a larger
fleet in MY 2011, we have determined
that the Reformed CAFE system and
associated target levels for MYs 2008–
2011 will result in required fuel
economy levels that are both
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technologically feasible and
economically practicable for
manufacturers.
VII. Technology issues
A. Reliance on the NAS Report
The agency affirms our reliance on the
cost and fuel saving estimates provided
in the NAS report for the technologies
relied upon in our analysis. The NAS
cost and effectiveness numbers are the
best available estimates at this time.
They were determined by a panel of
experts formed by the National
Academy of Sciences. The report has
been reviewed by individuals chosen for
their diverse perspectives and technical
expertise, in accordance with
procedures approved by the Report
Review Committee of the National
Research Council. The purpose of the
independent review was to provide
candid and critical comments that
assisted the authors and the NAS in
making the published report as sound as
possible and to ensure that the report
met institutional standards for
objectivity, evidence and
responsiveness to the study charge. The
agency has reviewed other studies of
technologies available to improve fuel
economy and have concluded that the
estimates of fuel economy technology
effectiveness and costs developed by the
NAS are the most reliable available.
Alternative estimates recommended by
some commenters have not been subject
to the same level of expert and public
review, and thus are not suitable for use
by NHTSA in establishing fuel economy
standards.
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B. Technologies Included in the
Manufacturers’ Product Plans
The Alliance, DaimlerChrysler, Ford,
General Motors, Nissan, Toyota, and
Sierra Research argued that the agency’s
analyses incorrectly projected the use of
certain technologies that were either
already featured on vehicles or were
included in the manufacturer’s product
plans. Because the benefits of these
technologies are already incorporated
into the manufacturer’s baseline
capabilities, any further projected fuel
economy improvements were
incorrectly attributed. The commenters
urged the agency to revise our analyses
to account for technologies that were
already on vehicles or in the product
plans submitted to the agency.
In performing the Stage Analysis and
the Reformed CAFE analysis to
determine the final CAFE standards, the
agency relied on manufacturers’
comments and confidential product
plan information to adjust our
calculations. Accordingly, the
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technologies that were already featured
on certain vehicles or already
incorporated into the manufacturers’
baseline product plans were removed
from the Stage Analysis. We note that
the detailed description of the
adjustments made to the Stage Analysis
contains confidential information and is
discussed in general terms in the FRIA.
However, this final rule provides a
description of the steps taken in order
to address comments and discrepancies
between the product plan information
available to NHTSA in preparing the
August 2005 NPRM and this final rule.
C. Lead Time
In developing the proposal, the
agency relied on lead time assumptions
for the introduction of technologies
based on technology availability and its
fuel saving benefits. The Alliance, Sierra
Research, and most vehicle
manufacturers argued that our
application rates and timing did not
adequately consider technology
readiness and the typical automotive
product lifecycle in proposing the
Unreformed CAFE standards. Honda
and Toyota cited the NAS report, which
stated that ‘‘the widespread penetration
of even existing technologies will
probably require 4 to 8 years.’’ 104
Honda and Toyota supported the NAS
findings with regard to lead time
assumptions.
Underscoring the importance of lead
time, Toyota asked NHTSA to propose
CAFE standards for model years beyond
2011 as soon as possible in order to
afford the manufacturers an opportunity
for timely product development and
planning. Toyota argued that in Japan
and Europe, fuel economy targets for the
2008 to 2010 model years have been in
place since 1999 and 2000 respectively.
Manufacturers offered the following
specific arguments in favor of reduced
phase-in rates and extending lead time.
Product cycles and finite engineering
resources. The commenters argued that
technologies cannot be incorporated in
every vehicle at the same time due to
capital costs, differing vehicle and
powertrain planning cycles, and
engineering resource constraints, both at
the manufacturer level as well as at the
supplier level. As DaimlerChrysler
explained, resource constraints dictate
that a new technology is first integrated
into a single product and later deployed
fleet-wide. Similarly, Ford argued that
there are not enough resources available
to develop and implement multiple
technologies simultaneously across the
entire product lineup within a short
104 Honda comment p. 6, and Toyota comment p.
3, quoting the NAS report.
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period of time. Toyota stressed that the
lead time is not how long it takes to
develop a given technology, but how
long it takes to incorporate this
technology into different vehicle
configurations. The manufacturers
stated that product cycles are typically
staggered so that not all light trucks
undergo changes in the same timeframe.
These commenters argued that in order
to realistically reflect the manufacturers’
capabilities, the Stage Analysis should
stagger technology application and
avoid projecting fleet-wide application
of any one technology within a single
model year.
With respect to the actual duration of
product cycles, different manufacturers
argued that for light trucks, they last
from at least 5 to more that 8 years.
Further, they argued that the product
and technology plans for each model are
usually finalized several years prior to
their introduction. Manufacturers stated
that after design decisions affecting the
powertrain are ‘‘frozen,’’ it is nearly
impossible to implement any major
changes to address fuel economy.
Incorporating ‘‘off-the-shelf’’
technologies. The Alliance and vehicle
manufacturers argued that even readily
available ‘‘off-the-shelf’’ technology
cannot be simply bolted onto an existing
vehicle because integrating any
technology into the vehicle is a complex
task requiring advance preparations, not
just with respect to vehicle integration,
but also with respect to the automated
assembly lines. They also argued that
the manufacturers need time to ensure
that the new technology is optimized
not just for vehicle integration and
assembly, but also for serviceability and
customer satisfaction in-use. The
manufacturers also argued that NHTSA
should not assume that manufacturers
can readily adopt ‘‘off-the-shelf’’
technologies from one vehicle
application to another.
Customer acceptance. The Alliance
and vehicle manufacturers argued that
incorporation of specific technologies is
also dependent upon customer
acceptance. For example,
DaimlerChrysler argued that a
premature fleet-wide application of new
technology could result in widespread
customer rejection, which can be
avoided if a given technology is slowly
phased in and allowed to mature. Many
commenters also argued that
simultaneous fleet-wide incorporation
of new technology raises product
quality and durability concerns that
could affect customer acceptance. For
example, Honda argued that new
technologies need to be ‘‘piloted’’ on a
limited number of vehicles, to ensure
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adequate quality before being spread to
a wider number of sales.
The agency recognizes that vehicle
manufacturers must have sufficient lead
time to incorporate changes and new
features into their vehicles. In making
its lead time determinations, the agency
considered the fact that vehicle
manufacturers follow design cycles
when introducing or significantly
modifying a product. For the final rule,
the agency based our lead time
assumptions more closely on the
findings of the NAS report, typically
relying on the mid-point of the NAS
range for full market penetration, i.e., 6
years or approximately a 17 percent
phase-in rate. As illustrated in
Appendix B of this document, and as
discussed further below, the agency
made numerous adjustments to timing
when applying technologies in order to
address lead time concerns.
D. Technology Effectiveness and
Practical Limitations
The Alliance, General Motors,
DaimlerChrysler, Ford, Toyota, and
Sierra Research argued that the agency
overstated potential fuel economy
benefits of certain technologies in its
analyses. The manufacturers argued that
benefits assigned to a given technology
are not the same for every vehicle.
Instead, these commenters asserted,
actual fuel economy benefits depend on
vehicle characteristics. Additionally, the
Alliance, Toyota, DaimlerChrysler,
Ford, and General Motors argued that
the agency’s analyses incorporate a
number of technologies that have not
yet been fully developed or have
implementation issues that limit their
wide-spread availability. Manufacturers
provided the following examples of
instances in which they believe the
agency overestimated fuel saving
potentials or applied technologies in an
overly aggressive manner:
• Aerodynamic Drag Reduction—
Manufacturers stated that some
aerodynamic changes could impact
vehicle compatibility and result in
styling constraints that could affect
consumer demand;
• Improved Rolling Resistance—
These commenters stated that recently
improved Federal tire safety standards
are so stringent they limit the
availability of low rolling resistance
tires. Further, these commenters stated
that consumers demand all-season tires
that perform well in winter weather
conditions but sacrifice rolling
resistance.
• Variable Valve Lift and Timing—
Manufacturers stated that benefits of
this technology must be offset by
friction due to the increased number of
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sliding components required for a 2-step
lift system, and by increased oil pump
losses due to the need for more oil
pump capacity. Further, these
commenters stated that application of
this technology to a multi-valve base
engine will not result in sufficient
incremental performance improvement
to allow downsizing the engine;
• Hybrids and Diesels—
Manufacturers asserted that the fuel
economy benefit of hybrids varies
depending on the type of hybrid, the
application, and the driving cycle. With
respect to diesels, manufacturers stated
that widespread customer acceptance is
still to be determined due to higher
costs, past experience with older diesel
technology, and challenges faced by
manufacturers regarding Tier 2 and LEV
II emissions compliance.
The manufacturers also argued that
some estimates did not account for
synergy or ‘‘system effects.’’ That is,
when multiple technologies that address
the same opportunity for improvement
(e.g., pumping losses) are combined,
their effectiveness is diminished
because they address the same type of
loss. Thus, the manufacturers argued
that the lack of a full examination of
‘‘system effects’’ has resulted in a set of
projected fuel economy improvements
that overestimate the technologies’
combined capabilities. With respect to
hybrid engines, several manufacturers
argued that the fuel economy benefit of
hybrid vehicles varies depending on the
type of hybrid, the application, and the
driving cycle.
In contrast, environmental
organizations generally stated that the
agency underestimated the availability
of fuel saving technologies. These
commenters generally held that existing
technologies could be applied to
manufacturers’ fleets and result in fuel
economy performances in excess of 26
mpg. The Union of Concerned Scientists
stated that the agency underestimated
the availability of hybrids, and noted
that Toyota has stated that it plans for
hybrids to account for 25 percent of its
sales by early next decade. The Union
of Concerned Scientists also cited Ford’s
goal of having the capacity to produce
250,000 hybrids by 2010. The comment
provided by Sierra Club, U.S. PIRG, and
NET described a study in which
‘‘existing fuel saving and safety
technology’’ applied to a Ford Explorer
would result in a 71 percent
improvement in fuel economy.105
105 Friedman et al., Building a Better SUV: A
Blueprint for Saving Lives, Money and Gasoline.
Union of Concerned Scientists and the Center for
Auto Safety. September 2003.
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We note that the hybrid numbers
cited by the Union of Concerned
Scientists refer to Ford’s goal for
introducing hybrids in both its light
truck fleet and its passenger car fleet.
With respect to the study cited by Sierra
Club et al., the technology applications
applied to the Ford Explorer have not
all been proven to be feasible through
application in a production vehicle.
With respect to ‘‘systems effects,’’
NHTSA’s analysis used fuel economy
benefit values that account for the
diminished effectiveness that one
technology may have when used in
concert with other similar technologies.
For instance, a number of technologies
reduce an engine’s pumping losses. For
these technologies, NAS offers two fuel
economy benefit values—a higher value
for a ‘‘baseline’’ engine, with no such
technologies applied, and a lower value
for a ‘‘reference’’ engine with pumping
loss partially reduced. The difference
between the ‘‘reference’’ and ‘‘baseline’’
values is an estimate of the synergistic
effect that results from applying similar
technologies to the same vehicle.
Whenever an additional technology is
selected for a vehicle that already has
one or more similar technologies,
NHTSA always chooses the lower value
to account for these synergies.
E. Technology Incompatibility
The Alliance, DaimlerChrysler, Ford,
General Motors, Nissan, and Toyota
argued that certain technologies
projected in the agency analyses are
incompatible with their vehicle or
engine architecture. While their specific
comments regarding NHTSA’s
technology projections are confidential,
we are able to provide some generic
examples.
Manufacturers argued that not all
engines are readily compatible with
cylinder deactivation. For some,
incorporation of this technology would
require substantial investment and
engineering resources. Similarly,
manufacturers argued that switching
from a single overhead cam design to a
dual overhead cam design would, in
some instances, require a complete
engine redesign. Manufacturers also
argued that because of greater torque,
CVTs are not compatible with heavier
vehicles equipped with large V8
engines. Instead, they work best on
lighter light trucks based on passenger
car platforms. Similarly, manufacturers
argued that electrical power steering is
compatible with only smaller light
trucks, unless the heavier vehicles were
also switched to 42-volt electrical
systems. At least one manufacturer
asserted that low friction oil might be
incompatible with some engine designs
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and expressed concerns about the
availability of low friction oil in some
markets. Finally, the manufacturers
argued that because of the consumer
demand and expectations for off-road
capabilities, all-season traction, and
greater stopping performance, low
rolling resistance tires are incompatible
with some light truck models.
In applying technology in the Stage
Analysis and the Reformed CAFE
analysis to determine the final
standards, the agency carefully
considered the manufacturers’
comments and confidential product
plan information to adjust our
calculations. In some instances, the
manufacturers’ comments reflected
strategies already employed in the
agency’s analysis. For example, the
NPRM analysis did not apply CVTs to
larger light trucks equipped with V8
engines. Further, the technologies that
turned out to be incompatible with
certain vehicles were removed from the
Stage Analysis. When it was practicable
to do so, the agency substituted different
technology applications that were
compatible with those vehicles. As
explained above, the detailed
description of the adjustments made to
the Stage Analysis contains confidential
information and is not publicly
available. However, Appendix A of this
document and the FRIA provide a
description of the steps taken in order
to address the issue of incompatible
technologies (see FRIA p. VI–10).
F. Weight Reduction
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In the analyses for the NPRM, we
included the possibility of limited
vehicle weight reduction for vehicles
over 5,000 lbs. curb weight where we
determined that weight reduction would
not reduce overall safety and would be
a cost effective choice.106 Use of the
5,000 lbs cut-off point was based on
analysis in the Kahane study. The
Kahane study found that the net safety
effect of removing 100 pounds from a
light truck is zero for light trucks with
a curb weight greater than 3,900 lbs.107
However, given the significant statistical
uncertainty around that figure, we
assumed a confidence bound of
approximately 1,000 lbs. and used 5,000
106 The amount of projected weight reduction was
two percent for light trucks with a curb weight
between 5,000 and 6,000 lbs and up to four percent
for light trucks with a curb weight over 6,000 lbs.
107 Kahane, Charles J., PhD, Vehicle Weight,
Fatality Risk and Crash Compatibility of Model
Year 1991–99 Passenger Cars and Light Trucks,
October 2003. DOT HS 809 662. Page 161. Docket
No. NHTSA–2003–16318 (https://
www.nhtsa.dot.gov/cars/rules/regrev/evaluate/pdf/
809662.pdf)
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lbs. as the threshold for considering
weight reduction.108
Several commenters supported our
assumption that manufacturers could
respond to the CAFE standards with
limited weight reductions that would
not reduce safety. Conversely, several
commenters stated that any weight
reduction will lead to a reduction in
safety. These comments are discussed
below.
Before discussing the comments, we
would like to clarify that our analysis
does not mandate weight reduction, or
any specific technology application for
that matter. We performed the analysis
for the NPRM and the final rule on the
assumption that manufacturers would
find it cost-effective to cut some weight
out of light trucks that have a curb
weight greater than 5,000 lbs. Our
analysis relied exclusively on other fuelsaving technologies for lighter light
trucks to demonstrate that
manufacturers can comply with the
required fuel economy levels
established today without the need for
unsafe compliance measures.
Honda cited several reports, which it
asserted demonstrated that limited
weight reductions would not reduce
safety and could possibly decrease
overall fatalities. Honda stated that the
2003 study by DRI found that reducing
weight without reducing size slightly
decreased fatalities, and that this was
confirmed in a 2004 study by DRI that
assessed new data and methodology
changes in the 2003 Kahane Safety
Study. Honda asserted that the DRI
results tend to confirm ‘‘that curb
weight reduction would be expected to
decrease the overall number of
fatalities.’’
DRI submitted an additional study,
Supplemental Results on the
Independent Effects of Curb Weight,
Wheelbase, and Track Width on Fatality
Risk in 1985–1998 Model Year
Passenger Cars and 1985–1997 Model
Year LTVs, Van Auken, R.M. and J. W.
Zellner, May 20, 2005. This DRI study
concluded that reductions in footprint
are harmful to safety, whereas
reductions in mass while holding
footprint constant would benefit safety.
The DRI study disagreed with NHTSA’s
finding that mass had greater influence
than track width or wheelbase on the
fatality risk of passenger cars in nonrollover crashes.
The Union of Concerned Scientists
stated that recent studies indicate that
increases in weight have very little
impact. However, the Union of
108 See the discussion of ‘‘Effect of Weight and
Performance Reductions on Light Truck Fuel
Economy’’ in Chapter V of the PRIA.
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Concerned Scientists did not cite any
specific study. Further, Environmental
Defense stated that the Kahane study on
which the agency relied for determining
the weight reduction limitations was
flawed. Environmental Defense stated
that the Kahane study 109 does not
adequately distinguish between the
effects of size and weight on motor
vehicle accident mortality, despite the
large body of evidence suggesting that
other factors besides vehicle weight,
such as vehicle size and design, have
critical implications for vehicle safety.
While NHTSA agrees that limited
weight reduction to heavier vehicles
will not reduce safety, we continue to
disagree with DRI’s overall conclusion,
cited by Honda, that weight reductions
while holding footprint constant would
significantly benefit safety in lighter
vehicles. NHTSA’s analyses of the
relationships between fatality risk,
mass, track width and wheelbase in 4door 1991–1999 passenger cars (Docket
No. 2003–16318–16) found a strong
relationship between track width and
the rollover fatality rate, but only a
modest (although significant)
relationship between track width and
fatality rate in non-rollover crashes.
Even controlling for track width and
wheelbase—e.g., by holding footprint
constant—weight reduction in the
lighter cars is strongly, significantly
associated with higher non-rollover
fatality rates in the NHTSA analysis. By
contrast, the DRI study of May 20, 2005
analyzed 4-door cars and found a strong
relationship between track width and
fatality risk, and non-significant
associations of mass and wheelbase
with fatality risk (Docket No. 2005–
22223–78, p. 31). In other words, when
DRI analyzed the same group of vehicles
as NHTSA, they did not get the same
results. This difference indicates that
DRI’s analytical method and/or database
are not the same as NHTSA’s.
The agency continues to stand by our
analytical method and database and we
continue to believe that weight
reduction in lighter vehicles would
reduce safety. We also continue to
believe that weight reductions in the
heavier light trucks, while holding
footprint constant, will not likely result
in net reduction in safety.
IIHS expressed similar concern with
weight reduction as the agency, stating
that the safety cost of reduced mass
would be most apparent if the weight
reductions were to occur among the
smallest and lightest vehicles.
Referencing the 2003 Kahane report,
IIHS indicated that decreases in mass
among vehicles weighing more than
109 See
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5,000 pounds could result in a net safety
benefit. However, IIHS continued to
caution that reducing mass reduces, on
average, a vehicle’s ability to protect its
occupants, noting that the effects of
mass on vehicle crashworthiness have
been observed and documented
(Kahane, 1997; Partyka, 1996; O’Neill et
al., 1974).
General Motors and the Alliance were
more explicit in their concerns over the
safety impact associated with weight
reduction. The Alliance stated that the
fundamental laws of physics dictate that
smaller and/or lighter vehicles are less
safe than larger/heavier counterparts
with equivalent safety designs and
equipment.
General Motors agreed that
improvements in material strength,
flexibility, and vehicle design have
helped improve overall vehicle and
highway safety. But, General Motors
added, for a given vehicle, reducing
mass generally reduces net safety.
Further, General Motors stated that it
does not intentionally reduce mass by
replacing it with advanced materials,
presuming that such action alone will
result in improved protection for the
occupants in a lighter vehicle: vehicles
with larger mass will provide better
protection to occupants involved in a
crash than a vehicle of the same design
with less mass, given equivalent
crashes.
General Motors also questioned the
agency’s reliance on a 5,000 lbs.
minimum vehicle weight for
considering weight reduction, which
was based on the finding of the 2003
Kahane report that reducing curb weight
negatively impacts safety only at curb
weights under 3,900 pounds. General
Motors stated that the agency’s
conclusion is inconsistent with the
sensitivity analysis performed by
William E. Wecker Associates, Inc. and
submitted to the ANPRM docket.
General Motors stated that the inflection
point on the Wecker report’s graph for
General Motors light trucks in both the
periods of MYs 1991–1995 and MYs
1996–1999 is higher than 5,000 pounds.
Additionally, General Motors stated
that the NPRM did not acknowledge or
rationally respond to the main point of
the Wecker report, which was that Dr.
Kahane’s ‘‘analysis alone does not
support the proposition that a crossover
weight at or near 5,085 pounds is a
robust, accurate description of the field
performance of the [light truck] fleet[.]’’
We believe that General Motors is
confusing the 5,085 lbs. crossover
weight (where the safety effect of mass
reduction in a vehicle weighing exactly
5,085 lbs., is zero) with the breakeven
point described in the NPRM, which is
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the point where the total effect of
reducing all vehicles heavier than the
breakeven weight by an equal amount is
zero. NHTSA estimated that the
breakeven point as described in the
NPRM is 3,900 lbs., if footprint is held
constant.
If the 3,900 lbs. estimate were
perfectly accurate, we would be
confident that weight reductions in
vehicles down to 3,900 pounds would
not result in net harm to safety.
However, we agree with commenters
that there is considerable uncertainty
about the crossover weight and also the
breakeven point. Therefore, in our
analysis, we limited weight reduction to
vehicles with a curb weight greater than
5,000 pounds. We believe that the 5,000
lbs. limit is sufficient so that we can be
confident that such weight reductions
will not have net harm on safety.
SUVOA encouraged NHTSA to
emphasize the importance of making
sure that CAFE requirements do not
encourage vehicle downsizing ‘‘or any
other action that might have an adverse
effect on safety.’’ SUVOA cited several
reports in support of its assertion that
downsizing harms safety.110. As
explained above, the agency has applied
weight reduction only to those vehicles
for which we are confident that such
reduction will not negatively impact
safety.
The Competitive Enterprise Institute
stated that the agency’s own rulemaking
demonstrates the safety of weight,
specifically the FMVSS No. 216, Roof
crush, rulemaking. The Competitive
Enterprise Institute noted that in that
rulemaking, NHTSA determined that
the proposed requirement of more
protective roofs would ‘‘add both cost
and weight’’ to the vehicles. This
commenter also stated that NHTSA
found that the stronger the roof crush
standard, the more added weight it
would entail. The Competitive
Enterprise Institute also cited the IIHS,
March 19, 2005 Status Report on fatality
risks in different vehicles, which the
110 SUVOA provided the following cites in
support of its assertion:
• 2001, the National Academy of Sciences
affirmed that earlier downsizing of vehicles
following the imposition of CAFE regulations
resulted in an additional 1,300 to 2,600 deaths and
an additional 20,000 serious injuries per year.
• A Harvard School of Public Health-Brookings
Institution study in the 1990s found that vehicle
downsizing due to federal fuel economy mandates
increased occupant deaths by 14 to 27 percent.
• An in-depth analysis by USA Today in 1999,
using NHTSA and automobile insurance industry
data, found that since 1975, 7,700 additional deaths
occurred for every mile per gallon gained. By 1999,
vehicle downsizing had killed more than 46,000
Americans. Factoring in the ensuing six years
through 2005, the total conservatively eclipses
55,000 deaths.
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commenter stated concluded that in
each vehicle group, ‘‘the heavier
vehicles, like bigger ones, generally had
lower death rates.’’
The weight safety analysis performed
by the agency for this rulemaking
accounted for not only the occupant
safety (crashworthiness) of the vehicle,
but also the rollover propensity of the
vehicle, and the safety of the occupants
of other vehicles it strikes. While in
some instances, the crashworthiness of
a vehicle can be improved through
design changes that add weight to a
vehicle, design changes can also reduce
a vehicle’s weight without reducing
crashworthiness, and may in some
instances improve the safety of a vehicle
(e.g., reduce rollover propensity).
Environmental Defense commented
that by limiting the use of weight
reduction to heavier vehicles, the
agency disregarded the likelihood that
manufacturers would rely on weight
reduction in smaller, lighter vehicles.
Environmental Defense suggested that
the improved baselines should reflect
this weight reduction strategy.
Environmental Defense asserted that
weight reduction is among the most
common and cost-effective options
available to manufacturers for
improving vehicle fuel economy across
the light truck fleet. However,
Environmental Defense referenced
estimates presented in DeCicco (2005)
that suggest that the cost per pound of
weight reduced through use of highstrength steel and advanced engineering
techniques has been as low as, or lower
than, 31 cents per pound reduced.
Moreover, Environmental Defense
stated, the exclusion of mass reduction
in NHTSA’s analysis bears no relation to
what will actually happen in the
marketplace when standards are
implemented. Environmental Defense
argued that absent safety regulations
prohibiting the use of mass reductions,
manufacturers are likely to choose this
compliance alternative in vehicles of all
weights as a cost effective way to
comply with CAFE. Environmental
Defense stated that NHTSA should
include mass reduction among its
compliance alternatives for all light
trucks.
As stated above, the agency does not
dictate which fuel savings technologies
must be applied to vehicles. Mass
reduction is a compliance alternative for
all light trucks. However, one of the
considerations in setting fuel economy
standards is to set standards that will
not lead to a reduction in the safety of
the light truck fleet. The standards
established by the agency are those
capable of being achieved by the
manufacturers without the need to
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reduce safety. If the agency were to
consider weight reduction as a
compliance option for all light trucks,
we are concerned that the resulting
increased stringency would force unsafe
downweighting.
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VIII. Economic Assumptions
A number of commenters raised
global issues related to the agency’s
proposed CAFE standards, questioning
everything from how costs and benefits
were calculated to whether the standard
is necessary or beneficial at all. Aside
from raising issues with specific
economic assumptions relied upon by
the agency, commenters also more
broadly questioned the rationale of the
light truck CAFE program in general.
The Competitive Enterprise Institute
(CEI) argued that NHTSA’s proposed
CAFE standards are unnecessary and
that they could potentially increase the
nation’s dependence on foreign oil. CEI
argued that particularly since the 2005
hurricane season dramatically drove up
fuel prices at the pump, vehicle sales of
large SUVs and other relatively
inefficient vehicles have plummeted.
According to CEI, market forces have
acted to improve the overall fuel
economy of new vehicles without the
need for regulatory intervention.
(General Motors made a similar
argument, as to how fuel economy
standards are less efficient than market
forces in terms of achieving
economically optimal levels of fuel
economy.)
Although the effect of market forces
on fuel economy levels is a matter of
debate, NHTSA does not have the
option of leaving fuel economy to the
markets. The agency is required by
Congress to set light truck fuel economy
standards for every model year at the
maximum feasible level considering the
need of the nation to conserve fuel,
technological feasibility and economic
practicability.
A. Costs of Technology
The Alliance, Sierra Research and
most vehicle manufacturers argued that
NHTSA has underestimated the costs of
certain technologies. Specific comments
are set forth below.
First, General Motors stated that the
costs relied upon by the agency were
derived from technologies designed for
application to passenger cars, but which
are being applied to light-duty trucks
without consideration of the necessary
adjustments for integrating such
technologies while maintaining the
truck’s utility and function. For
example, for heavier light trucks,
installation of electric power steering
would also require a switch to a 42-volt
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electrical system, and probably
increased battery maintenance costs.
General Motors argued that the
additional costs associated with
integrating technologies available on
light vehicles into heavier vehicles was
one of the primary reasons for the
discrepancy between their internal costs
estimates and NHTSA’s costs estimates
in the PRIA. General Motors further
argued that both NAS and the estimates
of Energy and Environmental Analysis
(a consulting firm), inadequately
document sources for the costs they
include.
The Alliance, Ford, Honda, Nissan
and DaimlerChrysler reiterated that
technologies are not simply bolted onto
the vehicle. Instead, extensive
modifications are often required. These
modifications involve a substantial
investment. For example, the cost
estimates of a given piece of engine
technology do not include the costs of
redesigning the engine, testing
prototypes, mapping the engine,
developing new vehicle calibrations,
and integrating the technology with the
vehicle. For this reason, Sierra Research
and at least one vehicle manufacturer
disagreed with the NAS cost multiplier
of 1.4 and argued that it should be
substantially greater.
For this rulemaking, the agency has
decided to use the cost and effectiveness
numbers that appear in the NAS report.
The NAS committee reviewed many
sources of information including
presentations at public meetings, and
available studies and reports. It also met
with automotive suppliers and industry
consultants including Sierra Research.
The committee then used its expertise
and engineering judgment aided by the
information described above to derive
its own estimates of costs and
effectiveness. After the prepublication
copy was released in July 2001, the
committee reexamined its analysis.
Representatives from the industry and
other stakeholders were invited to
critique the findings. Several minor
errors were discovered and corrected
before publication of the final report.
The NAS cost and effectiveness
numbers are presented as ranges that
reflect estimates for passenger cars,
pickup trucks, and SUVs/minivans.
However, under the NAS report, the
availability of these technologies differs
for various segments of the vehicle fleet.
The NAS report breaks down the
availability of technology for two classes
of pickups (small and large) and four
classes of SUVs/minivans (small SUV,
midsize SUV, large SUV, and minivan).
Each class has a unique set of
technologies available to it. While some
individual technologies can be applied
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to any type of vehicle, the sets of
technologies available to passenger cars
are not the same as the sets of
technologies available to light trucks.
Thus, the costs assigned to passenger
cars are not being used for light trucks
because the technologies differ and each
set of technologies has a unique cost
estimate. Further, the cost estimates in
the NAS report include consideration of
costs for light trucks (NAS, p. 40).
Second, commenters argued that the
agency did not consider ‘‘stranded’’
costs (General Motors, Sierra Research).
For example, the stringency of the
Unreformed CAFE standard may force a
manufacturer to begin purchasing 6speed transmissions from an external
supplier immediately. Consequently, inhouse manufacturing efforts for which
considerable resources may have
already been spent would be abandoned
without any return on that investment.
Sierra Research also argued that NHTSA
has not properly accounted for costs
associated with the premature
retirement of existing technology before
its costs have been fully amortized.
Thus, commenters argued that NHTSA
incorrectly assumed costs of
technologies introduced during normal
product cycle turnover even when the
technologies were actually attributed to
vehicles mid-cycle.
Stranded costs are essentially one
time write-offs that would be difficult to
identify and even more difficult to
quantify, especially in light of their
offsetting tax savings implications.
Write-offs of stranded costs are likely to
occur occasionally during the routine
course of business as manufacturers
periodically find it necessary to curtail
production plans in response to
unplanned regulatory or market
impacts. These write-offs will thus
influence the long run cost of doing
business. Although manufacturers
typically attempt to price vehicles to
maximize their profits, the impact of
stranded costs on vehicle prices will be
constrained by market conditions, and
measuring their impact would be
problematic.
As explained above in the technology
discussion, the agency has constrained
its fuel economy model to give
deference to manufacturers’ production
plans. In determining manufacturer
capabilities, significant design changes
are initiated in conjunction with
redesigns and vehicle introductions
stipulated in production plans provided
to NHTSA by vehicle manufacturers.
The potential for stranded costs is thus
minimized. Overall, NHTSA does not
believe that the revised phase-in
schedule of technologies assumed in its
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model would force manufacturers to
incur significant stranded costs.
B. Fuel Prices
Many commenters stated that the fuel
price estimates used in the agency’s
analysis and modeling were too low and
should be revised to reflect the best
current projections of market prices
(SUVOA, NADA, Mercatus Center,
Union of Concerned Scientists, and
California State Energy Commission).
Environmental organizations, citing the
record prices for fuel at the pump, went
further, arguing that more stringent
standards are justified (Environmental
Defense, NRDC, ACEEE).
In contrast, vehicle manufacturers
requested that the agency not rely solely
on higher fuel price forecasts to
automatically increase the stringency of
the CAFE standards (the Alliance,
General Motors, Mitsubishi). Such
commenters urged the agency to not
allow CAFE standards to rise
precipitously based upon a spike in oil
commodity prices, thereby disregarding
technology costs and other limitations.
Specific comments related to fuel prices
follow below.
Environmental Defense argued that
NHTSA’s fuel prices estimates in its
CAFE proposal, based upon AEO2005,
are too low. While Environmental
Defense acknowledged NHTSA’s stated
intention to revise its fuel prices
estimates in light of AEO2006
projections, it argued that even this
forecast may be too low, particularly in
light of private oil prices estimates of
$42 to $100 per barrel over the analysis
period. Accordingly, Environmental
Defense urged NHTSA to utilize the best
available fuel price forecasts in revising
the level of the standards in the final
rule.
NRDC made a similar argument
regarding the proposal’s fuel prices
estimates, which it perceives to be too
low. To remedy this problem, NRDC
recommended that the agency use fuel
price forecasts consistent with the world
oil price forecasts reported in EIA’s
‘‘High B Oil Price Scenario’’ or the
International Energy Agency’s World
Energy Outlook 2005 ‘‘Deferred
Investment Scenario,’’ forecasts which
NRDC suggested are more consistent
with recent world oil prices and current
petroleum futures market prices.
As another suggestion for revising the
NPRM’s fuel prices estimates, the
California State Energy Commission
stated that future fuel prices are likely
to be at least as high as the ‘‘Base Case’’
scenario adopted in the 2005 Integrated
Energy Policy Report for California,
which forecasts retail fuel prices
(including Federal and California State
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taxes). The Commission recommended
using this forecast, which it argued is
more consistent with current fuel prices.
According to the commenter, recent EIA
forecasts (at least since 1996) have
significantly underestimated actual
future fuel prices.
The Alliance stated that while higher
gasoline price forecasts may appear to
justify further increases in fuel economy
levels, ‘‘NHTSA must proceed carefully
and consider all of the ramifications of
moving to higher levels than those
proposed.’’ Along the same lines,
General Motors commented that
increased fuel prices could lead to
significantly higher CAFE standards
under NHTSA’s model; according to
General Motors, a recent study by
Resources for the Future (RFF) found
that increasing the price per barrel of oil
by $20 would lead to a CAFE target as
much as 4 mpg higher.
In its comments, General Motors also
compared the American light truck fleet
with the European light truck fleet,
stating that Europeans pay
approximately $5 per gallon for
gasoline, yet their vehicles do not use
technologies beyond those present in
the U.S. fleet. An appendix to General
Motors’ comments further analyzed the
differences in fuel economy between
American and European vehicles,
suggesting that the fuel economy of
vehicles on both side of the Atlantic is
roughly comparable, once other relevant
factors are taken into account (e.g.,
vehicle weight, transmission type,
engine power, engine type, and
premium gas usage). General Motors
asked the agency to explain this
apparent discrepancy between real
world experience in Europe and
NHTSA’s analysis.
General Motors also stated that
NHTSA’s analysis did use the proper
value for the tax on gasoline, which the
American Petroleum Institute (API)
currently reports to be $0.46 per gallon.
Mitsubishi stated that fuel prices are
currently in a state of flux and
recommended using AEO2006 in the
final rule. However, Mitsubishi
cautioned that raising the fuel economy
target levels, based upon higher fuel
prices, might not be economically
practicable and could force
manufacturers to completely reanalyze
their business strategies.
The Mercatus Center commented that
as part of the final rule, the agency
should increase its fuel price forecasts
and take steps to adequately address
likely future volatility on fuel prices.
Specifically, the Mercatus Center
recommended adjusting the baseline
sale mix and fuel economy levels from
manufacturer product plans for future
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model years to reflect shifts in sales
patterns toward more fuel-efficient
models resulting from current high fuel
prices and buyer concerns about
continued fuel price volatility. It also
urged NHTSA to include a separate
estimate of the economic value of
reduced fuel price volatility expected to
result from lower fuel use.
Several commenters also noted that
the State gasoline taxes in some states
were changing as of January 1, 2006 and
that the agency should update their
gasoline tax estimates accordingly.
The agency will continue to rely on
the most recent fuel price projections
from the EIA from the Department of
Energy. We consider the EIA projections
to be the most reliable long-range
projections. No one can predict the
impact of hurricanes and other external
factors that could affect the price of
gasoline at particular points in time or
in the short term. However, what we
need are long range projections for 2008
to 2011, when this CAFE standard takes
effect. In addition, the EIA’s AEO2006
Early Release is the most recent
projection available, and considers the
most recent events.
Further, while commenters
recommended that the agency rely on
higher fuel prices, no commenter
provided an alternative forecast that the
agency believes to be more reliable than
those published by EIA as part of its
Annual Energy Outlook (AEO). NRDC
did recommend that the agency rely on
fuel price forecasts consistent with the
world oil price forecasts reported in
EIA’s AEO 2005 ‘‘High B Oil Price
Scenario’’ or the International Energy
Agency’s World Energy Outlook 2005.
The ‘‘Reference Case Scenario’’
presented in AEO 2006, which is relied
upon by the agency in the final rule, is
on average almost 14 cents per gallon
higher than the scenario suggested by
NRDC.
The latest fuel price projections are
taken from the EIA’s Annual Energy
Outlook 2006 (AEO2006 Early Release)
reference case, which is the most recent
projection available, translated into
2003 economics to match other cost
estimates in the analysis, and are
extended until 2047 to match the 36
year lifetime for light trucks produced
for MY 2011. The estimated gasoline
price per gallon in 2003 economics
varies over the time period, starting at
$2.16 in 2008, reducing to $1.96 in
2014, and then increasing to $2.39 by
2047.
The agency will consider additional
fuel price projections (higher and lower
than the reference case) from EIA in its
uncertainty analysis; however, there is
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no way to adequately predict or analyze
the volatility of fuel prices.
Since gasoline taxes are a transfer
payment and not a societal cost, the
value of gasoline taxes is subtracted
from the estimated gasoline price to
estimate the value of gasoline to society.
The agency has updated its estimates of
gasoline taxes, using the January 1,
2006, update in State gasoline taxes. In
2003 economics, Federal taxes are
$0.176 and State and local taxes average
$0.262 for a total of $0.438.
As will be discussed in this
document, the agency has carefully
considered the broad ramifications of
the final rule and alternative stringency
levels, and has not increased the fuel
economy levels solely on the basis of a
projection of higher gasoline prices.
The agency does not see the value of
trying to explain the difference in fuel
prices and technology between Europe
and the United States, as requested by
General Motors. As General Motors
points out in its comments, there are a
variety of factors which differentiate the
U.S. and Europe. These jurisdictions
have different legal/regulatory
frameworks, and their driving publics
have different expectations, all of which
vehicle manufacturers endeavor to
accommodate. Thus, the fuel economy
situations in Europe and the U.S. are not
directly comparable and any such effort
would entail an extensive analysis,
which is likely to generate inconclusive
results and which is well beyond the
scope of this rulemaking.
C. Consumer Valuation of Fuel
Economy and Payback Period
Commenters differed in terms of their
recommended approach for properly
assessing consumer valuation of fuel
economy and the payback period for
fuel-saving technologies. As discussed
below, some commenters favored
focusing on the preferences of
individual consumers using a short-term
perspective, while others recommended
focusing on the societal benefits to all
consumers over the long term.
General Motors requested that the
agency compare consumer preference
for fuel economy versus vehicle utility,
in order to determine consumer
valuation of improved fuel economy.
General Motors also asked NHTSA to
consider how many vehicle sales would
be deferred due to CAFE-related price
increases. According to General Motors,
history has shown that consumers value
fuel economy increases of up to 1.2
percent per year, so any higher standard
forces consumers to accept a lower level
of performance utility than they would
otherwise choose. However, General
Motors did state that consumers are well
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informed and extremely rational,
arguing that car buyers are less
concerned with fuel economy
improvements when gasoline cost $1.50
per gallon, as compared to marginal
improvements when gasoline costs
$2.50 per gallon.
According to the NADA, recent new
light truck sales data suggest that,
despite higher fuel prices, consumers
continue to rank fuel economy below
other purchase considerations, such as
capacity, convenience, utility,
performance, and durability. Thus,
NADA suggested that NHTSA’s fuel
economy standards should not be
permitted to result in undue constraints
on light truck product availability or in
significant price increases, which could
in turn result in reduced sales, profits,
and workforces, and the retention of
older vehicles with poorer fuel
efficiency.
The California State Energy
Commission commented that stringency
levels of fuel economy targets should be
established by considering the value of
fuel savings from vehicle owners’
perspective over the first few years of
each model year’s lifetime, rather than
from a society-wide perspective. For
example, the California State Energy
Commission argued that consumers
appear to attach some value to owning
hybrid vehicles beyond the fuel savings
they produce, sometimes paying large
price premiums (up to $3,500 compared
to equivalent gasoline-powered models)
and waiting extended periods of time
for such vehicles to become available.
The commenter stated that the size of
the hybrid vehicle market is expected to
grow significantly by MY 2010.
According to the California State Energy
Commission, such consumer valuation
considerations should be taken into
account as part of the CAFE standards.
Conversely, Environmental Defense
argued that technology application
should be based on societal costs, not
private costs, and that the agency needs
to consider benefits over the lifetime of
the vehicle, as opposed to the consumer
time horizon of 4.5 years.
The CAFE program’s most immediate
impacts are on individual consumers,
but regulating fuel economy also has a
broader societal effect that must be
considered. The agency believes that
CAFE standards should reflect the true
economic value of resources that are
saved when less fuel is produced and
consumed, higher vehicle prices, and, to
the extent possible, any externalities
that impact the broader society.
Consumer’s perceptions of these values
may differ from their actual impacts, but
they will nonetheless experience the
full value of actual fuel savings just as
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they will pay the full increased cost
when the vehicle is purchased.
Moreover, owners will realize these
savings throughout the entire on-road
life of each vehicle. While initial
purchasers will only experience fuel
savings for the limited time they
typically own a new vehicle (4.5 years),
subsequent (used vehicle) purchasers
will continue to experience savings
throughout the vehicle’s useful life. The
agency does restrict its analysis of sales
impacts to the initial 4.5 year period
under the assumption that initial
buyer’s purchase behavior will be
influenced only by their perception of
benefits they will receive while owning
the vehicle, as opposed to benefits
flowing to subsequent owners. However,
the agency believes that the lifetime
value of impacts from CAFE
improvements should be fully reflected
in its analysis of societal impacts.
D. Opportunity Costs
The Alliance commented that, in
proposing its fuel economy standards,
NHTSA did not consider the
opportunity costs to consumers who
may be forced to forego incremental
improvements in vehicle performance,
safety, capacity, comfort, and aesthetics
(citing a 2003 study by the
Congressional Budget Office (CBO)
titled, ‘‘The Economic Costs of Fuel
Economy Standards Versus a Gasoline
Tax,’’ Chapter 2, pages 1–5). The
Alliance also cited a recent study which
found that a CAFE increase of 3 mpg
results in a hidden tax of $0.78 per
gallon of fuel conserved.111 General
Motors added that to the extent the
CAFE standards force trade-offs between
fuel economy and other vehicle
attributes that consumers value,
consumer welfare will be reduced and
‘‘lost opportunity costs’’ will be
imposed on vehicle manufacturers.
Further, General Motors argued that
NHTSA’s engineering and economic
analyses are incomplete because they do
not account for the potential economic
harm to automobile companies (which
are already facing difficult financial
challenges) and their employees, and
the analyses do not include producer
and consumer welfare losses. General
Motors stated the Congressional Budget
Office estimated a consumer welfare
loss of $230 per vehicle.
In response, the agency notes that the
CBO report cited by General Motors and
the Alliance is based on estimates of
consumer’s preferences over a period
111 The Alliance cited this study as: Andrew N.
Kleit, ‘‘Impacts of Long-Range Increases in Fuel
Economy (CAFE) Standard,’’ Economic Inquiry
(April 2004), pages 279–294.
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from roughly 1980 through 2001. The
CBO report states that ‘‘Consumers’
preferences over the past 15 or 20 years
have led automakers to increase
vehicles’ size and horsepower, while
holding gasoline mileage more or less
constant.’’ The CBO report also
acknowledges that if consumers’ tastes
change significantly, the report’s
conclusions would be affected. The
period examined by CBO corresponds to
the period when automakers created
and successfully marketed SUVs as an
alternative to passenger cars for routine
driving. For most of this period,
gasoline prices were stable and low by
historical standards. Near the end of the
period, prices began to rise, but since
that time they have reached levels that
are more than double the typical price
during the period. In response,
consumers have shown a dramatic shift
in their purchase preferences. Sales of
small passenger cars and fuel-efficient
hybrids have increased, while sales of
large SUVs have dropped.
Circumstances have, thus, already
overtaken the assumptions regarding
consumer preferences used in the CBO
analysis. Moreover, the CBO analysis is
based on a CAFE regulation that
achieves an assumed 10 percent
reduction in gasoline consumption, a
greater reduction than that which would
be accomplished by this regulation.
Thus, the agency does not believe that
the $230 loss in consumer welfare
estimated in the CBO report is an
appropriate measure of the impact of
CAFE reform.
NHTSA acknowledges that there are
potential shifts in consumer welfare
which are not reflected in its model
(e.g., if a manufacturer reduced
horsepower as a strategy to improve fuel
economy, some consumers would value
that horsepower loss more than the fuel
economy gain). However, it believes that
measuring these impacts is problematic,
especially in light of the recent dramatic
shift in gasoline prices and geopolitical
events surrounding the world oil
supply. Moreover, the agency is using
its model, not as an absolute standard,
but rather as an initial measure to
consider in setting standards. The
agency is cognizant of the financial
difficulty facing automobile
manufacturers and is striving to
minimize costs by scheduling
improvements in such a way that they
would coincide with normal design
cycles. Further, the agency believes that
incrementally improving fuel economy
across the vehicle fleet will not deprive
consumers of their choice of vehicles. A
wide variety of vehicle types will
continue to be available, and
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consumers’ selection of vehicles should
still reflect their judgments of the
relative value of fuel economy versus
horsepower at the margin.
E. Rebound Effect
The ‘‘rebound effect’’ refers to the
tendency for vehicle owners to increase
the number of miles they drive a vehicle
in response to an increase in its fuel
economy, such as would result from
more stringent CAFE standards. The
rebound effect occurs because an
increase in fuel economy reduces
vehicle owners’ fuel cost per mile
driven, which is the typically largest
component of the cost of operating a
vehicle. Because even with improved
fuel economy this additional driving
uses some fuel, the rebound effect
somewhat reduces the fuel savings (and
related benefits) that result when fuel
economy increases. The rebound effect
is usually expressed as the percentage
by which vehicle use increases when
the cost of driving decreases due to an
increase in fuel economy and/or a
decrease in the price of fuel.
Commenters expressed a variety of
views regarding the agency’s estimate of
the rebound effect that would be
anticipated in response to the new
CAFE standards. While some reviewers
suggested that the estimate of the
rebound effect the agency used is too
low (Alliance, General Motors), others
suggested that it is too high
(Environmental Defense, NRDC, ACEEE,
Union of Concerned Scientists,
California State Energy Commission).
Specific comments related to the
rebound effect are set forth below.
In general, manufacturers and their
associations deemed the 20-percent
rebound rate relied upon by the agency
to be conservative. For example, the
Alliance argued that a 20-percent
rebound effect is overly conservative,
based upon recent studies. Specifically,
the Alliance stated that a recent study
of variation in U.S. light-duty vehicle
use among different states over the
period from 1966 to 2001 by Small and
Van Dender estimated a long-term
rebound effect of 24 percent over the
entire period covered by the study.112
This estimate implies that a 10-percent
increase in fuel economy, which
translates into a 10-percent decrease in
fuel cost-per-mile driven, would
ultimately stimulate a 2.4-percent
increase in average annual miles driven
112 Kenneth A. Small and Kurt Van Dender, ‘‘The
Effect of Improved Fuel Economy on Vehicle Miles
Traveled: Estimating the Rebound Effect Using U.S.
State Data, 1996–2001, Paper EPE–014, University
of California Energy Institute, 2005; item #1702 in
NHTSA Docket 22223. An earlier version of the
study is item 15 in the same docket.
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using vehicles whose fuel economy is
improved. According to the Alliance, an
independent analysis by the Small and
Van Dender data found that despite
those authors’ claim that the rebound
effect had declined during the period
they studied, the rebound effect
remained at 24.6 percent at the end of
this period.113 The Alliance opined that
the rebound effect is probably on the
order of 35 percent, although it did not
supply any data to substantiate this
estimate.
According to General Motors,
previous studies of changes in
household motor vehicle and appliance
use in response to improvements in
their energy efficiency (which is
measured by fuel economy in the case
of vehicles) have shown that the
rebound effect lowers energy savings by
20–50 percent. General Motors agreed
with the agency that the increased
driving resulting from the rebound
effect also imposes various external
costs, including increased collisions and
traffic congestion. General Motors stated
that it commissioned four studies of the
rebound effect, each of which
concluded that the rebound effect
would be approximately 25 percent.
However, it did not provide copies of
the referenced studies. As General
Motors did not provide these studies,
the agency was unable to evaluate them.
Nevertheless, General Motors stated that
20 percent is adequate for calculations
related to rebound effect. No other
vehicle manufacturers commented on
this issue.
The National Automobile Dealers’
Association commented that fuel
savings should clearly be adjusted to
reflect the rebound effect, but did not
recommend a specific value of the
rebound effect.
In contrast to the above commenters,
Environmental Defense argued that the
agency has overestimated the rebound
effect because it relies upon earlier
studies in the literature that tended to
miss significant effects of variables such
as income growth, and that did not have
sufficiently large datasets to capture
long-term changes in vehicle use. Citing
the same 2004 study by Small and Van
Dender referred to in the Alliance
comments,114 which combined data for
each of the 50 states over a 36-year
period, Environmental Defense noted
the authors’ finding that the rebound
effect had declined to 12.1 percent
when measured over the period from
1997–2001, primarily as a consequence
113 Robert Crawford, ‘‘Review and Assessment of
VMT Rebound Effect in California,’’ RW Crawford
Energy Systems, Sept. 2004.
114 See footnote 95.
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of the higher income levels that
prevailed during those years than over
the entire period covered by the study.
Environmental Defense argued further
that if income growth continues during
the period analyzed under the CAFE
proposal, Small and Van Dender’s
analysis indicates that the rebound
effect would continue to decline. The
analyses Environmental Defense
presented in its comments used an
estimate of 5 percent for rebound effect,
and it also urged NHTSA to adopt a
similarly low estimate of the rebound
effect, which Environmental Defense
argued is in keeping with the most
recent research in this area.
Other commenters also urged NHTSA
to adopt a lower rate for the rebound
effect, and they generally referred to the
study by Small and Van Dender to
support their positions. For example,
NRDC suggested using a 6-percent rate
for the rebound effect over the lifetime
of MY 2008–2011 vehicles, which it
argued would correctly recognize the
effect of anticipated future income
growth. ACEEE urged the agency to use
a 10-percent rate, a change which it
suggested would increase the monetized
´
social benefits of Reformed CAFE for
MY 2011 vehicles by about $1.3 billion,
or approximately 30 percent.
Again, relying on results from the
Small and Van Dender study, the Union
of Concerned Scientists recommended
that NHTSA reduce the rebound effect
rate to not more than 10 percent. The
commenter stated that NHTSA offered
no justification for choosing the upper
end of its discussed range (10–20
percent), arguing that results for the last
years of the period analyzed in the
study supported a long-run rebound
effect of 6.8 percent or lower.
Accordingly, the Union of Concerned
Scientists stated that NHTSA should
adopt 10 percent as a reasonable and
conservative estimate of the rebound
effect, and asserted that doing so would
increase the ‘‘social optimum’’ fuel
economy targets for 2011 by 1.4–1.9
mpg.
The California State Energy
Commission called for a rebound effect
of 12 percent, which it believes is
reflective of the long-term rebound
effect of 12.1 percent for California
estimated by Small and Van Dender.115
NHTSA notes that all commenters
who recommended a lower value for the
rebound effect than the 20 percent
estimate used in the NPRM analysis
115 Kenneth A. Small and Kurt Van Dender, ‘‘The
Effect of Improved Fuel Economy on Vehicle Miles
Traveled: Estimating the Rebound Effect Using U.S.
State Data, 1996–2001, Paper EPE–014, University
of California Energy Institute, 2005, Docket 22223–
1702, Table 5, p. 19.
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relied exclusively upon the recent study
by Small and Van Dender as evidence
supporting a smaller rebound effect.
While the agency regards the Small and
Van Dender study as an important
contribution to the extensive literature
on the magnitude of the rebound effect,
it does not regard the very low values
for the rebound effect reported in that
study as persuasive for several reasons.
Unlike the studies relied upon by the
agency in developing its estimate of the
rebound effect, the Small and Van
Dender analysis remains an
unpublished working paper that has not
been subjected to formal peer review, so
the agency does not yet consider the
estimates it provides to have the same
credibility as the published and widelycited estimates it relied upon.116 The
agency’s interpretation of previously
published estimates is that they support
a range of 10–30 percent for the rebound
effect in vehicle use. The agency elected
to use the midpoint of that range in its
analysis for the NPRM. If a peerreviewed version of the Small and Van
Dender study is subsequently
published, the agency will consider it in
developing its own estimate of the
rebound effect for use in subsequent
CAFE rulemakings.
After reviewing the various comments
on the NPRM, the agency has elected to
continue using a value of 20 percent for
the rebound effect in its analysis of
potential fuel savings from stricter
CAFE standards for MY 2008–2011 light
trucks. The agency will continue to
monitor newly published research on
the rebound effect (as well as on other
critical parameters affecting fuel savings
from CAFE regulation), and it will
revise the estimates of the rebound
effect it employs in future analyses of
fuel savings if it concludes that new
evidence points persuasively toward a
different value.
F. Discount Rate
Discounting future fuel savings and
other benefits is intended to measure
116 These include, among others, David L. Greene,
‘‘Vehicle Use and Fuel Economy: How Big is the
Rebound Effect?’’ The Energy Journal, 13:1 (1992),
117–143; David L. Greene, James R. Kahn, and
Robert C. Gibson, ‘‘Fuel Economy Rebound Effect
for Household Vehicles,’’ The Energy Journal, 20:3
(1999), 1–21; Jonathan Haughton and Soumodip
Sarkar, ‘‘Gasoline Tax as a Corrective Tax: Estimates
for the United States,’’ The Energy Journal, 17:2, pp.
103–126; S.L. Puller and L.A. Greening,
‘‘Household Adjustment to Gasoline Price Changes:
An Analysis Using Nine Years of U.S. Survey Data,’’
Energy Economics, 21:1, pp. 37–52; Jones, Clifton
T., ‘‘Another Look at U.S. Passenger Vehicle Use
and the ‘Rebound’ Effect from Improved Fuel
Efficiency, The Energy Journal, 14:4 (1993), 99–110;
and Goldberg, Pinelopi Koujianou, ‘‘The Effects of
the Corporate Average Fuel Efficiency Standards in
the U.S.,’’ The Journal of Industrial Economics, 46:1
(1998), 1–33.
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the reduction in the value to society of
these benefits when they are deferred
until some future date rather than
received immediately. The discount rate
expresses the percent decline in the
value of these benefits—as viewed from
today’s perspective—for each year they
are deferred into the future. The agency
used a discount rate of 7 percent per
year to discount the value of future fuel
savings and other benefits when it
analyzed the CAFE standards proposed
in the NPRM.
The Alliance, General Motors, the
Mercatus Center, and Criterion
Economics all argued that in assessing
benefits and costs associated with the
CAFE standards, the agency should rely
on a discount rate greater than 7
percent. The Alliance stated that the
Congressional Budget Office discounts
consumers’ fuel savings at a rate of 12
percent per year and that other recent
studies of CAFE standards have also
used that rate. According to the
Alliance, that rate is slightly higher than
the average interest rate that consumers
reported paying to finance used car
purchases in the most recent Consumer
Expenditure Survey.117 The Alliance
argued further that consumers can be
expected to discount the value of future
fuel savings at a rate at least as high as
their cost for financing the purchase of
a vehicle whose higher price was
justified by its higher fuel economy.
The Alliance based its assertion for
use of 12 percent because, as it stated,
this value was used in the NAS report
and approximates the used car loan rate
published in the Consumer Expenditure
Survey. However, we note that the NAS
report did not use a single discount rate.
Instead, the NAS used both 12 percent
and 0 percent discount rates due to the
assumption that the proper discount
rate was ‘‘subjective.’’ Therefore, NAS
did not advocate a discount rate. As
explained below, the vehicle loan rate
faced by consumers is an appropriate
measure of the discount rate.
General Motors suggested a discount
rate of 9 percent, based on its assertions
that new vehicles are financed at 8
percent and used vehicles at 10 percent.
Essentially, General Motors is
recommending that the agency rely on
the interest for a car loan as the discount
rate. General Motors also argued that
fuel economy is not the only thing
117 The Consumer Expenditure Survey (CE)
program consists of two surveys collected for the
Bureau of Labor Statistics by the Census Bureau—
the quarterly Interview survey and the Diary
survey—that provide information on the buying
habits of American consumers, including data on
their expenditures, income, and consumer unit
(families and single consumers) characteristics.
https://www.bls.gov/cex/home.htm.
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which consumers value and that the
agency should take efforts to separate
private benefits from public
externalities. While we are uncertain as
to what General Motors is
recommending, we assume that its
comment suggests that a higher discount
rate, based on car loan rates, is
appropriate for discounting private
benefits (those to buyers), while a lower
rate is appropriate for social benefits
(such as reductions in externalities).
Criterion Economics also recommended
use of a 9 percent discount rate in its
comments, which it suggested is a
conservative rate between the average
real rates for new and used cars that
adequately accounts for volatility in
future energy prices.
As discussed further below, we agree
in that loan rates for new and used cars
should be considered when determining
the appropriate discount rate. However,
loan estimates made by both General
Motors and Criterion Economics are
considerably higher than data provided
by the Federal Reserve Board, which
estimates new loan rates (as of October
2005) of 6 percent for new cars and 9
percent for used cars.118
The Mercatus Center stated that the 7
percent discount rate selected by the
agency is too low, and as a result, it
results in the setting of standards that
are inequitable, particularly to lowincome households. According to
published academic research referenced
by the Mercatus Center, most
households have discount rates higher
than 7 percent, with low-income
households having particularly high
discount rates. Therefore, the Mercatus
Center urged NHTSA to rely on
discount rates of 12 percent for all
households and as high as 20 percent
for low-income households in
evaluating proposed standards.
However, the studies cited by Mercatus
Center to justify these discount rates
examine the implied discount rate for
future energy savings that result when
households purchase more energyefficient appliances such as furnaces
and air conditioners. These studies were
generally conducted in the late 1970’s
and early 1980’s and may not be
representative of the discount rates for
motor vehicles of the economic
conditions 20–25 years later.
Environmental Defense, NRDC, and
the Union of Concerned Scientists
provided comments endorsing use of a
lower discount rate. These organizations
expressed their belief that a 7-percent
discount rate is too high, proposing
118 Federal
Reserve Board, Statistical Release
G.19: Consumer Credit, https://www.federalreserve.
gov/releases/g19/.
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instead a rate of 3 percent.
Environmental Defense and NRDC
stated that OMB Circular A–4,
Regulatory analysis (2003), recommends
a discount rate of 3 percent when the
regulation directly affects private
consumption. These commenters
asserted that the proposed CAFE
regulation primarily and directly affects
private consumption (i.e., by affecting
the sales price of new vehicles and
reducing the per-mile cost of driving).
NRDC also argued that OMB Circular A–
4 further indicates that lower rates may
be appropriate for rules that produce
benefits over multiple generations.
Thus, these commenters recommended
that a discount rate reflecting the social
rate of time preference (i.e., a 3 percent
real rate) should be used.
In response to Environmental
Defense, the Union of Concerned
Scientists, and NRDC, the guidelines in
OMB circular A–4, New Guidelines for
the Conduct of Regulatory Analysis,
state that the agency should analyze the
costs and benefits of a regulation at 3
percent and 7 percent discount rates, as
suggested by guidance issued by the
federal OMB.119 The 3 percent and 7
percent rates reflect two potential
evaluations of impacts: Foregone private
consumption and foregone capital
investment, respectively. In accordance
with these guidelines, the agency
analyzes the impacts of costs and
benefits using both discount rates.
However, this guidance does not state
what discount rate should be used to
determine the standards.
There are several reasons for the
agency’s choice of 7 percent as the
appropriate discount rate to determine
the standards. First, OMB Circular A–4
indicates that this rate reflects the
economy-wide opportunity cost of
capital. The agency believes that a
substantial portion of the cost of this
regulation may come at the expense of
other investments the auto
manufacturers might otherwise make.
Several large manufacturers are
resource-constrained with respect to
their engineering and productdevelopment capabilities. As a result,
other uses of these resources will be
foregone while they are required to be
applied to technologies that improve
fuel economy.
Second, 7 percent is also an
appropriate rate to the extent that the
costs of the regulation come at the
expense of consumption as opposed to
investment. As explained below, the
119 White House Office of Management and
Budget, Circular A–4, September 17, 2003, p. 34,
https://www.whitehouse.gov/omb/inforeg/
circular_a4.pdf.
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agency believes a car loan rate is an
appropriate discount rate because it
reflects the opportunity cost faced by
consumers when buying vehicles with
greater fuel economy and a higher
purchase price. The agency assumed
that a majority of both new and used
vehicles is financed and since the vast
majority of the benefits of higher fuel
economy standards accrue to vehicle
purchasers in the form of fuel savings,
the appropriate discount rate is the car
loan interest rate paid by consumers.120
According to the Federal Reserve, the
interest rate on new car loans made
through commercial banks has closely
tracked the rate on 10-year treasury
notes, but exceeded it by about 3
percent.121 The official Administration
forecast is that real interest rates on 10year treasury notes will average about 3
percent through 2016, implying that 6
percent is a reasonable forecast for the
real interest rate on new car loans.122
During the last five years, the interest
rate on used car loans made through
automobile financing companies has
closely tracked the rate on new car loans
made through commercial banks, but
exceeded it by about 3 percent.123
Consideration is given to the loan rate
of used cars because some of the fuel
savings resulting from improved fuel
economy accrue to used car buyers.
Given the 6 percent estimate for new car
loans, a reasonable forecast for used car
loans is 9 percent. Since the benefits of
fuel economy accrue to both new and
used car owners, a discount rate
between 6 percent and 9 percent is
appropriate. Assuming that new car
buyers discount fuel savings at 6
percent for 5 years (the average duration
of a new car loan) 124 and that used car
buyers discount fuel savings at 9
percent for 5 years (the average duration
of a used car loan),125 the single
constant discount rate that yields
equivalent present value fuel savings is
very close to 7 percent.
Further, reliance on the consumer
borrowing rate is consistent with that of
the Department of Energy (DOE)
program for energy efficient appliances.
For more than a decade, the Department
of Energy has used consumer borrowing
interest rates or ‘‘finance cost’’ to
discount the value of future energy
120 Empirical evidence also demonstrates that
used car purchasers do pay for greater fuel economy
(Kahn, Quarterly Journal of Economics, 1986).
121 See, https://www.federalreserve.gov/releases/
g20/hist/fc_hist_tc.txt.
122 See, https://www.federalreserve.gov/releases/
h15/data/Monthly/H15_TCMNOM_Y10.txt.
123 See, https://www.federalreserve.gov/releases/
g20/hist/fc_hist_tc.txt.
124 Id.
125 Id.
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savings in establishing minimum energy
efficiency standards for household
appliances. This includes (1) the
financial cost of any debt incurred to
purchase appliances, principally
interest charges on debt, or (2) the
opportunity cost of any equity used to
purchase appliances, principally
interest earnings on household equity.
For example, for appliances purchased
in conjunction with a new home, DOE
uses real mortgage interest rates to
discount future energy savings.126 This
approach is analogous to NHTSA’s use
of real auto loan rates to discount future
gasoline savings in establishing CAFE
standards.
The Union of Concerned Scientists
also commented that NHTSA’s
methodology for calculating the
discounted present value of certain
external costs and benefits appears to be
inconsistent. Specifically, the
commenter stated that the benefits of
petroleum market effects
(monopsony 127 and disruption cost
reductions) and reduced emissions of
particulate matter (PM) and sulphur
oxides (SOX) and the external costs of
increased congestion, noise, and
crashes, appear to be discounted
differently from the fuel cost savings,
driving time, and refueling time savings.
The Union of Concerned Scientists
urged NHTSA to utilize the same
methodology for calculating the
discounted present value of all such
CAFE-related elements.
In response to the Union of
Concerned Scientists comment that the
agency appears to have discounted
different categories of benefits
inconsistently, the agency notes that the
three different categories identified in
its comment each bear a different
relationship to total fuel savings. As the
commenter notes, fuel cost savings, the
value of increased driving range
(identified incorrectly as ‘‘driving time’’
in the PRIA), and the value of refueling
time savings are directly related to
lifetime vehicle use, and the agency’s
estimates of the values of these benefits
126 See, Residential Furnaces and Boilers ANOPR
Technical Support Document, Chapter 8, at
https://www.eere.energy.gov/buildings/
appliance_standards/residential/
furnaces_boilers_1113_r.html.
127 Demand costs for imported oil (often termed
market power or ‘‘monopsony’’ costs) arise because
the world oil price appears to be partly determined
through the exercise of market power by the OPEC
cartel, and because the U.S. is a sufficiently large
purchaser of foreign oil supplies that its purchases
can affect the world price. The combination of
OPEC market power and U.S. ‘‘monopsony’’ power
means that increasing domestic petroleum demand
that is met through higher oil imports can cause the
world price of oil to rise, and conversely that
declining U.S. imports can reduce the world price
of oil.
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reflect this relationship. However,
benefits resulting from lower emissions
of the pollutants PM and SOX (which
occur during petroleum refining) also
depend partly on the fraction of fuel
savings that is reflected in reduced
domestic fuel refining (rather than
reduced imports of refined gasoline),
and in turn on the fractions of domestic
refining that utilize domesticallyproduced and imported crude
petroleum.128 Similarly, the external
costs of congestion, accidents, and noise
resulting from added vehicle use
depend on the magnitude of the
rebound effect as well as on lifetime fuel
savings. Thus these three categories of
benefits would be expected to bear
different relationships to total fuel
savings, as confirmed by the Union of
Concerned Scientists’ comments.
G. Import Externalities (Monopsony, Oil
Disruption Effects, Costs of Maintaining
U.S. Presence and Strategic Petroleum
Reserve)
General Motors commented
extensively on the issue of externalities
associated with the agency’s CAFE
proposal. As a general observation,
General Motors stated that the CAFE
proposal would result in a net
externality cost on consumer welfare,
because the externality costs (e.g.,
congestion, noise, highway fatalities/
injuries) exceed the externality benefits
(e.g., reduction in oil import
dependence, reduction in pollution).
General Motors stated that the agency’s
proposal did not identify any specific
market failures that would justify its
fuel economy regulation. The
commenter asked the agency to present
empirical estimates of reduced
economic and environmental
externalities resulting from the
proposed CAFE standards, along with
supporting analyses demonstrating how
these benefits were estimated.
In its comments, General Motors also
challenged certain specific figures
related to externalities incorporated by
the agency as part of the CAFE proposal.
For example, General Motors expressed
disagreement with the proposal’s
externality estimate of $0.106 per
gallon, as well as the estimate of costs
related to pollution. The commenter
stated that the National Research
Council estimates the total cost of
128 In the NPRM, benefits from reduced petroleum
market externalities were also incorrectly assumed
to depend on the fraction of fuel savings that is
reflected in lower imports of crude petroleum and
refined gasoline (rather than on total U.S. petroleum
consumption). In response to comments by the
Union of Concerned Scientists and other reviewers,
this error has been corrected in the Final Regulatory
Impact Analysis accompanying this Rule.
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economic and environmental
externalities from fuel production and
use to be $0.26 per gallon, and if this
estimate is correct, consumers are
already paying fuel taxes (which it
estimated at $0.46 per gallon) that
exceed the cost of these externalities.
General Motors also asked the agency to
address the research finding by Dr. Kleit
purporting to show negative net benefits
(i.e., it will have net costs) for the MY
2005–2007 CAFE standards.129
In addition, General Motors argued
that higher steady-state oil prices reduce
any demand costs or monopsony power,
and energy demand from China and
other emerging economies will only
strengthen this trend. The company
disagreed with the monopsony estimate
of $0.061 per gallon relied upon by the
agency. General Motors further argued
that the agency relied upon the
monopsony value reported in a 1997
study by Lieby et al., but stated that this
study assumes no cartel of producers
such as OPEC. According to General
Motors, in light of the potential for
OPEC to respond to U.S. efforts to
decrease demand, the monopsony value
of $0.061 is too high. General Motors
stated that like Resources for the Future,
it believes that using U.S. monopsony
power has marginal benefits at best, and
that at worst, attempting to use it could
actually provoke retaliatory pricing or
supply responses by OPEC that would
harm the U.S. economy.
General Motors also challenged the oil
disruption cost of $0.045 per gallon
included in the proposal. According to
General Motors, the agency has not
addressed Congressional Research
Service and the Bohi and Toman studies
which reported that the only reason for
oil disruption is an increase in price
(i.e., an oil price ‘‘shock’’), so because
the CAFE standards do not affect the
price of gasoline, there should be no
disruption effect.
General Motors expressed skepticism
regarding the externality costs related to
pollution contained in the CAFE
proposal. According to General Motors,
because U.S. refineries operate at 95
percent of capacity and routinely
129 Dr. Kleit’s analysis simply assumes that
manufacturers have already made all applications
of fuel economy technology to their models for
which the value of the resulting fuel savings
exceeds the cost of installing the technology.
Andrew N. Kleit, ‘‘Short- and Long-Range Impacts
of Increases in the Corporate Average Fuel Economy
(CAFE) Standard,’’ February 7, 2002, Docket
#11419–168159.
Under this assumption, any increase in the
stringency of CAFE will always produce negative
net benefits (i.e., net costs), because the technology
applications necessary to comply with the more
stringent standard will each have costs that exceed
the value of fuel savings they produce.
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purchase pollution permits (credits)
from others, any reduction in demand
for fuel would likely result in these
refineries simply purchasing fewer
permits, rather than reducing emissions
or capacity. General Motors stated that
the only pollution cost externality
resulting from the CAFE standards is
likely to be increased tailpipe emissions
from the rebound effect.
Criterion Economics commented that
NHTSA’s CAFE proposal ‘‘argued the
wrong case,’’ in that externalities alone
should be the determinant of socially
optimal CAFE levels (i.e., allowing the
marketplace to determine privately
optimized CAFE targets). According to
Criterion Economics, mandatory
increases in fuel economy above marketdetermined levels would generate
marginal private costs that exceed
marginal private benefits. In support of
its position that only externalities
should be considered in setting CAFE
standards, Criterion Economics
provided a figure illustrating the
interaction of marginal social benefits,
marginal social costs, marginal private
benefits, and marginal private costs to
argue that the market automatically
determines the optimal level for private
benefits. Criterion Economics
recommended that the agency revise the
CAFE standards to reflect socially
optimal levels based on externality costs
and benefits.
In contrast, NRDC and Environmental
Defense argued that monopsony costs
are underestimated in the proposal.
Environmental Defense stated that
monopsony costs should range from
$0.083 (under the EIA reference
scenario) to $0.198 per gallon (under a
$65 per barrel oil price scenario).
Environmental Defense also commented
that there is an arithmetic error in
NHTSA’s application of disruption and
adjustment costs (which are otherwise
conceptually correct), and it argued that
in setting final CAFE standards, the
agency should address non-quantified
externalities such as strategic petroleum
reserve and national security costs, at
least qualitatively if not quantitatively.
The California State Energy
Commission argued that the agency’s
estimate of $0.106 for oil import
externalities is too low and should be
increased to $0.33 per gallon of
gasoline. The California State Energy
Commission broke down this estimate
as follows: $0.12 per gallon for oil
import externalities; $0.01 to reflect
costs of gasoline spill remediation;
$0.02 to reflect damage from criteria
pollutant emissions resulting from fuel
delivery volumes, and $0.18 to reflect
damage costs of greenhouse gas
emissions. The Commission based its
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recommendation upon values reported
in a 2003 report titled ‘‘Benefits of
Reducing Demand for Gasoline and
Diesel.’’
The agency believes that assessing the
economic case for increasing the
stringency of the light truck CAFE
standard requires a comprehensive
analysis of the resulting benefits and
costs to the U.S. economy, rather than
simply comparing the external costs
associated with petroleum use and fuel
production to current fuel taxes. The
benefits of more stringent CAFE
standards include the market value of
the savings in resources from producing
less fuel, together with the resulting
reductions in the costs of economic
externalities associated with petroleum
consumption, and of environmental
externalities caused by fuel production.
The costs imposed on the U.S. economy
by more stringent CAFE regulation
include those costs for manufacturing
more fuel-efficient vehicles, as well as
the increased external costs of
congestion, accidents, and noise from
added driving caused by the rebound
effect.
Vehicle buyers value improved fuel
economy using retail fuel prices and
miles per gallon, but may consider fuel
savings only over the time they expect
to own a vehicle, while the value to the
U.S. economy of saving fuel is measured
by its pre-tax price, and includes fuel
savings over the entire lifetime of
vehicles. Thus it cannot simply be
assumed that the interaction of
manufacturers’ costs and vehicle buyers’
demands in the private marketplace will
determine optimal fuel economy levels,
and that these levels should only be
adjusted by Federal regulation if the
external costs of fuel production and
use exceed current fuel taxes.
The analysis reported in the FRIA
estimates the value of each category of
benefits and costs separately, and it
compares the total benefits resulting
from each alternative CAFE level to its
total costs in order to assess its
desirability. This more complete
accounting of benefits and costs to the
U.S. economy from reducing fuel use is
necessary to assess the case for CAFE
regulation generally, and for increasing
the stringency of the current light truck
CAFE standard in particular.
In response to comments on the
specific values of certain externalities
employed in the NPRM analysis, the
agency agrees that higher world oil
prices increase the monopsony or
demand costs imposed by U.S.
petroleum purchases, while greater
sensitivity of the supply of oil imported
by the U.S. to variation in its price (a
higher elasticity of petroleum supply)
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reduces the monopsony costs associated
with variation in U.S. oil demand.130
Thus, the value of the monopsony effect
used in the FRIA analysis reflects the
Energy Information Administration’s
recent Annual Energy Outlook 2006
forecast of future world oil prices,
which is significantly higher than
previously projected by EIA (see FRIA
p. VIII–31). The FRIA continues to use
the midpoint of the range of values for
the elasticity of oil imports suggested in
the study by Leiby et al. to estimate the
monopsony cost of increased U.S.
petroleum use (see FRIA p. VIII–33).
However, the agency also notes that
only a fraction of the monopsony cost of
increased U.S. oil consumption is
imposed on domestic purchasers of
petroleum and refined products, since
part of the burden of higher world oil
prices is borne by foreign purchasers. As
a result, that same fraction of any
reduction in monopsony costs resulting
from lower U.S. oil purchases is exactly
offset by revenue losses to domestic
petroleum producers, so it does not
represent a net savings to the U.S.
economy. Thus, in order to include only
the fraction that represents a net savings
to U.S. purchasers, the savings in
monopsony costs from reduced fuel use
must be adjusted by the percent of U.S.
petroleum consumption that is
imported. This results in a monopsony
value of $0.044 per gallon.
In contrast, the entire reduction in
total U.S. petroleum demand that results
from more stringent CAFE standards
reduces potential costs to the U.S.
economy from rapid increases in world
oil prices, because (as the studies cited
by reviewers of the NPRM point out)
these costs depend on total U.S.
petroleum consumption rather than on
the fraction that is imported. The agency
agrees that petroleum buyers’ use of
hedging strategies and private oil
inventories can reduce these costs, but
the significant costs of adopting these
strategies will also be reduced as
declines in U.S. petroleum demand
moderate the potential effect of rapid
fluctuations in world oil prices. Thus
the analysis presented in the FRIA
continues to employ the agency’s
previous estimate ($0.045 per gallon) of
the reduction in the price shock
component of U.S. oil consumption
externalities that is likely to result from
more stringent CAFE regulation (see
FRIA VIII–34).
Finally, the agency believes that while
costs for U.S. military security in oil130 For the exact relationship among monopsony
costs, oil prices, and the elasticity of supply of
imported oil, see Leiby et al., p. 26 Docket No.
NHTSA–2005–22223–27.
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producing regions and for maintaining
the Strategic Petroleum Reserve will
vary in response to long-term changes in
U.S. oil imports, these costs are unlikely
to decline significantly in response to
the modest reduction in the level of U.S.
oil imports that would result from the
proposed CAFE standard for MY 2008–
2011 light trucks. The U.S. military
presence in world regions that represent
vital sources of oil imports also serves
a range of security and foreign policy
objectives that is considerably broader
than simply protecting oil supplies. As
a consequence, no savings in
government outlays for maintaining the
Strategic Petroleum Reserve or a U.S.
military presence are included among
the benefits of the light truck CAFE
standard adopted for MY 2008–2011.
Combined, the externalities cost per
gallon added to the pre-tax price per
gallon in the FRIA is $0.088.131 This
compares to the PRIA estimate of $0.106
per gallon.
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H. Uncertainty Analysis
The California State Energy
Commission stated NHTSA’s proposal
does not adequately deal with the
primary source of uncertainty in setting
standards—the extent to which the
application of additional technology
could be justified by higher future fuel
prices. This commenter stated that the
agency’s uncertainty analysis should
first examine the sensitivity of optimum
standards to variation in retail fuel
prices only, and then analyze effect of
alternative stringency levels on social
benefits.
In response, we note that the purpose
of the uncertainty analysis is to examine
uncertainty surrounding the impact of
the proposed and final rules. OMB
Circular A–4 requires formal
probabilistic uncertainty analysis of
complex rules where there are large,
multiple uncertainties whose analysis
raises technical challenges or where
effects cascade and where the impacts of
the rule exceed $1 billion. CAFE meets
these criteria on all counts. However,
the commenter appears to be concerned
primarily with uncertainty surrounding
the CAFE standard selection process,
rather than that surrounding the impacts
of the selected standards. The agency
believes that its selection of CAFE levels
should be based on its best estimates of
all input variables used to estimate
optimized social benefits. An
examination of the uncertainty of
outcomes in this process would produce
131 The $0.088 value represents the value for
reducing U.S. demand on the world market plus the
value for reducing the threat of supply disruptions.
See Table X–3 in the FRIA.
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information of academic interest but
would not alter the agency’s reliance on
the most probable outcome for setting
standards. It is also not clear that
uncertainty surrounding the price of
gasoline is greater than that surrounding
other variables used in the NHTSA
model. In fact, the range of uncertainty
for both the effectiveness and cost of
technologies includes more potential
variation than the three fuel price
scenarios examined in the uncertainty
analysis. Since each of these factors
influences the calculation of optimized
social benefits, the agency does not
believe it would be useful to isolate only
the uncertainty in fuel prices.
I. The 15 Percent Gap
The agency assumes that there is a 15
percent difference between the EPA fuel
economy rating and the actual fuel
economy achieved by vehicles on the
road. For example, if the overall EPA
fuel economy rating of a light truck is
20 mpg, the actual on-road fuel
economy achieved by the average driver
of that vehicle is expected to be 17 mpg
(20*.85). NRDC and the Union of
Concerned Scientists commented that
the 15-percent reduction the agency
applied to reported fuel economies to
adjust for in-use fuel economy
performance is too low, and both
commenters recommended using an onroad gap of 20 percent. The Union of
Concerned Scientists stated that the
EPA is in the process of revising its
estimates of real-world fuel economy in
response to widespread consumer
dissatisfaction with the reliability of its
present adjustment. In support of its
recommendation to use a 20-percent
reduction, NRDC cited the range of 20
to 23 percent relied upon by EIA’s
National Energy Modeling System
(NEMS) over the expected lifetimes of
MY 2008–2011 vehicles (See AEO2005
Table 47). General Motors stated that it
agrees with a 15 percent on-road fuel
economy gap.
On February 1, 2006, the
Environmental Protection Agency
proposed test changes to their fuel
economy testing to bring them closer to
on-road fuel economy (71 FR 5426). In
its proposal, EPA estimated that the
actual highway driving fuel economy
estimate would be 5 to 15 percent lower
than the EPA fuel economy rating and
that the actual city driving fuel economy
estimate would be 10 to 20 percent
lower than the EPA fuel economy rating
for most vehicles. However, the EPA has
not issued a final rule on this issue.
NHTSA will continue to rely on an
overall fuel economy adjustment factor
of 15 percent, consistent with current
EPA regulations. In future rulemakings
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17637
the agency will consider new
regulations as issued by the EPA.
J. Pollution and Greenhouse Gas
Valuation
In its comments, General Motors
maintained that increases in emissions
of criteria pollutant resulting from the
rebound effect are not likely to be offset
by reduced refinery emissions, as
assumed in the agency’s analysis. As
noted earlier, General Motors argued
that domestic refineries are subject to
strict emission caps, and they must buy
permits (credits) in order to support
current production. It concluded that a
small reduction in overall ‘‘demand for
fuel would allow domestic refineries to
simply buy fewer pollution permits
without changing the emissions at the
refineries.’’
General Motors also asserted that
domestic refineries produce at over 95
percent of capacity, and that all
increases in demand for refined
products must be met by imports.
Therefore, General Motors concluded
that a reduction in demand for fuel
would not reduce domestic refinery
output and corresponding pollutants,
but instead would cause a reduction in
imports of refined products such as
gasoline.
In response to General Motors’
comments, the agency notes that there
are currently two cap-and-trade
programs governing emissions of criteria
pollutants by large stationary sources.
The Acid Rain Program seeks to limit
NOX and SO2 emissions, but applies
only to electric generating facilities and
thus will not affect refinery
emissions.132 The NOX Budget Trading
Program is also primarily intended to
reduce electric utility emissions, but
does include some other large industrial
sources such as refineries. However, as
of 2003, refineries participating in the
program accounted for less than 5% of
total NOX emissions by U.S.
refineries.133 In addition, some
refineries could be included among the
sources of NOX emissions that will be
controlled under the recently-adopted
Clean Air Interstate Rule, which is
scheduled to take effect beginning in
2009.134 However, refinery NOX
132 See https://www.epa.gov/airmarkets/arp/
index.html.
133 Estimated from EPA, NO Budget Trading
X
Program (SIP Call) 2003 Progress Report, Appendix
A, https://www.epa.gov/airmarkets/cmprpt/nox03/
NBP2003AppendixA.xls, and National Air Quality
and Emissions Trends Report 2003, Table A–4,
https://www.epa.gov/air/airtrends/aqtrnd03/pdfs/
a4.pdf.
134 The Clean Air Interstate Rule also requires
reductions in SO2 emissions and establishes an
emissions trading program to achieve them, but
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emissions could only be affected in
states that specifically elect to include
sources other than electric generating
facilities in their plans to comply with
the rule. The EPA has indicated that it
expects states to achieve the emissions
reductions required by the Clean Air
Interstate Rule primarily from the
electric power industry.135 Thus the
agency continues to believe that any
reduction in domestic gasoline refining
resulting from the adopted CAFE
standard will be reflected in reduced
refinery emissions of criteria pollutants.
Environmental organizations stated
that the agency must attach some value
to reducing greenhouse gas emissions,
and adjust the benefits of more stringent
CAFE standards accordingly. NRDC
recommended a value of $10 to $25 per
ton of CO2 emissions reduced by fuel
savings from stricter CAFE, based on
values assigned by the California Public
Utilities Commission, Idaho Power Co.,
and the European Union emissions
program. Environmental Defense stated
that the agency should use a value of
$50 per ton of reduced CO2 emissions.
The Union of Concerned Scientists
similarly objected to the zero value
assigned to reduced emissions of
greenhouse gases in the CAFE proposal,
and instead recommended using a value
of $50 per ton of carbon (corresponding
to approximately $0.15 per gallon of
gasoline).
The estimated reductions in
emissions of criteria pollutants from
gasoline refining and distribution used
in the PRIA analysis were adjusted to
reflect only the fraction of fuel savings
that is expected to reduce domestic
refining, rather than imports of refined
gasoline. They were also adjusted to
include only reductions in emissions
that occur during domestic extraction
and transportation of crude petroleum
feedstocks. The estimates of these
reduced emissions from crude oil
extraction and gasoline refining used in
the FRIA continue to reflect these
adjustments (see FRIA p. VIII–60).
The agency continues to view the
value of reducing emissions of CO2 and
other greenhouse gases as too uncertain
to support their explicit valuation and
inclusion among the savings in
environmental externalities from
reducing gasoline production and use.
There is extremely wide variation in
only electric generating facilities are included in the
rule’s SO2 emissions trading program; see EPA,
Clean Air Interstate Rule: Basic Information, https://
www.epa.gov/cair/basic.html#timeline.
135 See EPA, Clean Air Interstate Rule: Basic
Information, https://www.epa.gov/cair/
basic.html#timeline, and ‘‘Fact Sheet: Clean Air
Interstate Rule,’’ https://www.epa.gov/cair/pdfs/
cair_final_fact.pdf.
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published estimates of damage costs
from greenhouse gas emissions, costs for
controlling or avoiding their emissions,
and costs of sequestering emissions that
do occur, the three major sources for
developing estimates of economic
benefits from reducing emissions of
greenhouse gases.136 Moreover, as stated
above, commenters did not reliably
demonstrate that the unmonetized
benefits, which include CO2, and costs,
taken together, would alter the agency’s
assessment of the level of the standard
for MY 2011. Thus, the agency
determined the stringency of that
standard on the basis of monetized net
benefits.
Additionally, costs for remediating
gasoline spills are highly variable
depending on the volume of fuel
released, the environmental sensitivity
of the immediate environment, and the
presence of specific fuel additives. As a
consequence, the agency has elected to
include no monetary value for reducing
greenhouse gas emissions or
remediating fuel spills among the
benefits of reducing gasoline use via
more stringent fuel economy regulation.
K. Increased Driving Range and Vehicle
Miles Traveled
General Motors argued that the value
of time spent refueling should be zero.
General Motors stated that during the
fuel economy test EPA requires fuel
tanks to contain a fixed percentage of
gasoline compared to tank capacity and
that manufacturers have reduced
gasoline tank volume on average in
response to higher fuel efficiency.
Sierra Research added that range is a
design criterion and that there is no
basis for assuming that this criterion
will change in response to an increase
in CAFE standards. Sierra Research
provided illustrations purported to
show the relationship between fuel
capacity and fuel economy standards,
and fuel economy and range for 2004
light trucks, in order to demonstrate that
increased fuel economy standards might
not result in increased vehicle range.
The following reflects our
understanding of vehicle driving range
and tank size. Typically, the tank size
for a model is determined when the
model is designed, and the tank size
does not change for small incremental
improvements in fuel economy (as
would occur by virtue of these
136 Environmental Defense submitted studies
regarding the valuation of greenhouse gases.
However, the studies were submitted over three
months after the close of the comment period and
less than one month before the agency’s statutory
deadline for issuing a MY 2008 standard. These
studies have been docketed (NHTSA–2005–2223–
2250, 2251).
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standards) until the vehicle is
redesigned. Thus, until redesign,
increased fuel economy would result in
increased driving range, and the value
of time for reduced refueling is real. If
tank downsizing does occur, then there
is a cost savings to manufacturers which
could be subtracted from technology
costs. One way or another, there is a
benefit. Thus, the agency is retaining its
benefit estimates for increased driving
range.
General Motors questioned whether
NHTSA’s estimate of the average
vehicle’s lifetime mileage (152,032
miles) was overstated. NADA also
cautioned that the agency’s fuel
conservation predictions should reflect
an appropriate range of fuel price and
vehicle-miles-traveled assumptions.
In response to the comments by
General Motors and NADA, the agency
notes that the lifetime mileage estimate
reported in the NPRM does not apply to
the average vehicle; instead, it
represents the average accumulated
mileage of a vehicle that survives for a
full 36 years. As the accompanying
vehicle survival rates indicate, only a
small fraction of vehicles originally
produced in any model year are
expected to survive to this age. The
agency has recently updated its
estimates of survival probabilities and
average annual mileage by vehicle age,
and these updated estimates are utilized
to calculate the impacts of CAFE
standards reported in the FRIA
accompanying this final rule.137
Further, as discussed below in Section
XII. Comparison of the final and
proposed rule, the agency has adjusted
the vehicle miles traveled schedule to
reflect increases in the fuel price
forecasts.
L. Added costs from congestion, crashes
and noise
General Motors agreed with the
agency’s cost estimates related to traffic
congestion, crashes, and noise.
However, the commenter again stated its
belief that the proposed CAFE standards
would result in a net externality cost—
not benefit—in terms of consumer
welfare. Specifically, General Motors
stated that the costs associated with
increased congestion, noise, and
highway fatalities and injury costs
resulting from increases in driving
outweigh the benefits associated with
137 The data sources and procedures used to
develop these updated estimates of vehicle survival
and usage are reported in NHTSA, ‘‘Vehicle
Survivability and Travel Mileage Schedules,’’
Report DOT HS 809 952, National Center for
Statistics and Analysis, January 2006, Docket
NHTSA–2005–22223–2218. See FRIA p. VIII–11.
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decreased oil import dependence and
pollution reduction.
NHTSA agrees that this is a true
observation made by General Motors on
the agency’s analysis, although we
believe the commenter overstates its
significance. We say this because the
savings in lifetime fuel expenditures
significantly outweigh the combined net
externalities costs and the costs of
added technology, making this a costbeneficial rule.
M. Employment Impacts
The California State Energy
Commission commented that the agency
mentioned the potential for the CAFE
proposal to result in job losses, but it
did not discuss the issue of employment
in detail. The Commission stated that
increasing CAFE stringency may
actually increase employment among
automobile manufacturers and related
sectors, although union employment
and employment in the petroleum
manufacturing industry might decline.
Without going into detail, the
commenter stated that several previous
studies have concluded that increasing
CAFE standards could increase U.S.
employment and economic output. The
Commission also suggested that by
requiring U.S. automakers to produce
more fuel-efficient vehicles, stricter
CAFE standards could enhance the
competitive positions of those
manufacturers in international markets
where fuel prices are typically higher,
thereby increasing total sales,
production volumes, and domestic
employment. The Commission asked
the agency to address the issue of the
employment impacts of its CAFE
standards more explicitly in the final
rule.
The Marine Retailers Association of
America (MRAA) expressed concern
that increases in CAFE levels could lead
to vehicle downsizing, which in turn
could have a negative impact upon the
boating industry. According to the
MRAA, there are approximately 17
million recreational boats in the U.S.,
about 80 percent of which are pulled by
a light truck or SUV. MRAA stated that
to the extent vehicle downsizing occurs,
manufacturers may find it more difficult
to produce a vehicle with adequate
horsepower and torque to tow a boat,
and without an adequate vehicle to tow
a boat, many consumers may simply
decide not to purchase a boat.
Accordingly, the MRAA asked NHTSA
to carefully consider the employment,
sales, and other impacts of its CAFE
proposal upon the boating industry.
The agency believes that the CAFE
impact on jobs is fairly minor and there
are counterbalancing impacts. The
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agency estimates that higher prices will
result in a small loss of sales, which
negatively impacts employment. On the
other hand, in a few limited cases, the
requirements could result in the use of
additional new technology, which
would increase employment. Both of
these impacts on jobs are anticipated to
be very minor, and the counterbalancing
impacts will be near zero. Very few light
trucks are exported for sale and we
believe that the proposed increases in
fuel economy are unlikely to change
these sales volumes appreciably. Thus,
we expect that there is little chance of
improving the competitive position of
the manufacturers in international
markets as a result of revised light truck
CAFE standards.
The agency has not included changes
in vehicle performance as part of its
strategy for the manufacturers to
improve fuel economy and changes in
weight were not accompanied by
changes in horsepower. Thus, our
assumptions include no changes that
would affect the boating industry.
However, our assumptions do not
require a manufacturer to follow our
predicted course of action.
IX. MY 2008–2010 Transition Period
As stated above, the agency is
providing a transition period during
MYs 2008–2010. During this period,
manufacturers have the option of
complying under the standard
established under the Unreformed CAFE
system or the standard established
under the Reformed CAFE system.
A. Choosing the Reformed or
Unreformed CAFE System
As part of the transition to a fully
phased-in Reform CAFE system in MY
2011, during MYs 2008–2010,
manufacturers have the option of
complying under the Reformed CAFE
system or the Unreformed CAFE system.
Manufacturers are required to announce
their selection for a model year, and that
selection will be irrevocable for that
MY. However, a manufacturer is
permitted to select the alternate
compliance option in the following MY.
Beginning MY 2011, a manufacturer
must comply only under the Reformed
CAFE system.
In the NPRM, we proposed that a
manufacturer would announce its
selection as part of its mid-model year
report, as filed according to 49 CFR
537.7. In order to provide manufacturers
a greater level of flexibility, the final
rule does not require a manufacturer to
elect one of the two compliance options
until the end of the model year. This
will permit a manufacturer to determine
its actual fuel economy before
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17639
determining whether to elect
compliance under the Unreformed or
Reformed CAFE system. Within 45 days
following the end of the model year, a
manufacturer must submit to the agency
a report indicating whether it has
elected to comply with the Reformed or
Unreformed CAFE program for that
model year.
B. Application of Credits Between
Compliance Options
The EPCA credit provisions operate
under the Reformed CAFE system in the
same manner as they do under the
Unreformed CAFE system. The
harmonic averages used to determine
compliance under the Reformed CAFE
system permit the amount, if any, of the
credits earned to be calculated as under
the Unreformed CAFE system:
Credits = (Actual CAFE¥Required
CAFE) * 10 * Total Production Credits
earned in a model year can be carried
backward or forward as currently done
in the Unreformed CAFE system.
Further, credits are transferable
between the two systems. Both
Unreformed CAFE and Reformed CAFE
use harmonic averaging to determine
fuel economy performance of a
manufacturer’s fleet. Under Reformed
CAFE, fuel savings from under- and
over-performance with each category are
generated and applied almost
identically to the way in which this
occurs under the Unreformed CAFE
system. As a result, the two systems
generate credits with equal fuel savings
value. Therefore, credits earned in a
model year under Unreformed CAFE are
fully transferable forward to a model
year under the Reformed CAFE system,
up to the statutory limit of three years.
Likewise, credits under Reformed CAFE
can be carried back to Unreformed
CAFE.
X. Impact of Other Federal Motor
Vehicle Standards
A. Federal Motor Vehicle Safety
Standards
The EPCA specifically directs us to
consider the impact of other Federal
vehicle standards on fuel economy. This
statutory factor constitutes an express
recognition that fuel economy standards
should not be set without due
consideration given to the effects of
efforts to address other regulatory
concerns, such as motor vehicle safety
and emissions. The primary influence of
many of these regulations is the
addition of weight to the vehicle, with
the commensurate reduction in fuel
economy.
Several manufacturers commented on
the evaluation of Federal motor vehicle
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standards, generally stating that the
agency’s estimated weight impacts were
too low. Our response to these
comments and a summary of our
evaluation are provided below. A
detailed discussion of the evaluation is
provided for in the FRIA (see FRIA
p. IV–2).
The agency has evaluated the impact
of the Federal motor vehicle safety
standards (FMVSS) using MY 2007
vehicles as a baseline. We have issued
or proposed to issue a number of
FMVSSs that become effective between
the MY 2007 baseline and MY 2011.
These have been analyzed for their
potential impact on light truck fuel
economy weights for MYs 2008–2011:
The fuel economy impact, if any, of
these new requirements will take the
form of increased vehicle weight
resulting from the design changes
needed to meet new FMVSSs.
The average test weights (curb weight
plus 300 pounds) of the light truck fleet
for General Motors, Ford, and
DaimlerChrysler in MY 2008, MY 2009,
MY 2010 and MY 2011 are 4,744, 4,800,
4,792, and 4,786,138 respectively. Thus,
overall, the three largest manufacturers
of light trucks expect weight to remain
almost unchanged during the time
period addressed by this rulemaking.
The changes in weight include all
factors, such as changes in the fleet mix
of vehicles, required safety
improvements, voluntary safety
improvements, and other changes for
marketing purposes. These changes in
weight over the three model years
would have a negligible impact on fuel
economy.
1. FMVSS 138, Tire Pressure Monitoring
System
As required by the Transportation
Recall Enhancement, Accountability,
and Documentation (TREAD) Act,
NHTSA is requiring a Tire Pressure
Monitoring System (TPMS) be installed
in all passenger cars, multipurpose
passenger vehicles, trucks and buses
that have a Gross Vehicle Weight Rating
of 10,000 pounds or less. The effective
dates are based on the following phasein schedule:
20 percent of light vehicles produced
between September 1, 2005 and
August 31, 2006,
70 percent of light vehicles produced
between September 1, 2006 and
August 31, 2007,
All light vehicles produced after
September 1, 2007 are required to
comply.
138 This figure is for the fleet not including
MDPVs for a more accurate comparison to the fleet
numbers for MYs 2008 through 2010. The figure
including MDPVs is 4,832 lbs.
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Thus, for MY 2008, an additional 30
percent of the fleet will be required to
meet the standard as compared to MY
2007. We estimate from a cost teardown
study that the added weight for an
indirect system is about 0.156 lbs. and
for a direct system is 0.275 to 0.425 lbs.
Initially, direct systems will be more
prevalent, thus, the increased weight is
estimated to be average 0.35 lbs. (0.16
kilograms). Beginning in MY 2008, the
weight increase from FMVSS No. 138 is
anticipated to be 0.11 pounds (0.05
kilograms).
As stated in the TPMS final rule,139
by promoting proper tire inflation, the
installation of TPMS will result in better
fuel economy for vehicle owners that
previously had operated their vehicles
with under-inflated tires. However, this
will not impact a manufacturer’s
compliance under the CAFE program.
Under the CAFE program, a vehicle’s
fuel economy is calculated with the
vehicle’s tires at proper inflation.
Therefore, the fuel economy benefits of
TPMS have not been considered in this
rulemaking.
2. FMVSS 202, Head Restraints
The final rule requires an increase in
the height of front seat outboard head
restraints in pickups, vans, and utility
vehicles, effective September 1, 2008
(MY 2009). If the vehicle has a rear seat
head restraint, it is required to be at
least a certain height.140 The initial head
restraint requirement, established in
1969, resulted in the average front seat
head restraints being 3 inches taller than
pre-standard head restraints and adding
5.63 pounds 141 to the weight of a
passenger car. With the new final rule,
we estimate the increase in height for
the front seats to be 1.3 inches and for
the rear seat to be 0.26 inch, for a
combined average of 1.56 inches.142
Based on the relationship of pounds to
inches from current head restraints, we
estimate the average weight gain across
light trucks would be 2.9 pounds (1.3
kilograms).
139 70 FR 18136, 18139; April 8, 2005; Docket No.
2005–28506.
140 The compliance date for the upgraded
requirements applicable to head restraints
voluntarily installed at rear outboard seating
positions recently was amended from September 1,
2008, to September 1, 2010 (see, 71 FR 12415;
March 9, 2006).
141 Tarbet, Marcia J., ‘‘Cost and Weight Added by
Federal Motor Vehicle Safety Standards for Model
Years 1968–2001 in Passenger Cars and Light
Trucks’’, NHTSA, December 2004, DOT–HS–809–
834. Pg. 51. (https://www.nhtsa.dot.gov/cars/rules/
regrev/evaluate/809834.html).
142 ‘‘Final Regulatory Impact Analysis, FMVSS
No. 202 Head Restraints for Passenger Vehicles’’,
NHTSA, November 2004, Docket No. 19807–1,
p. 74.
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3. FMVSS 208, Occupant Crash
Protection (Rear Center Seat Lap/
Shoulder Belts)
This final rule requires a lap/shoulder
belt in the center rear seat of light
trucks. There are an estimated
5,061,079 143 seating positions in light
trucks needing a shoulder belt, where
they currently have a lap belt. This
estimate of seating positions is a
combination of light trucks, SUVs,
minivans and 15 passenger vans that
have either no rear seat, or one to four
rear seats that need shoulder belts. This
estimate was based on sales of 7,521,302
light trucks in MY 2000. Thus, the
average light truck needs 0.67 shoulder
belts. The average weight of a rear seat
lap belt is 0.92 lbs. and the average
weight of a manual lap/shoulder belt
with retractor is 3.56 lbs.144 Thus, the
anticipated weight gain is 2.64 pounds
per shoulder belt. We estimate the
average weight gain per light truck for
the shoulder belt would be 1.8 pounds
(0.8 kilograms).
A second, potentially more important,
weight increase depends upon how the
center seat lap/shoulder belt is
anchored. The agency has allowed a
detachable shoulder belt in this seating
position, which could be anchored to
the ceiling or other position, without a
large increase in weight. If the center
seat lap/shoulder belt were anchored to
the seat itself, typically the seat would
need to be strengthened to handle this
load. If the manufacturer decides to
change all of the seats to integral seats,
having all three seating positions
anchored through the seat, then both the
seat and flooring needs to be
strengthened. The agency requested
information about manufacturer plans
for complying with this requirement
and after reviewing the confidential
submissions, NHTSA estimates that the
average weight gain per light truck for
the shoulder belt would be 0.36 lbs
(0.16 kg) compared to MY 2007. For the
anchorage, the average weight increase
would be 0.2 lbs (0.09 kg) or more.
The effective dates are based on the
following phase-in schedule:
50 percent of light vehicles produced
between September 1, 2005 and
August 31, 2006,
80 percent of light vehicles produced
between September 1, 2006 and
August 31, 2007,
100 percent of light vehicles produced
after September 1, 2007.
143 ‘‘Final Economic Assessment and Regulatory
Flexibility Analysis, Cost and Benefits of Putting a
Shoulder Belt in the Center Seats of Passenger Cars
and Light Trucks’’, NHTSA, June 2004, Docket No.
18726–2, p. 33.
144 Tarbet 2004, p. 84.
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Thus, for MY 2008, an additional 20
percent of the fleet will be required to
meet the standard. We estimate the
average weight gain per light truck for
the shoulder belt would be 0.36 lbs
(0.16 kg) [1.8 pounds (0.8 kilograms) *
0.2] compared to MY 2007. For the
anchorage, the average weight increase
would be 0.2 pounds (0.09 kg) or more.
4. FMVSS 208, Occupant Crash
Protection (35 mph Frontal Impact
Testing)
The advanced air bag rule requires 35
mph belted testing with the 50th
percentile male dummy with a phase-in
schedule of:
35 percent of light vehicles produced
between September 1, 2007 and August
31, 2008,
65 percent of light vehicles produced
between September 1, 2008 and August
31, 2009,
100 percent of light vehicles produced
after September 1, 2009.145
The impacts of this requirement were
not considered in the evaluation for the
NPRM. Evaluation of the 35 mph belted
test has been added in response to
comment from General Motors that
raised the issue. About 85 percent of the
fleet already meets the test based on
NCAP results. It is assumed that
pretensioners and load limiters would
be the countermeasures used to pass the
test. The estimated combined weight of
these features is 2.4 pounds for the two
front outboard seats. Thus, the average
incremental weight would be 0.36 lbs
(0.16 kg).
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5. FMVSS 301, Fuel System Integrity
This final rule amends the testing
standards for rear end crashes and
resulting fuel leaks. Many vehicles
already pass the more stringent
standards, and those affected are not
likely to be pick-up trucks or vans. It is
estimated that weight added will be
only lightweight items such as a flexible
filler neck. We estimate the average
weight gain across this vehicle class
would be 0.24 lbs (0.11 kg).
The effective dates are based on the
following phase-in schedule:
40 percent of light vehicles produced
between September 1, 2006 and August
31, 2007,
70 percent of light vehicles produced
between September 1, 2007 and August
31, 2008,
100 percent of light vehicles produced
after September 1, 2008 are required to
comply.
145 The standard will be fully effective on
September 1, 2010 when it includes small
manufacturers, multi-stage manufacturers and
alterers.
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Thus, 60 percent of the fleet must
meet FMVSS 301 during the MY 2008–
2010 time period. Thus, the average
weight gain during this period would be
0.14 lbs (0.07 kg).
B. Potential Future Safety Standards
and Voluntary Safety Improvements
There are several safety standards that
have recently been proposed, or that the
agency is required by Congress to
propose in the near future that could
impact some of the MY 2008–2011
vehicles. In most cases, these proposals
or future proposals are already being
met voluntarily by a part of the fleet.
Additionally, the agency has
historically considered the impact of
voluntary safety improvements. The
agency has expressed concern that
overly stringent CAFE standards might
discourage manufacturers from pursuing
voluntary improvements (53 FR 39275,
39296; October 6, 1988). Currently,
there are improvements that are being
made voluntarily to meet market
demand and/or to perform better on
government or insurance industry tests
involving vehicle ratings. In our
analysis for this final rule, the potential
future safety standards and voluntary
improvements have been combined
without regard to effective date, even
though the final effective dates for the
potential future safety standards may be
later than MY 2011.
1. Anti-Lock Brakes and Electronic
Stability Control (ESC)
Many manufacturers are planning to
install ESC on all their light vehicles.
Recent congressional legislation
contained in section 10301 of the Safe,
Accountable, Flexible, Efficient
Transportation Equity Act: A Legacy for
Users of 2005 (SAFETEA–LU)146
requires the Secretary of Transportation
to ‘‘establish performance criteria to
reduce the occurrence of rollovers
consistent with stability enhancing
technologies’’ and to ‘‘issue a proposed
rule * * * by October 1, 2006, and a
final rule by April 1, 2009.’’ A
requirement by NHTSA in this area
could potentially be effective with MY
2011.
The ESC system needs anti-lock
brakes to work appropriately. Anti-lock
brakes add about 20 pounds to the
weight of a light truck. Currently, about
91 percent of all light trucks have antilock brakes. Thus, if all light trucks
added anti-lock brakes, average light
truck weight would increase by 1.8
pounds. ESC is estimated to add about
9 pounds to a vehicle. In 2005, an
estimated 23 percent of light trucks have
146 Pub.
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ESC. Thus, if all light trucks added ESC,
average light truck weight would
increase by 6.9 pounds. So, the total
weight increase is 8.7 pounds (3.95 kg.).
2. Roof Crush, FMVSS 216
On August 23, 2005, NHTSA
published an NPRM proposing to
upgrade the agency’s safety standard on
roof crush resistance. (70 FR 49223) The
NPRM proposed to extend the standard
to vehicles with a GVWR of 10,000
pounds or less, increase the force
applied to 2.5 times each vehicle’s
unloaded weight, and replace the
current limit on the amount of roof
crush with a requirement to maintain
enough headroom for a mid-size adult
male occupant.
The Alliance, Ford, DaimlerChrysler
and Toyota commented that the agency
should have included the weight impact
of the FMVSS 216 amendments in its
analysis. The agency agrees.
Manufacturers’ estimates of the weight
implications of compliance with the
proposed FMVSS No. 216 ranged from
minimal to tens of pounds.
As estimated at the time of the
FMVSS 216 NPRM, the proposed
upgrade was estimated to increase
average vehicle weight by 6.07 pounds.
The proposed effective date was the first
September 1 occurring three years after
publication of the final rule.
In addition to the comments on the
CAFE NPRM, NHTSA received a
number of comments on the weight
estimates in response to the Roof Crush
NPRM. Other manufacturers
commented on the Roof Crush NPRM
that the agency’s weight estimates were
too low. However, other commenters
indicated that weight estimates were too
high because they said that the agency
did not consider alternative, lighter,
materials that manufacturers could use
to comply with the standard. The
agency is still evaluating all of the
comments to the Roof Crush NPRM and
estimates that, if a final rule were
issued, it would be in 2007. Therefore,
for purposes of this CAFE rule, the
agency is using the estimates made at
the time of the Roof Crush NPRM and
assuming an effective date of September
1, 2010.
3. Side Impact and Ejection Mitigation
Air Bags (Thorax and Head Air Bags)
Many manufacturers are installing
side impact air bags (thorax bags,
combination head/thorax bags, or
window curtains). NHTSA proposed an
oblique pole test as part of FMVSS 214
on May 17, 2004 (69 FR 27990). Based
on current technology, this NPRM
would result in head protection by
either a combination head/thorax side
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air bag or window curtains. SAFETEA–
LU also requires the use of window
curtain air bags for ejection mitigation,
which would result in taller and wider
window curtains that would be tethered
or anchored low to keep occupants in
the vehicle.
Assuming in the future that the
typical system will be thorax bags with
a window curtain, the average weight
increase would be 11.55 pounds (4.77 +
6.78) or 5.25 kg (2.07 + 3.08). In MY
2005, about 31 percent of the fleet had
thorax air bags, 7 percent had
combination air bags and, and 25
percent had window curtains. The
combined average weight for these
systems in MY 2005 was 3.49 pounds
(1.59 kg). Thus, the future increase in
weight for side impact air bags and
window curtains compare to MY 2005
installations is 8.06 pounds (11.55–3.49)
or 3.66 kg (5.25–1.59).
Another area that could result in an
increase in weight is if the
manufacturers include structure to get a
higher score in the IIHS higher side
impact barrier test. Public data is not
available to estimate what voluntary
weight increases have been added or
will be added to get a better score in this
test.
4. Offset Frontal Crash Testing
IIHS has been testing and rating
vehicles using an offset deformable
barrier crash test at 64 km/h. Many
manufacturers have redesigned their
vehicles to do better in these tests and
have increased the weight of their
vehicles. Four light trucks that the
agency has tested, which improved from
a poor rating to a marginal or good
rating in the IIHS testing, increased their
weights, some with other redesigns, as
follows:
TABLE 14.—INCREASES IN WEIGHT TO IMPROVE OFFSET FRONTAL TESTING
Before
SUV ......................
SUV ......................
Pickup ...................
Minivan .................
147 Part
1997
1999
2001
1996
Chevrolet Blazer (4,686 lbs.) ...........................
Mitsubishi Montero Sport (4,646 lbs.) .............
Dodge Ram 1500 (4,930 lbs.) .........................
Toyota Previa (3,810 lbs.) ...............................
2002
2001
2002
1998
Trailblazer (5,181 lbs.) .....................................
Mitsubishi Montero Sport (4,715 lbs.) .............
Dodge Ram 1500 (4,969 lbs.) .........................
Toyota Sienna (3,937 lbs.) ..............................
Increase in
weight
147 495
lbs.
69 lbs.
39 lbs.
127 lbs.
of the explanation for the weight increase between the Blazer and Trailblazer is an increase of approximately 1,070 sq. in. in footprint.
These weight increases have an affect
on the vehicle’s fuel economy. However,
many vehicles have already been
redesigned with this offset frontal test in
mind. Whether increases in weight like
this will continue for other vehicles in
the future is unknown.
C. Cumulative Weight Impacts of the
Safety Standards and Voluntary
Improvements
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After redesign
After making the changes in response
to comments discussed above, NHTSA
estimates that weight additions required
by FMVSS regulations that will be
effective in MYs 2008–2011, compared
to the MY 2007 fleet will increase light
truck weight by an average of 4.07
pounds or more (1.83 kg or more).
Likely weight increases from future
safety standards or voluntary safety
improvements will add 22.83 pounds or
more (10.37 kg or more) compared to
MY 2005 installations.
The Alliance, DaimlerChrysler, Ford,
General Motors and Toyota argued that
the weight additions projected by
NHTSA for FMVSS regulations that will
be effective in MYS 2008–2011 is too
low. NHTSA projected an average of
15.46 pounds (including both FMVSS
requirements and voluntary safety
improvements) and a CAFE impact of
0.04 mpg. Only Ford provided a total
estimate which could be compared to
this number, and their estimate was
significantly higher.
In some instances the manufacturers’
weight estimates are similar to
NHTSA’s, in some instances they are
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less than NHTSA’s, but often they are
more than NHTSA’s. The agency’s
estimates are based on cost and weight
tear down studies of a few vehicles and
cannot possibly cover all the variations
in the manufacturers’ fleets. The
manufacturer’s estimates of the fuel
economy impact of added weight on
mpg have typically been less than
NHTSA’s estimates. NHTSA estimated
that an increase of 3–4 pounds 148
results in a decrease of 0.01 mpg, the
manufacturers’ data show that an
increase of up to 7 pounds results in a
decrease of 0.01 mpg. The combination
of the manufacturers estimating more
safety weight impacts, but that weight
having less impact on miles-per-gallon,
has resulted in similar impacts being
estimated by NHTSA and the
manufacturers. The agency has not
questioned the manufacturers’ estimates
closely because the differences in the
overall fuel economy impact due to
required safety standards as estimated
by Ford, General Motors, and NHTSA is
small. A more detailed discussion of the
impact of safety improvements is
provided in the FRIA (see FRIA p. IV–
2).
D. Federal Motor Vehicle Emissions
Standards
1. Tier 2 Requirements
Pursuant to its authority under the
Clean Air Act, on February 10, 2000, the
Environmental Protection Agency (EPA)
148 In reality, the fuel economy impact depends
on the baseline weight of the vehicle.
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published a final rule establishing new
Federal emission standards for
passenger cars and light trucks (see 65
FR 6698). Known as the ‘‘Tier 2’’
Program, the new emissions standards
in EPA’s final rule cover both light-duty
vehicles (i.e., passenger cars and light
trucks with a GVWR of 6,000 pounds or
less) and medium-duty passenger
vehicles (MDPVs) (i.e., vehicles with
either a curb weight of more than 6,000
pounds or a GVWR of more than 8,500
pounds and which otherwise meet the
EPA definition (as discussed previously
in this notice)).
The ‘‘Tier 2’’ standards are designed
to focus on reducing the emissions most
responsible for the ozone and
particulate matter (PM) impact from
these vehicles (e.g., NOX and nonmethane organic gases (NMOG),
consisting primarily of hydrocarbons
(HC)) and contributing to ambient
volatile organic compounds (VOC). In
addition to establishing new emissions
standards for vehicles, the Tier 2
standards also establish standards for
the sulfur content of gasoline.
For new passenger cars and lighter
light trucks (rated at less than 6,000
pounds GVWR), the Tier 2 standards’
phase-in began in 2004, and the
standards are to be fully phased in by
2007. For MDPVs, the phase-in schedule
under the Tier 2 Program requires that
50 percent of the MDPV fleet must
comply in MY 2008 and that 100
percent comply by MY 2009.
Prior to model year 2008, EPA also
regulates MDPVs under ‘‘Interim-Non-
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Tier 2’’ standards, applicable to MDPVs
in accordance with a phase-in schedule
beginning with MY 2004. The phase-in
schedule requires compliance at the
following levels: 25 percent in 2004, 50
percent in 2005, 75 percent in 2006, and
100 percent in 2007. Thus, beginning in
2008, half of new MDPVs are expected
to comply with Tier 2 and the other half
with ‘‘Interim Non-Tier 2 Standards.’’
(Once the Tier 2 standards for MDPVs
are fully implemented, the Interim-NonTier 2 standards will be eliminated.)
When issuing the Tier 2 standards,
EPA responded to comments regarding
the Tier 2 standard and its impact on
CAFE by indicating that it believed that
the Tier 2 standards would not have an
adverse effect on fuel economy.
In their confidential product plan
submissions, several manufacturers
stated that the Tier 2 requirements have
an effect on fuel economy through
additional weight and design
requirements. However, after careful
consideration, we have concluded that
the impacts of the Tier 2 standards on
fuel economy would not be significant
for the following reasons. First,
manufacturers themselves have
estimated that the resulting reduction in
fuel economy during MYs 2008–2010,
in comparison to MY 2007, would be no
greater than 0.04 mpg. Furthermore,
with the exception of MDPVs, the Tier
2 requirements will be fully
implemented in MY 2007, prior to the
MYs that are the subject of this
rulemaking for CAFE.
2. Onboard Vapor Recovery
On April 6, 1994, EPA published a
final rule controlling vehicle-refueling
emissions through the use of onboard
refueling vapor recovery (ORVR)
vehicle-based systems (see 59 FR
16262). These requirements applied to
light-duty vehicles (cars) beginning in
the 1998 model year, and were phased
in over three model years. The ORVR
requirements also apply to light-duty
trucks with a GVWR of 6,000 pounds or
less beginning in model year 2001,
being phased in over three model years.
For light-duty trucks with a GVWR of
6,001–8,500 lbs, the ORVR requirements
first applied in the 2004 model year and
were phased in over three model years.
The ORVR requirements impose a
weight penalty on vehicles, as they
necessitate the installation of vapor
recovery canisters and associated tubing
and hardware. However, the operation
of the ORVR system results in fuel
vapors being made available to the
engine for combustion while the vehicle
is being operated. As these vapors
provide an additional source of energy
that would otherwise be lost to the
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atmosphere through evaporation, the
ORVR requirements do not have a
negative impact on fuel economy,
despite the associated weight increase.
In its comments, Honda disagreed
with the agency’s assertion that ORVR
systems do not have a negative impact
on fuel economy because the systems
make available for combustion vapors
that would otherwise be lost to the
environment. Honda stated that the
agency’s assertion is correct for ‘‘in-use
fuel economy,’’ but it is not true for the
test procedures used to determine fuel
economy under CAFE, because the fuel
economy test procedures rely on a
carbon balance equation. Honda stated
that the measured fuel economy of a
vehicle under the fuel economy test
procedures is exactly the same, whether
or not the ORVR system makes fuel
vapors available to the engine for
combustion.
NHTSA reiterates that ORVR provides
a slight fuel economy benefit with
respect to in-use fuel economy. NHTSA
acknowledges that Honda’s point is also
correct—that this fuel economy benefit
is not distinguishable in the Federal test
procedure (FTP) or highway test cycle
measurements. However, ORVR is not
expected to have a significant effect on
the fuel economy values measured on
the FTP and highway tests. Further, the
slight on-road fuel economy benefit
realized is not utilized by NHTSA to set
fuel economy standards.
In its rulemaking proceedings for
ORVR, EPA conducted an extensive
analysis on increases in vehicle weight
due to the addition of ORVR hardware
and software. A discussion of the ORVR
weight penalty is contained in EPA’s
‘‘Final Regulatory Impact Analysis:
Refueling Emission Regulations for
Light-Duty Vehicles and Trucks and
Heavy-Duty Vehicles,’’ January 1994;
Chapter 5 Economic Impact, section
5.3.2.1. If mechanical seal ORVR
systems are more widely used in the
future than liquid seal ORVR systems
(which represent approximately 95–98
percent of today’s vehicles), the weight
penalty could increase above that
discussed in EPA’s RIA. However, any
increase in vehicle weight due to more
widespread use of mechanical seal
ORVR systems would be negligible and
not be expected to be a major fuel
economy design consideration.
statute provides that the State of
California may issue such standards
upon obtaining a waiver from the EPA
(CAA section 209(b); 42 U.S.C. 7543(b)).
The State of California has established
several emission requirements under
section 209(b) of CAA as part of its Low
Emission Vehicle (LEV) program.
California initially promulgated these
section 209(b) standards in its LEV I
standards, and it has subsequently
adopted more stringent requirements
under section 209(b) of the CAA in its
LEV II regulations. The relevant LEV II
regulations are being phased in for
passenger cars and light trucks during
the 2004–2007 model years.149
The LEV II amendments restructure
the light-duty truck category so that
trucks with a GVWR rating of 8,500
pounds or less are subject to the same
low-emission vehicle standards as
passenger cars. The LEV II Program also
includes more stringent (than LEV I)
emission standards for passenger car
and light-duty truck LEVs and
establishes standards for ‘‘ultra low
emission vehicles’’ (ULEVs).
The LEV II Program also has
requirements for ‘‘zero emission
vehicles’’ (ZEVs) that apply to passenger
cars and light trucks up to 3,750 lbs.
loaded vehicle weight (LVW), beginning
in MY 2005. Trucks between 3,750 lbs.
LVW and 8,500 lbs. GVWR are phased
in to the ZEV regulation from 2007–
2012. The ZEV requirements begin at 10
percent in 2005 and ramp up to 16
percent for 2018 under different paths.
Compliance with more stringent
emission requirements of the section
209 CAA requirements in the LEV II
program is most often achieved through
more sophisticated combustion
management. The associated
improvements and refinement in engine
controls generally improve fuel
efficiency and have a positive impact on
fuel economy.150 However, such gains
may be diminished because the
advanced technologies required by the
program can affect the impact of other
fuel-economy improvements (primarily
due to increased weight). The agency
has considered this potential impact in
our evaluation of manufacturers’
product plans.
3. California Air Resources Board—
Clean Air Act Section 209 Standards
The Clean Air Act (CAA) generally
prohibits States or any other political
subdivision from adopting any standard
relating to the control of emissions from
new motor vehicles (CAA section
209(a); 42 U.S.C. 7543(a)). However, the
149 As of the end of 2005, ten states have adopted
the LEV II program, including Connecticut, Maine,
Massachusetts, New Jersey, New York, Oregon,
Pennsylvania, Rhode Island, Vermont, and
Washington.
150 Northeast States for Coordinated Air Use
Management, ‘‘White Paper: Comparing the
Emissions Reductions of the LEV II Program to the
Tier 2 Program,’’ October 2003.
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The concerns about energy security
and the effects of energy prices and
supply on national economic well-being
that led to the enactment of EPCA
persist today. The demand for
petroleum is steadily growing in the
U.S. and around the world.
The Energy Information
Administration’s International Energy
Outlook 2005 (IEO2005)151 and Annual
Energy Outlook 2006 (Early Release)
(AEO2006) indicate growing demand for
petroleum in the U.S. and around the
world. U.S. demand for oil is expected
to increase from 21 million barrels per
day in 2004 to 28 million barrels per
day in 2030. In the AEO2006 reference
case, world oil demand increases
through 2030 at a rate of 1.4 percent
annually, from 82 million barrels per
day in 2004 to 118 million barrels per
day in 2030 (AEO2006). Approximately
67 percent of the increase in world
demand is projected to occur in North
America and emerging Asia. Energy use
in the transportation sector is projected
to increase at an annual rate of 1.8
percent through 2025 (AEO2006).
To meet this projected increase in
demand, worldwide productive capacity
would have to increase by more than 36
million barrels per day over current
levels. OPEC producers are expected to
supply 40 percent of the increased
production. In contrast, U.S. crude oil
production is projected to increase from
8.4 million barrels per day in 2004 to
9.62 million in 2015, and then begin
declining, falling to 8.9 million barrels
per day in 2025. By 2025, 60 percent of
the oil consumed in the U.S. would be
imported oil. 152
Energy is an essential input to the
U.S. economy, and having a strong
economy is essential to maintaining and
strengthening our national security.
Secure, reliable, and affordable energy
sources are fundamental to economic
stability and development. Rising
energy demand poses a challenge to
energy security, given increased reliance
on global energy markets. As noted
above, U.S. energy consumption has
increasingly been outstripping U.S.
energy production.
Conserving energy, especially
reducing the nation’s dependence on
petroleum, benefits the U.S. in several
ways. Improving energy efficiency has
benefits for economic growth and the
environment, as well as other benefits,
such as reducing pollution and
improving security of energy supply.
More specifically, reducing total
petroleum use decreases our economy’s
vulnerability to oil price shocks.
Reducing dependence on oil imports
from regions with uncertain conditions
enhances our energy security and can
reduce the flow of oil profits to certain
states now hostile to the U.S. Reducing
the growth rate of oil use will help
relieve pressures on already strained
domestic refinery capacity, decreasing
the likelihood of product price
volatility.
We believe that the continued
development of advanced technology,
such as fuel cell technology, and an
infrastructure to support it, may help in
the long term to achieve reductions in
foreign oil dependence and stability in
the world oil market. The continued
infusion of advanced diesels and hybrid
propulsion vehicles into the U.S. light
truck fleet may also contribute to
reduced dependence on petroleum. In
the shorter term, our Reformed CAFE
final rule will encourage broader use of
fuel saving technologies, resulting in
more fuel-efficient vehicles and greater
overall fuel economy.
We have concluded that the increases
in the light truck CAFE standards that
will result from today’s final rule will
contribute appropriately to energy
151 See https://www.eia.doe.gov/oiaf/ieo/pdf/
0484(2005).pdf.
152 AEO2006, Table A20, International Petroleum
Supply and Disposition Summary.
XI. Need of the Nation To Conserve
Energy
EPCA specifically directs the
Department to balance the technological
and economic challenges related to fuel
economy with the nation’s need to
conserve energy. While EPCA grew out
of the energy crisis of the 1970s, the
United States still faces considerable
energy challenges today. U.S. energy
consumption has been outstripping U.S.
energy production at an increasing rate.
This imbalance, if allowed to continue,
will undermine our economy, our
standard of living, and our national
security. (May 2001 National Energy
Policy (NEP) Overview, p. viii)
As was made clear in the first chapter
of the NEP, efficient energy use and
conservation are important elements of
a comprehensive program to address the
nation’s current energy challenges:
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America’s current energy challenges can be
met with rapidly improving technology,
dedicated leadership, and a comprehensive
approach to our energy needs. Our challenge
is clear—we must use technology to reduce
demand for energy, repair and maintain our
energy infrastructure, and increase energy
supply. Today, the United States remains the
world’s undisputed technological leader: but
recent events have demonstrated that we
have yet to integrate 21st-century technology
into an energy plan that is focused on wise
energy use, production, efficiency, and
conservation.
(Page 1–1)
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conservation and the comprehensive
energy program set forth in the NEP. In
assessing the impact of the standards,
we accounted for the increased vehicle
mileage that accompanies reduced costs
to consumers associated with greater
fuel economy and have concluded that
the final rule will lead to considerable
fuel savings. While increasing fuel
economy without increasing the cost of
fuel will lead to some additional vehicle
travel, the overall impact on fuel
conservation remains decidedly
positive.
We acknowledge that, despite the
CAFE program, the United States’
dependence on foreign oil and
petroleum consumption has increased
in recent years. Nonetheless, data
suggest that past fuel economy increases
have had a major impact on U.S.
petroleum use. The NAS determined
that if the fuel economy of the vehicle
fleet had not improved since the 1970s,
U.S. gasoline consumption and oil
imports would be about 2.8 million
barrels per day higher than they are
today. Increasing fuel economy by 10
percent would produce an estimated 8
percent reduction in fuel consumption.
Increases in the fuel economy of new
vehicles eventually raise the fuel
economy of all vehicles as older cars
and trucks are scrapped.
Our analysis in the EA indicates that
Reformed CAFE standards will result in
an estimated 73 million metric tons of
CO2 over the lifetime of the vehicles (see
EA p. 31). They will further reduce the
intensity of the greenhouse gas
emissions generated by the
transportation sector of the national
economy, consistent with the
President’s overall climate change
policies. However, NHTSA has not
monetized greenhouse gas reduction
benefits in this rule, given the scientific
and economic uncertainties associated
with developing a proper estimation of
avoided costs due to climate change.
XII. Comparison of the Final and
Proposed Standards
The standards established in today’s
final rule are more stringent than those
proposed in the NPRM. Moreover, the
Final Rule subjects MDPVs to the light
truck CAFE program beginning in MY
2011, where as the NPRM did not
include the regulation of these vehicles.
By applying more stringent standards to
a more encompassing definition of light
trucks, the final rule requires higher fuel
efficiency from more vehicles than was
proposed in the NPRM. The fuel savings
estimated to result from the standards
adopted today are 4.4 billion gallons
from the MYs 2008–2010 Unreformed
standards, 4.9 billion gallons from the
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MYs 2008–2010 Reformed standards,
and an additional fuel savings of over
2.8 billion gallons from the MY 2011
Reformed standard.
TABLE 15.—INDUSTRY-WIDE FUEL
ECONOMY LEVELS REQUIRED BY
PROPOSED AND FINAL REFORMED
CAFE STANDARDS
MY
Proposed
2008
2009
2010
2011
22.6
23.1
23.4
23.9
Final
Increase
22.7
23.4
23.7
24.0
+0.1
+0.3
+0.3
+0.1
The total fuel saving estimated to
result from the Reformed CAFE
standards for MYs 2008–2011 is
approximately 7.8 billion gallons.
However, in the NPRM the agency
estimated that the Reformed CAFE
standards as proposed would
potentially save 10.2 billion gallons of
fuel over the lifetimes of light trucks
manufactured during these same model
years. The lower estimated fuel savings
of the final rule despite adopting more
stringent standards can be explained by
a number of factors that affected the
agency’s analysis. These include:
changes in the Volpe model, higher fuel
price forecasts, revisions to the
Reformed CAFE standard, and changes
to manufacturers’ product plans.
Some of these factors increased the
estimated fuel savings for the final rule
compared to the level reported in the
NPRM, while others reduces the rule’s
estimated fuel savings. These factors are
each discussed below.
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A. Changes in the Volpe Model
There were two changes made to the
Volpe model between the analysis
reported in the NPRM and the analysis
conducted for the final rule, a revision
to the maximum lifetime of light trucks
and a revision to how the model applied
technologies. First, the maximum
lifetime of light trucks was extended
from 25 to 36 years, and the fraction of
vehicles originally produced during a
model year that remain in service at
each age was increased to reflect this
longer lifetime. These changes were
made in response to NHTSA’s detailed
analysis of R.L. Polk registration data for
recent model year light trucks. These
changes increase fuel savings resulting
from any increase in CAFE standards
because they increase the number of
miles driven (and the amount of fuel
consumed under the Baseline standard)
during a vehicle’s expected lifetime.
This change increased the total fuel
savings estimated to result from the
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Reformed CAFE standards by 0.2 billion
gallons.
The second change to the Volpe CAFE
model was a revision to the way it
applied technology to achieve increased
fuel economy. The Reformed CAFE
system establishes required fuel
economy levels, in part, by setting fuel
economy targets through a marginal
cost-benefit analysis. As noted above,
this analysis applies technologies until
the marginal cost of the technology
equals the marginal benefits of that
technology. The higher fuel prices
projected by EIA after the NPRM might
be expected to cause the model to apply
a greater amount of fuel saving
technology in the final rule than in the
NPRM, and potentially result in final
standards that are more stringent than
those adopted today. This did not occur,
in part, because of the revised
technology assumptions incorporated in
the Volpe model, as explained below.
The agency revised its technology
assumptions to be more consistent with
the estimates in the NAS report about
the number of years needed to
implement each of the various
technologies and in response to
comments from manufacturers. To
achieve consistency with the NAS
report, we reduced the projected rates of
technology implementation employed
by the model. In their comments,
several manufacturers stated that greater
leadtime than that provided in the
NPRM is needed for the introduction of
technologies across a manufacturer’s
fleet of vehicles and that some
technologies would only be introduced
or added to vehicles in conjunction with
a major vehicle redesign or a vehicle
introduction. Honda stated that it can
take 10 years from the point of initial
introduction of a technology until the
point at which that technology is
employed throughout a manufacturer’s
fleet. Honda and Toyota cite the NAS
report which concluded that application
of existing technologies will ‘‘probably
require 4 to 8 years.’’ Honda further
stated that phase-in rates have a critical
impact on lead time requirements.
Nissan, citing the NAS report, stated
that overly aggressive implementation of
technologies has the potential to
‘‘adversely affect manufacturers, their
suppliers, their employees, and
consumers.’’ These concerns were
echoed by Ford and the Alliance.
In response to these comments, the
agency re-evaluated the ‘‘phase-in’’
assumptions used in the Volpe model.
‘‘Phase-in’’ caps represent the maximum
fraction of a manufacturer’s model line
or fleet to which a technology can be
applied when it is initially introduced.
For example, we assumed that low
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friction lubricants could be fully
implemented in a period of four years,
with equal rates of implementation in
each year. This translates to a ‘‘phasein’’ cap of 25 percent (100 percent
phase-in divided by 4 years).
The agency has decreased the
implementation rate for most
technologies to provide implementation
rates consistent with the NAS estimate
of 4 to 8 years. This resulted in
decreasing phase-in caps, with many
ranging from 25 percent (4 year
introduction) to 17 percent
(approximately 6 years, the midpoint of
the NAS estimate). The agency assumed
shorter implementation rates for
technologies that did not require
changes to the manufacturing line. For
other technologies (e.g., hybrid and
diesel powertrains) we employed phasein caps as low as 3 percent, to reflect the
major redesign efforts and capital
investments required to implement
these technologies. A detailed
comparison of the phase-in caps used in
the NPRM analysis and the final rule
analysis is provided in Appendix B of
this document.
In addition to revisions based on the
NAS report, the agency also made
revisions to the Volpe model in
response to specific manufacturers’
comments. Changes to the Volpe model
include deleting the use of some
technologies for specific manufacturers
and delaying implementation of some
technologies to coincide with product
redesigns/model introduction. The
changes instituted by the agency involve
technology phase-in schedules and
deleting some technologies from
consideration. For the NPRM, the Volpe
analysis excluded additional
application of automatic transmissions
with aggressive shift logic. In
consideration of the extremely limited
planned use of automatically-shifted
manual (i.e., clutch) transmissions
(ASMTs) the revised Volpe analysis also
excludes additional applications of
ASMTs. Although these technologies
may eventually appear on vehicles
during the MY 2011 timeframe, the
agency is aware of technical and
regulatory burdens that likely will be
difficult to overcome during MYs 2008–
2011.
Manufacturers’ updated 2005 product
data showed that they plan to include
some technologies on their MY 2008–11
light trucks that had previously been
utilized in the agency’s NPRM analysis
to increase fuel economy from its
baseline level originally specified in
manufacturers’ 2004 product plans.
Manufacturers claimed that because
they added these technologies after
submitting product plan data to the
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agency in 2004, that the agency was
double counting the effect of these
technologies. The agency disagrees. The
analysis for the NPRM was based on the
product plans submitted in 2004. The
analysis for the final rule is based on the
updated product plans manufacturers
provided the agency in response to the
August 2005 RFC. If a technology was
applied to a vehicle model in the
NPRM, and that same technology was
utilized by manufacturers on the same
vehicle in their updated product plans,
the agency did not apply that
technology to that vehicle in the
analysis it conducted for the final rule.
In other words, the agency did not
project the use of a technology on a
model that a manufacturer stated was
already equipped with that technology.
Manufacturers also provided
information stating that certain
technologies, which the agency had
projected in its NPRM analysis, were
incompatible with their products. In
response, the agency hasn’t projected
the use of certain technologies on
specific products for specific
manufacturers that claimed technology
incompatibility. In almost all cases,
these technologies were classified as
being available for use on other
products, both for the specific
manufacturers that claimed
incompatibility with some products and
for other manufacturers’ products. The
computer model used to implement the
Volpe Analysis, as well as the Stage
analysis, used ‘‘engineering constraints’’
to apply general (i.e., industry-wide)
limits on the application of some
technologies in consideration of
technical issues (as opposed to product
planning or lead time considerations,
which are addressed separately).
Further, the agency constrained the
introduction of two technologies
(aerodynamic drag reduction and
materials substitution) to coincide with
a major vehicle redesign or a vehicle
introduction. Constraining these
technologies to major redesigns is
consistent with manufacturer practice,
given that applying such technologies
requires changes to integral design
components such as paneling. These
constraints are in addition to the
‘‘engineering constraints’’ discussed
above.
Additionally, the agency itself has
removed technologies included in the
NAS report from consideration due to
indications that these technologies will
not be available for implementation nor
are any manufacturers planning to
incorporate these technologies in their
vehicles during the MYs 2008–2011
time frame. For the NPRM, the Volpe
analysis excluded additional
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application of automatic transmissions
with aggressive shift logic. For the final
rule the Volpe analysis also excluded
application of automatically-shifted
manual (i.e., clutch) transmissions in
consideration of its limit planned
application.
The changes to the technology
assumptions relied upon by the Volpe
model reduced the estimated fuel
savings for the final Reformed CAFE
standards, in comparison to the
proposed Reformed CAFE standards, by
1.5 billion gallons of fuel. Considered
together, the changes to the Volpe
model reduced the fuel savings
estimated for the Reformed CAFE
standards, again in comparison with the
proposed standards, by 1.3 billion
gallons of fuel.
B. Higher Fuel Price Forecasts
As stated above, the agency is relying
on the most recent EIA forecasts for fuel
prices for the final rule. In the NPRM,
the agency relied on gasoline prices
ranging from $1.51–1.58 a gallon. In the
final rule, the agency is relying on the
updated fuel price forecast, which
provides a range of gasoline prices of
$1.96–2.39 a gallon. These higher fuel
prices had the effect of raising the
optimized fuel economy targets for MY
2011 under the Reformed CAFE
standard.153 This, in turn, raised the
estimate of fuel savings resulting from
the Reformed standard by 0.7 billion
gallons.
However, as discussed in Chapter
VIII, higher fuel prices increase the permile cost of driving and therefore are
expected to reduce the average number
of miles driven each year by light trucks
(an impact of the ‘‘rebound effect,’’
discussed above). The effect of the
resulting reduction in lifetime use of
MY 2008–11 light trucks is to reduce
fuel savings resulting from the Reformed
CAFE standard by 0.7 billion gallons,
offsetting the gain that occurred due to
higher fuel prices. However, this 0.7
billion gallon reduction results from the
effect of higher fuel prices on usage of
all four model years of light trucks
affected by the Reformed CAFE standard
(2008–11), while the 0.7 billion increase
in fuel savings resulting from higher
fuel prices resulted from higher fuel
economy targets for only MY 2011 light
trucks. The impact of higher standards
for MY 2011 was thus offset by the
153 Because the fuel economy targets for MY
2008–10 are set by equating industry-wide
compliance costs for the Reformed CAFE standard
to those under the Unreformed standard (rather
than by the optimization process used in MY 2011),
higher fuel prices do not affect the targets for those
years.
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combined impact of less driving over
the 4 model years combined.
C. Revisions to the Reformed CAFE
System
The fuel savings estimates for the
Reformed CAFE system reported in the
NPRM and final rule also differ because
the Reformed CAFE system adopted by
the final rule differs in certain details
from the Reformed CAFE system
described in the NPRM. First, the
Reformed CAFE system adopted in the
final rule replaces the footprint category
system for setting fuel economy targets
with a continuous function. While the
continuous function closely follows the
shape of the step function of the
category system, slight differences
reduced the fuel savings estimate for the
Reformed CAFE standard reported in
the NPRM by less than 0.1 billion
gallons.
Second, as stated above, the Reformed
CAFE standards adopted in the final
rule set fuel economy targets for MY
2008–10 that are more stringent than
those proposed in the NPRM. This
occurs because the targets for those
model years are set by equalizing total
industry-wide compliance costs with
those of the Unreformed CAFE
standards. Estimated compliance costs
for the Unreformed standards are higher
in the final rule than in the NPRM
because manufacturers’ updated
product plans already include several of
the lower cost fuel improvement
technologies, and therefore, the analysis
applies technologies with higher costs
in order to achieve the same fuel
economy level under the proposed
Unreformed CAFE system. Setting fuel
economy targets under the Reformed
CAFE system to equal these higher
Unreformed CAFE compliance costs
therefore results in more stringent
targets. This change increased the
estimated fuel savings resulting from the
Reformed standard described in the
NPRM by 1.6 billion gallons.
Finally, the Reformed CAFE system
adopted in the final rule includes
MDPVs beginning in MY 2011, while
the NPRM excluded MDPVs in all
model years. Including MDPVs under
the Reformed standard in MY 2011
increased the estimate of fuel savings by
0.3 billion gallons.
The net effect of changes to the
Reformed CAFE system in the final rule,
as opposed to the Reformed CAFE
system in the NPRM, accounts for 1.8
billion more gallons of fuel saved.
D. Updated Product Plans
The most important factor
contributing to the difference between
the fuel savings estimated for the
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proposed and final rules is changes in
the product plans supplied by the
manufacturers between the NPRM and
final rule. In developing the NPRM, the
agency relied upon manufacturer
product plans provided in response to
the 2003 ANPRM. Following
publication of the RFC in association
with the 2005 NPRM, manufacturers
provided updated product plans. These
updated product plans indicate that in
comparison to their previous plans,
several manufacturers intend to increase
production of smaller vehicles, which
typically have higher fuel economies,
and to utilize more fuel-saving
technologies across their fleets.
Table 16 below illustrates a sampling
of the fuel-economy baselines relied on
in the NPRM and the baselines relied
upon for the final rule.
TABLE 16.—BASELINE FUEL ECONOMIES RELIED UPON IN THE NPRM AND FINAL RULE
MY 2008 (mpg)
MY 2009 (mpg)
MY 2010 (mpg)
Manufacturer
NPRM
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General Motors ....................................................................................................
Ford ......................................................................................................................
DaimlerChrysler ...................................................................................................
Toyota ..................................................................................................................
Honda ...................................................................................................................
Nissan ..................................................................................................................
The changes to product plans reflect
a decrease in the planned production of
larger light trucks, which typically have
lower fuel economy performances. The
product plans indicate that
manufacturers are planningto produce
less of the ladder-frame type of SUVs
and more unibody crossover vehicles,
which typically have higher fuel
economy. This shift in the mix of
vehicle sizes results in a higher overall
average CAFE requirement for the entire
vehicle fleet, which increases lifetime
fuel savings for MY 2008–2011 light
trucks by 2.4 billion gallons.
At the same time, many of the
technology improvements that the
agency applied in setting standards for
the NPRM are thus no longer available
to increase fuel economy, because they
are now being utilized to achieve the
higher baseline fuel economy levels
reflected in manufacturers’ revised
product plans. These technologies
include a variety of engine
improvements and upgraded
transmissions, many of which were
applied by the agency to increase
baseline fuel economy to the level of the
standards proposed in the NPRM, and
others that represent changes in
manufacturers’ plans for technology
introduction. Other changes in the
revised product plans include an
increase in the projected number of
hybrid vehicles that manufacturers plan
to produce. Not only do manufacturers
plan to increase their production of
current hybrid models, but they also are
planning to introduce hybrid versions of
both existing and new vehicles. As to be
expected, the additional hybrid vehicles
had a beneficial effect on manufacturers’
baseline CAFE levels.
If the agency’s analysis for the NPRM
applied a technology to improve the fuel
economy of a light truck model but its
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manufacturer’s updated product plan
indicated that it now planned to utilize
the same technology on that model, that
technology was then unavailable to the
agency in its analysis of how
manufacturers could improve fleet fuel
economy to meet the standards
considered in the final rule. While the
effect of that technology is still reflected
in the vehicle’s lower lifetime fuel
consumption, that effect now appears to
result from its manufacturer’s decision
to utilize it even in the absence of any
action by the agency to increase CAFE
standards, rather than from its efforts to
comply with the standard established by
the final rule.
Thus the limited availability of
technologies during the period subject
to this rulemaking, in part, has resulted
in the final standards being set at the
same or similar levels as those initially
proposed. The fuel savings attributable
directly to the rule is the reduction in
fuel consumption from the level that
would occur with a manufacturer’s
planned baseline. Because the level of
the final standards is close to what was
proposed, but the fuel economy levels
represented in manufacturers’ baselines
have generally improved, the amount of
fuel savings directly attributable to the
final standards appears to be less than
that projected in the NPRM.
The increase in baseline fuel economy
of resulting from additional
technologies accounts for a lifetime fuel
savings of 5.3 billion gallons for MY
2008–2011 light trucks, which are no
longer included in the fuel savings
estimated for the Final Rule. Thus the
net effect of revised manufacturer
product plans is to reduce the fuel
savings attributed to the Reformed
CAFE standard in the NPRM by 2.9
billion gallons (5.3 minus 2.4 billion
gallons).
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NPRM
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E. Evaluating the Adopted Reformed
CAFE System
The variety of factors that contributed
to the revised fuel savings estimate for
the Reformed CAFE standard adopted in
the final rule make it difficult to
compare the fuel savings estimate
reported in the final rule with the
estimate reported in the NPRM for the
proposed Reformed CAFE standards.
The combination of changes to
manufacturers’ product plans with
revisions to the Volpe model and its
assumptions account for a decrease in
the agency’s estimate of fuel savings that
will result from the Reformed CAFE
standards from the 10.2 billion gallons
reported in the NPRM to 7.8 billion
gallons in this rule. Had these changes
not been made, the adopted Reformed
CAFE standards would likely have
saved significantly more fuel than the
10.2 billion gallons reported in the
NPRM.
In a broader sense, the fuel efficiency
of the light truck fleets that will be
produced in MYs 2008–2011 will be
significantly higher than that of the
fleets that were originally planned when
manufacturers submitted their initial
product plans to NHTSA in 2004. This
improvement in fuel efficiency reflects
manufacturers’ response to the higher
fuel prices through fuel economy
improvements to their fleets and a shift
towards smaller vehicles, as well as the
improvements in fuel economy required
by the CAFE standards adopted in this
rule. Because current and forecasted
gasoline prices have risen dramatically
since manufacturers submitted their
initial plans, consumer preferences have
shifted away from the largest models
toward more modestly-sized and fuel
efficient light trucks. Some of the fuel
savings previously attributed to the
proposed CAFE standards now appear
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to result from manufacturers’ responses
to changed market conditions.
In addition, the Reformed CAFE
proposal announced in the NPRM put
manufacturers on notice that fuel
efficiency standards for light trucks
would increase, and that future
standards would challenge
manufacturers to improve fuel
efficiency for all light truck models,
regardless of their size. The revised
product plans that manufacturers
submitted in response to the NPRM
responded to these factors, and the
changes to model assumptions
discussed above, in conjunction with
the more stringent Reformed CAFE
standards adopted by the final rule, will
significantly improve the fuel efficiency
of light trucks produced in MY 2008–
2011. The revised product plans that
manufacturers submitted following
publication of the NPRM responded to
these changed conditions, and together
with the more stringent standards
adopted by this rule, the more fuel
efficient vehicles that will be produced
in MYs 2008–2011 will consume
approximately 11 billion fewer gallons
of fuel over their lifetimes than they
would have based on the manufacturers’
initial product plans.
A more meaningful comparison can
be made between the fuel savings
estimates for the adopted Reformed
CAFE standard and the NPRM Reformed
CAFE standard when both are
calculated using the modeling
assumptions and manufacturer product
plan data that were used in the analysis
conducted for the Final Rule. We reestimated fuel savings for the NPRM
Reformed CAFE standards using the
revised Final Rule modeling
assumptions and product plans, and
found that the Reformed standard
presented in the NPRM would save 5.5
billion gallons under these revised
assumptions. This contrasts with the
previously-reported fuel savings
estimate of 7.8 billion gallons for the
adopted Reformed CAFE standard. Thus
increasing the stringency of the final
rule and including MDPVs in 2011
together increased lifetime fuel savings
projected to result from the rule by 2.3
billion gallons (equal to 7.8 billion
minus 5.5 billion gallons).
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XIII. Applicability of the CAFE
Standards
A. Inclusion of MDPVs in MY 2011
The agency is extending the
applicability of the light truck CAFE
program to include vehicles defined by
the EPA as ‘‘medium duty passenger
vehicles’’ (MDPVs) beginning in MY
2011. As explained below, the agency
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finds that standards for these vehicles
are feasible, and that these vehicles are
used for substantially the same purpose
as vehicles rated at not more than 6,000
lbs. GVWR. Further, the inclusion of
these vehicles in MY 2011 will result in
a savings of 251 million gallons of fuel
over the lifetime of those vehicles. The
regulation of these vehicles under the
CAFE program will begin with the 2011
MY.
In the NPRM, the agency requested
comment on extending the applicability
of the CAFE program to include MDPVs.
The EPA defines ‘‘MDPV’’as a ‘‘heavy
duty vehicle’’ 154 with a GVWR less than
10,000 lbs. that is designed primarily for
the transportation of persons. The
MDPV definition excludes any vehicle
which:
(1) Is an ‘‘incomplete truck’’ as defined in
this subpart; or
(2) Has a seating capacity of more than 12
persons; or
(3) Is designed for more than 9 persons in
seating rearward of the driver’s seat; or
(4) Is equipped with an open cargo area (for
example, a pick-up truck box or bed) of 72.0
inches in interior length or more. A covered
box not readily accessible from the passenger
compartment will be considered an open
cargo area for purposes of this definition.155
The agency is incorporating the EPA
MDPV definition into the definition of
‘‘automobile’’ in 49 U.S.C. 523.3, such
that these vehicles will be regulated as
light trucks. The MDPV definition
essentially includes SUVs, short bed
pick-up trucks, and passenger vans,
which are within the specified weight
and weight-rated ranges.
Under EPCA, the agency can regulate
vehicles with a GVWR between 6,000 lb.
and 10,000 lb. under CAFE if we
determine that (1) standards are feasible
for these vehicles, and (2) either that
these vehicles are used for the same
purpose as vehicles rated at not more
than 6,000 lbs. GVWR, or that their
regulation will result in significant
energy conservation.
In the NPRM, the agency discussed its
preliminary analysis of the feasibility of
including MDPVs and the impact of
their inclusion on the fuel savings of the
CAFE standards. The agency expressed
its belief that fuel economy technologies
applicable to vehicles with a GVWR
below 8,500 lbs. might be applicable to
MDPVs, e.g., low-friction lubricants, 6speed transmissions and cylinder
deactivation. In addition, since MDPVs
are already required by EPA to undergo
154 The EPA defines ‘‘heavy duty vehicle’’ as a
motor vehicle that is rated at more than 8,500 lbs.
GVWR; or that has a vehicle curb weight of more
than 6,000 lbs.; or that has a basic vehicle frontal
area in excess of 45 square feet.
155 40 CFR 86.1803–01.
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a portion of the testing necessary to
determine fuel economy performance
under the CAFE program (See 40 CFR
Part 600 Subpart F), the agency
expressed its belief that meeting the
additional testing requirements would
not be unreasonably burdensome.
Moreover, the agency’s preliminary
estimate was that inclusion of MDPVs in
the MY 2011 Reformed CAFE standard
could save additional fuel. The agency
stated that we were not considering
inclusion of the heavier rated vehicles
in MYs 2008–2010, as our estimates
indicated that their inclusion would
lead to a loss in overall fuel savings. The
agency sought comment on whether
MDPVs should be included in the final
rule for MY 2011.
Commenters were divided as to
whether MDPVs should be included in
the CAFE definition of light trucks.
Although the NPRM requested comment
on the inclusion of MDPVs, most
responses addressed all vehicles up to
10,000 lbs. GVWR. Manufacturers and
their trade associations were opposed to
including these heavier vehicles in the
CAFE program, stating that subjecting
these vehicles to CAFE standards was
not feasible and that these vehicles are
used for substantially different purposes
than vehicles with a GVWR under 6,000
lbs. Environmental organizations,
States, and state organizations
supported the inclusion of these
vehicles, stating that including these
vehicles is feasible, will result in
significant fuel savings, and is
appropriate as the primary use of most
of these vehicles is to transport
passengers. No commenter addressed
the questions concerning alternate ways
to encourage improving fuel economy of
these vehicles.
The Alliance, Ford, Nissan, General
Motors, and the Recreational Vehicle
Industry Association (RVIA) opposed
establishing standards applicable to any
vehicle with a gross vehicle weight
rating (GVWR) greater than 8,500 lbs.
(heavier light trucks). Manufacturers
stated that subjecting such vehicles to
the CAFE program was not feasible and
that these vehicles are used for a
substantively different purpose than
vehicles with a GVWR less than 6,000
lbs. (lighter light trucks). Additionally,
compared to the 120 billion gallons of
fuel used by light trucks per year,
General Motors stated that the estimated
fuel savings cannot be considered
significant. Moreover, the Alliance and
Ford stated that inclusion of these
vehicles would primarily impact only
one manufacturer (a domestic
manufacturer) and therefore would
undercut the agency’s goal of
establishing a more equitable regulatory
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framework. Therefore, these
commenters argued, inclusion of such
vehicles in the CAFE program is
impermissible under EPCA.
The Union of Concerned Scientists,
NRDC, NESCAUM, Environmental
Defense, U.S. PIRG, Sierra Club,
National Environmental Trust, Rocky
Mountain Institute, SUN DAY,
Connecticut Department of
Environmental Protection, AAA,
Representatives Baldwin et al.,
Pennsylvania Department of
Environmental Protection, ACEEE and
STAPPA and ALAPCO supported
expanding the definition of light truck
to include all vehicles with a GVWR
between 8,500 lbs. and 10,000 lbs.
NRDC and Environmental Defense
stated EPCA not only permitted the
expansion of the light truck definition,
but that the statute’s directive to
consider the Nation’s need to conserve
energy mandated an expansion. First,
NRDC stated that many of the
technologies evaluated in the NAS
report could be applied to all vehicles
with a GVWR between 8,500 lbs. and
10,000 lbs. Second, NRDC stated the
fuel savings from including MDPVs
would be significant. However, NRDC
did not provide any discussion as to
why the savings would be considered
significant. Third, NRDC stated that the
EPA and CARB already recognize a
segment of these vehicles as primarily
passenger-carrying vehicles through the
MDPV classification. UCS and
Environmental Defense cited a Polk
survey to support the proposition that
the heavier light trucks are used for
substantially the same purposes as the
lighter light trucks.
Environmental Defense stated that a
separate class could be established for
all vehicles with a GVWR between 8,500
lbs. and 10,000 lbs., so as not to detract
from the fuel savings of the fleet
currently regulated. NESCAUM stated
that by not including all vehicles with
a GVWR less than 10,000 lbs in the
CAFE program, the structure would
maintain an incentive for manufacturers
to ‘‘upweight’’ vehicles in order to
remove vehicles from the standards.
The agency concludes that inclusion
of MDPVs in MYs 2008–2010 would
lower the fleet-wide required fuel
economy level for those years by
approximately 0.3 mpg.156 The net
156 Under the Unreformed CAFE structure,
maximum feasible standards are set with particular
consideration given to the least capable
manufacturer, which has been determined to be
General Motors for this proposed rule. A large
percentage of the MDPVs are produced by General
Motors and, due to their weight, have very low fuel
economy. The inclusion of these vehicles would
lead to greater fuel savings by General Motors, but
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effect of including MDPVs in the MY
2008–2010 Reformed CAFE standards
would be a reduction in overall fuel
savings of almost 1.1 billion gallons.
The agency has determined that
regulation of the MDPV fuel economy
beginning MY 2011 is consistent with
the criteria set forth in EPCA for
expanding the applicability of the light
truck CAFE program. First, regulation of
these vehicles is feasible. Second, in
establishing the MDPV definition, the
EPA determined that these vehicles are
used primarily to transport
passengers,157 a use substantially
similar to vehicles with a GVWR less
than 6,000 lbs. GVWR. Moreover, the
analysis performed for the final rule
indicates that inclusion of MDPVs in the
light truck CAFE program for MY 2011
will lead to a savings of 251 million
gallons of fuel.
In 1977, the agency extended the
definition of ‘‘automobile’’ under CAFE
to include certain light trucks with a
GVWR greater than 6,000 lbs. The
agency stated that for regulation of these
vehicles to be feasible the expanded
definition of ‘‘automobile’’ must be
consistent with that adopted by the EPA
for emissions purposes (42 FR 63184,
63185–6; December 15, 1977). In 1976,
the EPA established maximum curb
weight (6,000 lbs.) and maximum
frontal area (45 ft3) limitations on the
trucks subject to emissions testing. The
agency noted that the EPA concluded
that vehicles that exceed those
limitations are not used for the same
type of service as those with smaller cab
areas and curb weights (42 FR 63186).
Consistent with the EPA regulations we
amended the definition of automobile to
include light trucks with a GVWR up to
and including 8,500 lbs., that have a
curb weight of less than 6,000 lbs. and
a frontal compartment space less than
45 ft2 (49 CFR 523.3). As General Motors
noted in its comments, the agency
linked the feasibility of regulating
vehicles to the existence of EPA
emission test procedures and data.
To generate data necessary to
determine compliance with the fuel
economy requirements, vehicles
representative of manufacturer’s model
lines are subject to city and highway
chassis dynamometer tests (40 CFR Part
less by the other manufacturers. This would occur
because the addition of the low fuel economy
MDPVs in MYs 2008–2010 would depress the level
of General Motors’ CAFE and therefore depress the
level of the Unreformed CAFE standards. Since the
MY 2008–2010 Reformed CAFE standards are set so
as to roughly equalize industry-wide costs with the
MY 2008–2010 Unreformed CAFE standards,
depressing the Unreformed CAFE standards for
MYs 2008–2010 would also depress the Reformed
CAFE standards for those years.
157 65 FR 6698; February 10, 2000.
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600). Vehicles classified as ‘‘light
trucks’’ under the current CAFE
definition are required to undergo this
testing for the EPA emissions
requirements. Because both the fuel
economy and emissions requirements
rely on the same tests, the test burden
to manufacturers is minimized.
Under the EPA’s Tier 2 requirements,
requirements for MDPVs to undergo city
chassis dynamometer emission testing
under Tier 2 are being phased-in
starting in MY 2008 (50 percent) with
all MDPVs subject to the testing in MY
2009 (40 CFR 86.1811–04(j)). The Tier 2
regulation exempts MDPVs from
highway chassis dynamometer testing.
Therefore, MDPVs are not subject under
Tier 2 to the complete set of tests
necessary for the fuel economy
requirements. However, we have
determined that this additional testing
will not be burdensome for the
manufacturers.
The EPA estimates that regulating
MDPVs under the fuel economy
standards would require approximately
50–100 city/highway paired tests at a
cost of $2,000 per pair, plus an
additional $50,000–100,000 per test
vehicle for test preparation (i.e., a coastdown analysis 158 and appropriate
mileage accumulation). Based on these
estimates, the industry-wide compliance
test costs for MDPVs range from $2.1
million to $8.2 million. The EPA noted
that this cost could potentially be
further reduced due to carry-over tests
and the fact that a manufacturer is
permitted to certify up to 20 percent of
its fleet through an analytical process
that does not require vehicle testing.
The Alliance and Ford stated that the
fuel economy of the heavier light trucks
is currently not known; therefore the
agency has no baseline from which to
set standards. As MDPVs are not
currently required to undergo chassis
dynamometer testing, several
manufacturers asserted that the agency
did not have adequate information to
determine a baseline fuel economy for
these vehicles from which potential fuel
savings could be projected. The EPA
and several manufacturers provided the
agency with data that has allowed us to
estimate a fuel economy baseline for
MDPVs. These data predominately
cover MDPVs with gasoline power
trains. NHTSA has developed additional
data for MDPVs, including diesels, by
extrapolating from the performance of
sister vehicles with a GVWR less than
8,500 lbs. Since the data supplied by the
EPA was based on emission testing
158 A coast-down analysis is used to determine a
vehicle’s horsepower for running the chassis
dynamometer tests.
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conducted on ‘‘worst case’’ vehicles,
rather than best sellers as would be
done for fuel economy, the baseline
derived from this data is conservative.
Vehicles with a GVWR greater than
8,500 lbs that are not defined as MDPVs
(e.g., heavier rated long bed pick-up
trucks) are not subject to EPA testing
that provides the data necessary to
determine compliance with the CAFE
program. Inclusion of the heavier-ratednon-MDPVs would increase the test
burden for manufacturers. These
vehicles would be subject to a whole
new testing regime. Moreover, because
these vehicles are not subject to
comparable testing requirements, there
is not sufficient data to estimate a fuel
economy baseline. Without a reliable
baseline, the agency is unable to
determine fuel economy targets that
would result in required fuel economy
levels that are economically practicable
and technologically feasible.
Aside from the ability to obtain test
data and the determination of a
baseline, technologies are available that
can be applied to MDPVs in order to
improve fuel economy performance.
The agency recognizes that not all
technologies that are applied to vehicles
with lighter weight ratings are
applicable to MDPVs. However, we have
identified several technologies that
could be applied, for example, 6-speed
transmissions, multiple valves per
cylinder, variable valve timing, and
cylinder deactivation.
Commenters provided a variety of
survey data on the use of vehicles with
a GVWR greater than 8,500 lbs and less
than 10,000 lbs. The Alliance, General
Motors, Ford, and Nissan stated that the
heavier light trucks are used for
commercial, agricultural and utility
reasons distinct from the uses of
vehicles with a GVWR less than 6,000
lbs. Ford cited recent Ford New Vehicle
Customer Studies (NVCS) that
determined that SUVs in the MDPV
category are used for towing 80 percent
more often than midsize SUVs. In
addition, Ford stated that for the 2004
MY, commercial and fleet users made
up 63 percent of Ford Excursion buyers.
However, Ford did not indicate as to
whether the use of the Excursions in
these fleets was primarily to transport
people, or to perform more ‘‘work-like’’
functions. Ford also stated that full size
vans in the MDPV category are used for
significantly different purposes; of all
the E-Series trucks sold, 84 percent are
purchased for commercial purposes,
and as commercial use of these full size
vans increases, consumer use of these
vehicles as passenger or conversion
vans is decreasing. General Motors
asserted that when considering vehicle
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use, the agency must focus on ‘‘peak’’
use.
The Union of Concerned Scientists
and Environmental Defense cited a Polk
survey to support the proposition that
the heavier light trucks are used for
substantially the same purpose as the
lighter light trucks. According to the
Polk survey, the daily use light trucks,
broken down by percentage, is as
follows: Commuting (53.8 percent),
personal trips (33.6 percent), carrying
passengers (29.6 percent), hauling (4.3
percent), towing (4.0 percent), and offroad use (3.7 percent). Union of
Concerned Scientists stated that the
Polk study found that use patterns of
light, medium, and heavy pickup trucks
are substantially the same overall, with
a few notable exceptions. The Union of
Concerned Scientists and
Environmental Defense stated that this
data demonstrate that vehicles with a
GVWR greater than 8,500 lbs. and less
10,000 lbs are used for substantially
similar purposes.
As stated above, the EPA determined
that MDPVs are used primarily to
transport passengers. In establishing the
definition, the EPA stated:
We are defining medium-duty passenger
vehicles as any complete heavy duty vehicle
less than 10,000 pounds GVWR designed
primarily for the transportation of persons.
(65 FR 6698, 6849; February 10, 2000;
emphasis added).
Additionally, the EPA noted that that
in crafting the definition, it made a
distinction based on bed length,
[B]ecause a vehicle introduced with a
shorter bed would have reduced cargo
capacity and would likely have increased
seating capacity relative to current pick-ups,
making it more likely to be used primarily as
a passenger vehicle. Id.
In establishing the final rule, the EPA
demonstrated an effort to distinguish
vehicles that are used primarily to
transport people from vehicles used for
more ‘‘work-like’’ functions. The
transportation of passengers is a use that
is substantially similar to the use of
vehicles with a GVWR less than 6,000
lbs. As in the 1977 final rule, we are
amending the definition of automobile
consistent with the EPA’s
determination.
The agency also considered Ford’s
comment that inclusion of MDPVs
would result in disparate impacts under
Reform CAFE. Ford specifically stated
that the target for a category containing
MDPVs would have to be lowered to
account for the reduction in the overall
capability of the category fleet.
Therefore, manufacturers that do not
produce MDPVs, but that have other
vehicles in that category, would receive
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a less stringent target. On the other
hand, Environmental Defense stated that
a separate class could be created for
heavier vehicles so as to not reduce the
target for vehicles which are already
regulated.
After considering these comments, the
agency has decided not to regulate
MDPVs as a separate class of light truck.
First, we note that issues regarding the
impact of MDPVs on the largest vehicle
category are no longer applicable. Under
the continuous function, vehicles will
be compared to targets assigned to each
vehicle’s footprint value. Further, as the
agency has stated previously when
deciding whether to establish separate
standards for 2WD and 4WD vehicles,
‘‘the fact that standards must be average
fuel economy standards indicates that
the manufacturers should be given some
opportunity to balance vehicles with
different fuel economies to ensure,
consistent with the need to conserve
energy, that a reasonable variety of
vehicle types can be produced to satisfy
consumer demand.’’ (42 FR 13807,
13811; March 14, 1977)
Since the manufacturers of MDPVs
are all full-line manufacturers, the
agency has decided that on balance it is
advantageous to regulate these vehicles
with all light trucks in order to provide
manufacturers the flexibility of either
improving the fuel economy of these
vehicles, relying on improvements in
other vehicles to offset the fuel economy
of these vehicles, or some combination
of these two strategies.
Finally, we have determined that
inclusion of MDPVs in MY 2011 will
result in an additional fuel savings of
251 million gallons of fuel.
B. ‘‘Flat-Floor’’ Provision
In the NPRM, the agency tentatively
decided to amend the ‘‘flat floor
provision’’ in the light truck definition
(49 CFR 523.5) so that the definition
expressly includes vehicles with seats
that fold and stow in a vehicle’s floor
pan. The agency stated that we
tentatively determined that these seats
are functionally equivalent to removable
seats and minimize safety concerns that
arise from the potential to improperly
re-installed seats. The agency said that
its goal was treating passenger vans and
mini vans in a similar fashion.
In response to commenters, the
agency is amending the flat-floor
provision to accommodate certain
folding seats, but also to restrict the
group of vehicles relying on the flat
floor provision to qualify as a light truck
to those vehicles having at least 3 rows
of designated seating positions as
standard equipment. That is, a vehicle
would qualify only if it had at least 3
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rows of seats, the 2nd and 3rd of which
are capable of creating a flat cargo
surface through either folding or
detachment.
The current regulation classifies as a
light truck any vehicle with readily
removable seats that, once removed,
leave a flat floor level surface. In
pertinent part, the current regulatory
text reads as follows:
Permit expanded use of the automobile for
cargo-carrying purposes or other
nonpassenger-carrying purposes through the
removal of seats by means installed for that
purpose by the manufacturer or with simple
tools, such as screwdrivers and wrenches, so
as to create a flat, floor level, surface
extending from the forwardmost point of
installation of those seats to the rear of the
automobile’s interior.159
This definition is only one of several
classifying light trucks, and historically,
it has operated, as originally intended,
to bring only minivans and full size
passenger vans into the light truck
category. Sport utility vehicles qualify
as light trucks because they have the
indices of off-road capability: a 4-wheel
drive system and certain dimensional
characteristics.160 While the criteria
used for SUVs remain viable, the
definition pertaining to minivans has
become outdated in that it does not
bring all minivans and passenger vans
into the light truck category.
The Alliance, Ford, Nissan, AIAM,
and General Motors stated that the
proposed revision to the flat floor
provision reflects current market
conditions and that the agency properly
acknowledged the risks of improperly
re-installed seats. However, Ford,
Nissan, and General Motors, requested
that the agency clarify the term
‘‘stowing of foldable seats in the vehicle
floor pan’’ to appropriately capture
minivans and exclude passenger
vehicles with seats that have only the
seatback fold (e.g., station wagons).
DaimlerChrysler, Mitsubishi, and
Johnson Controls raised concern that the
proposed amendment would not
capture all minivans, given that the
design of folding seats is not limited to
those that stow under the floor pan.
DaimlerChrysler and Johnson Controls
recommended that the agency adopt a
flat loading surface requirement in
conjunction with a minimum volume
criterion.
As discussed in the NPRM, minivans
traditionally subject to light truck CAFE
standards began offering various seat
designs that are intended to be
functionally similar to removable seats,
while remaining attached at some point
to the vehicle. In the NPRM we
recognized seats that fold and stow in a
vehicle’s floor pan; i.e., flush with the
vehicle’s floor, thereby creating a flat
surface that is dimensionally
indistinguishable from the surface floor
that would exist if the same seats were
removed instead of being stowed.161
There are still other minivans that offer
seats that fold so as to create a different/
new continuous flat cargo surface that is
located above the floor level. The
current definition of light trucks has the
potential of subjecting minivans that
offer stowable seats to passenger vehicle
CAFE standards, while subjecting very
similar minivans featuring removable
seats to light truck standards.
In response to comments, we are
adopting a revision to the flat-floor
provision that recognizes the various
designs that permit seats to fold and
stow. The provision adopted today
replaces the ‘‘flat, floor level surface’’
language with a requirement that
removal or stowing of seats creates a
‘‘flat, leveled surface extending from the
forwardmost point of installation of
those seats to the rear of the
automobile’s interior.’’ This new
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language eliminates the need to define
‘‘floor pan’’ and does not require seat
designs to store in any particular
manner.
Several commenters raised concern
with revising the flat-floor provision.
The Union of Concerned Scientists,
Environmental Defense, and the New
York Department of Environmental
Conservation opposed the proposed
revision, stating that it would widen the
existing light truck ‘‘loophole.’’
Furthermore, the Union of Concerned
Scientists stated that the original
justification for the flat floor provision
no longer applies. The Union of
Concerned Scientists stated that the flat
floor provision was established to reflect
that passenger vans were derived from
cargo vans, but that this is no longer
true. (In the July 28, 1977 rulemaking,
the agency stated that station wagons
should not be classified as light trucks
because, in part, they are built on a car
chassis rather than a truck chassis (see
42 FR 38362, 38367). The Union of
Concerned Scientists stated that while
cargo vans and pickup trucks currently
share the same platform, minivans do
not.
First, the agency continues to
conclude that in general, minivans are
appropriately classified as light trucks.
Minivans offer fuel economy
compromising utility features normally
associated with light trucks.
Specifically, unlike the smaller
passenger cars, all minivans feature
three rows of seats, thus offering greater
passenger carrying capability.162
Further, data from https://
www.Edmunds.com, NHTSA CAFE
Database, and the Automotive News
Data Center indicate that minivans offer
significantly larger cargo carrying
capacity compared to passenger cars
(see Table 17 below).
TABLE 17.—MAXIMUM CARGO CAPACITY OF MINIVANS
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Vehicle
Type
DCX R-class ....................................................................................................
DCX Pacifica ...................................................................................................
DCX Caravan/Town & Country SWB ..............................................................
Honda Odyssey ...............................................................................................
Toyota Sienna .................................................................................................
Ford Freestar/Mercury Monterey .....................................................................
GM Uplander/Terraza/Montana .......................................................................
Nissan Quest ...................................................................................................
Mazda MPV .....................................................................................................
Chevy HHR ......................................................................................................
Audi A4 ............................................................................................................
DCX E-class ....................................................................................................
Saab 9–5 .........................................................................................................
Minivan ...............................................
Minivan ...............................................
Minivan ...............................................
Minivan ...............................................
Minivan ...............................................
Minivan ...............................................
Minivan ...............................................
Minivan ...............................................
Minivan ...............................................
Wagon ................................................
Wagon ................................................
Wagon ................................................
Wagon ................................................
159 See
49 CFR 523.5(a)(5).
Utility Vehicles of different sizes qualify
as light trucks because they are equipped with a 4wheel drive system and because they have higher
160 Sport
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ground clearance and steeper approach and
departure angles.
161 For example, Chrysler Town and Country and
Dodge Caravan feature ‘‘Stow ‘n Go’’ seating.
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Maximum cargo capacity
85 cu. ft.
80 cu. ft.
147 cu. ft.
147 cu. ft.
149 cu. ft.
137 cu. ft.
120 to 137 cu. ft.
149 cu. ft.
127 cu. ft.
56 cu. ft.
59 cu. ft.
69 cu. ft.
73 cu. ft.
162 Only one minivan, the Chrysler Pacifica, does
not offer a third row as standard equipment.
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TABLE 17.—MAXIMUM CARGO CAPACITY OF MINIVANS—Continued
Vehicle
Type
Volvo V70 ........................................................................................................
Volvo V50 ........................................................................................................
Jaguar X-type ..................................................................................................
BMW 530 ix .....................................................................................................
Dodge Magnum ...............................................................................................
Pontiac Vibe/Toyota Matrix .............................................................................
Mazda 3 ...........................................................................................................
Wagon ................................................
Wagon ................................................
Wagon ................................................
Wagon ................................................
Wagon ................................................
5-door hatchback ...............................
5-door hatchback ...............................
Both of these capabilities affect fuel
economy because in order to
accommodate additional seats and
provide greater cargo carrying capacity,
Minivans are made larger and heavier
than passenger cars. The seats
themselves add significant weight to
these vehicles. In addition to fuel
economy compromising utility features,
we previously explained that continued
inclusion of minivans in the light truck
standard is justified, in part, based on
their good performance in crash tests.163
The same cannot be readily said for a
diverse population of station wagons
and hatchbacks that may have flatfolding seats, because some of them are
very small and potentially less safe.
However, the agency recognizes the
risk of expanding the light truck
definition to include vehicles not
intended to be in that class, i.e., station
wagons and hatchbacks. In order to
focus the definition only on those
vehicles that the agency believes should
be included in the light truck category,
we believe it is appropriate to restrict
the group of vehicles relying on the flat
floor provision to qualify as a light truck
to those also having at least 3 rows of
designated seating positions as standard
equipment. That is, a vehicle could
qualify only if it had at least 3 rows of
seats, the 2nd and 3rd of which are
capable of creating a flat cargo surface
through either folding or detachment.
The regulatory text would read as
follows:
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For vehicles equipped with at least 3 rows
of designated seating positions as standard
equipment, permit expanded use of the
automobile for cargo-carrying purposes or
other nonpassenger-carrying purposes
through the removal or stowing of seats so as
to create a flat, leveled surface extending
from the forwardmost point of installation of
those seats to the rear of the automobile’s
interior.
The agency has chosen to adopt the
‘‘third row’’ criterion for four reasons.
First, this definition best advances our
goal of subjecting all minivans to one
CAFE standard, and eliminates an
artificial distinction between minivans
163 See August 2005 NPRM (70 FR 51414 at
51456).
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depending on whether they have folding
seats or removable seats. Second, an
obvious advantage of this approach is
simplicity and objectivity. For example,
this definition would not require
complicated cargo capacity
measurements in order to determine
whether a vehicle is a light truck, as
would be required under
DaimlerChrysler’s suggestion. Third,
compared to geometric criteria, such as
a minimum cargo volume, this approach
is less susceptible to gaming, as it is
unlikely that smaller vehicles that the
agency believes should not be subject to
the light truck standards would be
equipped with 3rd row seats. Finally,
the 3rd row seat criterion ensures that
vehicles classified as light trucks
continue to include those that offer
added utility features contemplated by
Congress when it created a separate
CAFE standard for light trucks.
In addition to furthering our goal of
subjecting all minivans to the CAFE
standard for light trucks, the provision
adopted today limits the number of
vehicles that will be reclassified as light
trucks. After examining https://
www.Edmunds.com, NHTSA CAFE
Database, and the Automotive News
Data Center, we found that only a Volvo
V70 (≤ 10,000 annual sales) has a flatfolding 3rd row seat, and would thus
qualify as a light truck. By contrast,
other alternatives considered by the
agency would not necessarily bring all
minivans under one standard, and could
also have the unintended effect of
reclassifying a more substantial number
of passenger cars as light trucks.
We note that small sport utility
vehicles without 3rd row seats would
nevertheless qualify as light trucks
based on other existing criteria; i.e.,
availability of 4-wheel drive or
approach angles and minimum
clearance. Thus, our approach is
expected to have few unintended
consequences. Nevertheless, some
vehicles previously classified as light
trucks would no longer be subject to the
light truck CAFE standard. One such
vehicle is a Chrysler PT Cruiser, which
qualifies now as a light truck because it
has a removable rear seat which creates
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71
63
50
58
72
54
31
cu.
cu.
cu.
cu.
cu.
cu.
cu.
ft.
ft.
ft.
ft.
ft.
ft.
ft.
a flat floor. However, the PT cruiser
does not have a 3rd row of seats. Also,
one minivan, the Chrysler Pacifica does
not offer a third row as standard
equipment. To provide manufacturers
adequate time to adjust their product
plans to the new provision we are
making the new definition effective
beginning in MY 2012, the change will
not have any immediate impact on MYs
2008–2011 vehicles.
In order to provide additional
flexibility we are permitting
manufacturers to rely on either the old
or the revised definition of light trucks
until MY 2012. This will ensure that a
vehicle previously subject to light truck
CAFE standards would not immediately
become subject to the pasenger car
standard thus upsetting the
manufacturers’ compliance plans. At the
same time, those manufacturers
currently offering minivans with folding
seats would be able to take advantage of
the new definition immediately.
We do not anticipate that the
provision adopted today will result in
manufacturers installing third row
seating for the sole purpose of
compliance with the light truck CAFE
program. Installing third row seats
presents practical difficulties (e.g.,
limited headroom) and costs associated
with making this change in vehicles
with smaller interior volume.
Specifically, we believe the costs of
redesigning small vehicles to feature 3rd
row seats will outweigh potential
benefits of subjecting these vehicles to
the light truck standard. Further, small
vehicles such as hatchbacks, will likely
be compared to fuel economy targets
comparable to that of the passenger car
CAFE standard, thus further reducing
the incentive to make major design
changes for the purpose of classifying
such vehicle as a light truck.
XIV. Additional Issues
A. Limited-Line Manufacturer Standard
Porsche requested that the agency
establish a separate standard for limitedline manufacturers, stating that
manufacturers that produce only one or
two light trucks are not afforded the
flexibility provided through fleet-wide
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averaging. Porsche noted that it
manufacturers only a single model of
light truck that Porsche stated is
designed to ‘‘satisfy a specific consumer
demand.’’ Porsche argued that it would
have even greater difficulty in
complying under the Reformed CAFE
system, as its light truck would fall
within a category that has a target more
stringent than the Unreformed CAFE
standard. Porsche stated that the agency
had authority to establish a limited-line
manufacturer standard, and had
previously done so for ‘‘limited product
line trucks’’ for MYs 1980 and 1981.
When the agency first established the
light truck CAFE program, we
established a separate standard for
limited product line light trucks. This
standard was to accommodate light
trucks manufactured by companies
which did not produce passenger
automobiles and thus did not have
access to passenger automobile engine
and emission control technology (43 FR
11995, 11996; March 23, 1978). The
limited product line light truck standard
was established primarily to address the
unique compliance issues facing
International Harvester, as International
Harvester’s engines were derivatives of
medium duty trucks (above 10,000 lbs
GVWR). We noted that International
Harvester did not have experience with
‘‘state-of-the-art’’ emission controls,
which other manufacturers had
obtained in the passenger car market,
and that International Harvester would
be at a disadvantage attempting to
comply with both the emission and fuel
economy standards then being
established (43 FR 11995, 11998).
While the limited product line light
truck standard was established to
address compliance difficulties of a
limited line light truck manufacturer,
the light truck class was defined, in
part, by vehicle characteristic, i.e., it
applied only to trucks with basic
engines, as that term was defined by the
EPA. The agency discontinued the
limited line truck classification
beginning in MY 1982, stating that the
vehicle class was designated merely to
provide a transition period (45 FR
20871, 20877; March 31, 1980).
The agency does not agree with
Porsche’s suggestion that the company’s
particular circumstances support
establishment of a separate fuel
economy standard for limited-line
manufacturers, or for vehicles of the
type manufactured by limited-line
manufacturers as was previously done
in response to issues faced by
International Harvester. Porsche stated
that it faces a disadvantage because it
makes only a single high performance
truck and has no ‘‘legitimate’’
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opportunity to comply, and that
compliance is made more difficult by
the reforms established today. Although
some manufacturers have chosen to
participate in market segments that
make it easier for them to meet CAFE,
we note that all manufacturers must
meet particular challenges when
complying with a standard.
Porsche is correct in that in the very
first years in which CAFE standards
were in effect, the agency established a
separate light truck standard for light
truck manufacturers who did not use
passenger car engines in their trucks.
This separate standard, promulgated in
1978, offered a degree of relief to
International Harvester, a company
struggling to meet both CAFE and
emissions standards with limited
resources. As indicated above, the
separate standard was not intended to
provide International Harvester permit
relief, but to provide it with additional
time to gain the expertise necessary to
comply with the standards.
NHTSA finds it difficult to equate
Porsche’s present position with that of
International Harvester in 1978. Unlike
International Harvester, which had been
producing a family of larger light trucks
whose basic design remained
unchanged from the early 1960’s,
Porsche began the design process
knowing that CAFE standards would
apply to its product. Porsche
presumably entered the light truck
market after determining that the costs
of compliance or paying penalties were
offset by the benefits of doing so. While
the increase in CAFE standards
established by this final rule will
require that Porsche increase its efforts
to build more fuel efficient light trucks,
the company cannot state that its
designs pre-date CAFE, that an increase
in CAFE standards was not foreseeable
or that it is not technologically feasible
for Porsche to meet the standards.
As indicated above, NHTSA does not
believe that present market conditions
dictate establishing a separate fuel
economy standard for Porsche or other
limited-line manufacturers. We are also
not convinced by Porsche’s argument
that doing so would be consistent with
Congressional intent. Porsche has
correctly noted that the House Report
for EPCA stated that ‘‘the Secretary
could, in setting classes of nonpassenger automobiles, establish
separate classes for types of nonpassenger automobiles manufactured by
small manufacturers.’’ (H.R. Rep. No.
94–340 at 90.) However, we point out
that the report refers to ‘‘types of
vehicles.’’ We question whether
Congress intended for the agency to set
standards based on manufacturer
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17653
characteristics, as opposed to vehicle
characteristics.
When the agency established CAFE
standards for limited product line light
trucks, that class included only vehicles
with a specific engine type. While the
reform established today results in
different required fuel economy
standards for different manufacturers
based on product mix, the standard still
relies on differentiating vehicles based
on a vehicle characteristic, i.e.,
footprint.
B. Credit Trading
Nissan recommended that the agency
implement a credit trading program that
permits manufacturers to buy and sell
credits. Nissan stated that such a
program would allow manufacturers to
earn credits for exceeding their fleetwide fuel economy target, and sell or
trade those credits to other
manufacturers. Nissan believes that
such a program is consistent with the
goals of the EPCA statute and would
improve overall fuel economy by
providing added incentives for the
achievement of greater fuel economy
improvements. Nissan asserted that
such a program also would allow greater
flexibility in CAFE compliance without
causing a negative overall impact on
fuel economy, and in fact, it could
successfully benefit the environment.
Nissan provided an analysis in support
of the agency’s authority to establish
such a credit trading program.
The agency is not adopting a credit
trading program as suggested by Nissan.
While the agency has not explored in
detail a credit trading program, we
question whether the agency has
authority for such a program. A review
of 49 U.S.C. 32903—the specific
provision addressing CAFE credits for
exceeding fuel economy standards—
does not appear to support credit
trading. That section persistently refers
only to ‘‘a manufacturer’’ or ‘‘the
manufacturer,’’ thereby suggesting to us
that Congress intended that only the
particular manufacturer who earned the
credits be permitted to use them. For
example, section 32903(a) provides that
When the average fuel economy of passenger
automobiles manufactured by a manufacturer
. . . exceeds an applicable average fuel
economy standard . . . the manufacturer
earns credits. The credits may be applied
to—(1) any of the 3 consecutive model years
immediately before the model year for which
the credits are earned; and (2) to the extent
not used under clause (1) of this subsection,
any of the 3 consecutive model years
immediately after the model year for which
the credits are earned.
(Emphasis added.) Also, section
32903(d) states that,
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The Secretary of Transportation shall apply
credits to a model year on the basis of the
number of tenths of a mile of gallon by which
the manufacturer involved was below the
applicable average fuel economy standard.
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(Emphasis added.) Moreover, we believe
that the Reformed CAFE program
adopted today provides manufacturers
with sufficient flexibility as to obviate
the need for a credit trading program.
C. Reporting Requirements
Today’s final rule requires
manufacturers to report on a model and
configuration level, a vehicle’s footprint.
This information will be used to
determine a vehicle’s applicable fuel
economy target.
The Alliance opposed reporting
footprint on at a vehicle-configuration
level. The Alliance suggested that
footprint values should be reported by
model on a body style and wheelbase
level along with associated projected
sales volumes. The Alliance stated that
body-style and wheelbase level of detail
could be easily compiled and submitted.
Conversely, for some manufacturers, the
Alliance stated, reporting on a
configuration level would require
programming changes in corporate
databases and reports.
The agency is maintaining the
footprint reporting requirements as
proposed. If reporting were to be
required at the level suggested by the
Alliance, models that are offered with
varying footprint values may not be
captured. For example, the Ford base
F150, is offered with in several versions
with different body styles and
wheelbases. However, these versions are
each offered in with different engine,
transmission, and drive type
configurations. Each of these
configurations may have a different fuel
economy performance. Under the
Alliance’s suggestion, these
configurations would not be captured.
The Alliance also stated that the
agency should eliminate some of data
required for the CAFE reports,
specifically: Catalytic converter, SAE
net rated power in kilowatts, total drive
ratio, axle ratio, frontal area, optional
equipment, number of forward speeds
(already indicated by transmission
class). The Alliance stated that this
information is no longer relevant.
The NPRM did not propose to revise
the data reporting requirements aside
from requiring the footprint related data
and elimination of data currently
required to be reported is outside the
scope of this rulemaking. Moreover,
consideration of such revisions would
require coordination with the EPA to
ensure consistency between the two
agencies’ regulatory programs, given the
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joint responsibilities under EPCA.
However, the agency will work to
evaluate the necessity of the data
currently required to be reported and
will consider potential revisions in
future rulemakings.
D. Preemption
Summary of NHTSA’s position
In mandating federal fuel economy
standards under EPCA, Congress has
expressly preempted any state laws or
regulations relating to fuel economy
standards. A State requirement limiting
CO2 emissions is such a law or
regulation because it has the direct
effect of regulating fuel consumption.
CO2 emissions are directly linked to fuel
consumption because CO2 is the
ultimate end product of burning
gasoline. Moreover, because there is but
one pool of technologies for reducing
tailpipe CO2 emissions and increasing
fuel economy available now and for the
foreseeable future, regulation of CO2
emissions and fuel consumption are
inextricably linked. It is therefore
NHTSA’s conclusion that such
regulation is expressly preempted.
A State requirement limiting CO2
emissions is also impliedly preempted
under EPCA. It would be inconsistent
with the statutory scheme, as
implemented by NHTSA, to allow
another governmental entity to make
inconsistent judgments made about how
quickly and how much of that single
pool of technology can and should be
required to be installed, consistent with
the need to conserve energy,
technological feasibility, economic
practicability, employment, vehicle
safety and other relevant concerns.
NHTSA’s statement in the NPRM about
preemption
In the NPRM, NHTSA reaffirmed its
judgment that State regulation of motor
vehicle tailpipe emissions of CO2 is both
expressly and impliedly preempted by
statute:
We reaffirm our view that a state may not
impose a legal requirement relating to fuel
economy, whether by statute, regulation or
otherwise, that conflicts with this rule. A
state law that seeks to reduce motor vehicle
carbon dioxide emissions is both expressly
and impliedly preempted.
Our statute contains a broad preemption
provision making clear the need for a
uniform, federal system: ‘‘When an average
fuel economy standard prescribed under this
chapter is in effect, a State or a political
subdivision of a State may not adopt or
enforce a law or regulation related to fuel
economy standards or average fuel economy
standards for automobiles covered by an
average fuel economy standard under this
chapter.’’ 49 U.S.C. 32919(a). Since the way
to reduce carbon dioxide emissions is to
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improve fuel economy, a state regulation
seeking to reduce those emissions is a
‘‘regulation related to fuel economy
standards or average fuel economy
standards.’’
Further, such a regulation would be
impliedly preempted, as it would interfere
[with] our implementation of the CAFE
statute. For example, it would interfere the
careful balancing of various statutory factors
and other related considerations, as
contemplated in the conference report on
EPCA, we must do in order to establish
average fuel economy standards at the
maximum feasible level. It would also
interfere with our effort to reform CAFE so
to achieve higher fuel savings, while
reducing the risk of adverse economic and
safety consequences.164
During the comment period on the
NPRM, some commenters questioned
the correctness of NHTSA’s judgment as
well as the appropriateness of
reaffirming it in the NPRM.
The appropriateness of our discussing
preemption in the NPRM
We discussed our views about
preemption in the NPRM for several
reasons. First, the agency was guided by
Executive Order 13132, Federalism, and
by Section 3(b)(1)(B) of Executive Order
12988, Civil Justice Reform. Second, we
were guided by a desire to obtain
comments from State and local officials
and other members of the public in
order to inform fully the agency’s
position on this important issue.
Third, we were also guided by
statements of the Supreme Court, which
has encouraged agencies to consider the
preemptive effects of their rulemakings
during the rulemaking process, rather
than waiting until litigation ensues to
do so.165 Finally, from time to time over
the years, NHTSA has raised the issue
of preemption in its rulemaking notices
when the agency judged it appropriate
to do so, as have other agencies within
the Department of Transportation. E.g.,
54 FR 11765 (March 1989); 58 FR 68274
(December 1993) and 70 FR 21844
(April 2005).
Public Comments About the Merits of
Our Views on Preemption
The motor vehicle manufacturers and
their associations agreed with the
agency’s position regarding federal
preemption under § 32919(a) of EPCA.
Nissan supported that position with a
detailed legal analysis. Conversely,
several of the environmental groups and
164 70
FR 51414, 51457.
e.g., Hillsborough County v. Automated
Medical Laboratories, Inc., 471 U.S. 707, 718 (1985);
Medtronic, Inc., v. Lohr, 518 U.S. 470, 506 (1996)
(Justice Breyer, in concurrence); and Geier v.
American Honda Motor Co., 529 U.S. 861, 908
(2000) (Justice Stevens, in dissent).
165 See,
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States,166 and a number of U.S. Senators
and Representatives, disagreed with the
agency’s position that a State carbon
dioxide (CO2) standard is expressly and
impliedly preempted.
Nissan argued that California’s
proposed CO2 standard is expressly
preempted by EPCA’s broadly worded
preemption provision. A State standard
is preempted even if it does not directly
address fuel economy; it is sufficient if
it simply relates to fuel economy.
That commenter noted that the text of
EPCA’s preemption provision is similar
to that of the preemption provision in
the Employee Retirement Income
Security Act (ERISA). The Supreme
Court has found that a state law is
‘‘related to’’ a benefits plan under
ERISA and thus preempted by ERISA’s
preemption provision ‘‘if it has a
connection with or reference to such a
plan.’’
Nissan said that California’s
greenhouse gas standard is connected to
fuel economy. California’s greenhouse
gas regulation is, in effect, a fuel
economy regulation. The emission of
one greenhouse gas, CO2, is related to
fuel economy. The only means for
vehicle manufacturers to reduce
vehicular CO2 emissions is through
making improvements to fuel economy.
This is evident from CARB’s report,
which discusses the maximum feasible
and cost effective technologies available
and the identification of technologies
that are in fact fuel economy
improvements.
Nissan also said that California’s
standard also interferes with the
nationally uniform plan that CAFE
establishes for governing the fuel
efficiency of the U.S. fleet and is
therefore impliedly preempted. A state
law or standard may be impliedly preempted because the federal interest is so
dominant that Congress intends to
occupy a regulatory field with no room
for state supplementation (field
preemption) or because the federal
government has enacted a complete
regulatory scheme in an area such that
any state action would be inconsistent
with the federal legislation (conflict
preemption).
Nissan concluded by arguing that
individual state laws setting fuel
economy standards would be impliedly
as well as expressly preempted. It
argued that those laws would conflict
with EPCA, which authorizes DOT to
develop and administer a national CAFE
program. Neither the EPA, nor States are
permitted to interfere with the CAFE
166 California, Connecticut, Maine, Massachusetts,
New York, New Jersey, Oregon, Pennsylvania, and
Vermont.
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regulatory regime currently established
by Congress under EPCA. Because, as
noted above, the emission of CO2 is
related to fuel economy and because the
only way to reduce CO2 is through fuel
economy technologies, any effort to do
so by EPA or the States would interfere
with Congressional objectives under
EPCA.
Taken together, the primary
arguments of the opponents of
preemption were as follows:
The opponents argued that the
preemption waiver provision of the
Clean Air Act expressly recognizes the
right of California to adopt and enforce
its own standards for ‘‘air pollutants’’
emitted by motor vehicles (i.e.,
emissions standards), and the right of
the other States to adopt and enforce
standards identical to California’s
standards.167 They said that Congress
ratified and strengthened the
preemption waiver provision in 1977,
two years after the enactment of EPCA
in 1975. Thus, they argue, Congress
could not have intended EPCA to limit
the rights they believe are recognized by
the Clean Air Act.
The opponents believe further that a
State CO2 standard, including
California’s GHG/CO2 equivalent
emissions standard, is not preempted
under EPCA’s express preemption
provision, Section 32919(a). They
offered two arguments in support of this
belief.
First, they argued that EPCA does not
expressly preempt a State CO2 standard.
They believe that statute’s express
preemption provision should be read
narrowly, preempting State standards
that regulate fuel economy itself, but not
State standards that have a stated
purpose other than improving fuel
economy (i.e., reducing emissions) and
merely have the effect of increasing fuel
economy.
Second, they argued that the intent of
Congress concerning the relationship
between State motor vehicle emissions
standards and CAFE standards under
EPCA is expressed in the Act’s
provision setting out the factors to be
considered in setting CAFE standards
(‘‘decisionmaking factors provision’’),
Section 32902(f), not its express
preemption provision. The
decisionmaking factors provision
requires NHTSA to consider
technological feasibility, economic
practicability, the effect of other
Government standards on fuel economy,
and the need of the nation to conserve
energy, in determining the level at
which it should set each CAFE
167 Clean Air Act §§ 209(b), 177, 42 U.S.C. 7543
and 7507.
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standard. The opponents said the
decisionmaking factors provision
subordinates the CAFE standards to all
State emissions standards, not vice
versa.
In addition, the opponents of
preemption appear to have argued that
there is no implied (conflict)
preemption because State CO2 standards
and CAFE standards have different
objectives and because NHTSA did not
show how a State CO2 standard would
adversely affect the CAFE standards.
They argue further that, in the event of
a conflict, CAFE standards must give
way to the emissions standards per the
decisionmaking factors provision.
NHTSA’s Response to Public Comments
on the Merits
Background
Fuel Economy Provisions of the Energy
Policy and Conservation Act
EPCA established the CAFE program,
mandating the issuance and
implementation of standards for
passenger cars and light trucks. The
statute specifies that the passenger car
standard is 27.5 mpg unless the agency
finds that the maximum feasible level
for a model year is different, and sets it
at that level. It directs NHTSA to
establish light truck standards at the
maximum feasible level, subject to four
statutorily specified factors.168
The Act specifies that the agency is to
determine the maximum feasible level
after considering technological
feasibility, economic practicability, the
effect of other motor vehicle standards
on fuel economy, and the need of the
Nation to conserve energy.169 The
agency has historically included the
potential for adverse safety
consequences when deciding upon a
maximum feasible level. The
overarching principle that emerges from
the enumerated factors and the courtsanctioned practice of considering
safety and links them together is that
CAFE standards should be set at a level
that will achieve the greatest amount of
fuel savings without leading to
significant adverse economic or other
societal consequences.170
EPCA specifies that compliance with
CAFE standards is to be determined in
accordance with test and calculation
procedures established by EPA. 49
U.S.C. 32904(c). Under the procedures
established by EPA, compliance with
the CAFE standards is based on the rates
168 49
U.S.C. 32902(a).
U.S.C. 32902(f).
170 Average Fuel Economy Standards for Light
Trucks; Model Years 2008–2011, 70 FR 51414,
51424 (August 30, 2005) (to be codified at 49 CFR
pt. 533).
169 49
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of emission of CO2, CO, and
hydrocarbons from covered vehicles,
but primarily on the emission rates of
CO2. In the measurement and
calculation of a given vehicle model’s
fuel economy for purposes of
determining a manufacturer’s
compliance with federal fuel economy
standards, the role of CO2 is
approximately 100 times greater than
the combined role of the other two
relevant carbon exhaust gases. Given
that the amount of CO2, CO, and
hydrocarbons emitted by a vehicle
varies directly with the amount of fuel
it consumes, EPA can reliably and
accurately convert the amount of those
gases emitted by that vehicle into the
miles per gallon achieved by that
vehicle.
Congress explicitly and broadly
preempted all state laws and standards
relating to fuel economy standards:
[w]hen an average fuel economy standard
prescribed under this chapter [49 U.S.C.S.
§§ 32901 et seq.] is in effect, a State or a
political subdivision of a State may not adopt
or enforce a law or regulation related to fuel
economy standards or average fuel economy
standards for automobiles covered by an
average fuel economy standard under this
chapter.171
Congress did not include a provision
authorizing any waivers of that
preemption provision for any State for
any reason.
Clean Air Act
Congress has also preempted all state
standards relating to the control of
motor vehicle emissions:
[n]o State or any political subdivision thereof
shall adopt or attempt to enforce any
standard relating to the control of emissions
from new motor vehicles or new motor
vehicle engines.172
However, Congress has also expressly
authorized EPA to waive the
preemption provision under the Clean
Air Act for states that adopted emissions
control standards before 1966.173 While
California is the only State that meets
that criterion, and thus is the only state
that can obtain a waiver of the
preemption provision, the Clean Air Act
permits other States to adopt California
emission standards.174
Current State GHG Standards 175
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The GHG standard purports to
regulate four motor vehicle climate
change emissions:
171 49
U.S.C. 32919(a).
U.S.C. 7543 (a).
173 42 U.S.C. 7543 (b).
174 42 U.S.C. 7507.
175 According to the National Academy of
Sciences, Massachusetts, New York, New Jersey,
172 42
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• CO2, CH4 and N2O emissions
resulting directly from operation of the
vehicle,
• CO2 emissions resulting from
operating the air conditioning system,
• HFC (refrigerant) emissions from
the air conditioning system due to either
leakage, losses during recharging, or
release from scrappage of the vehicle at
end of life, and
• Upstream emissions associated with
the production of the fuel used by the
vehicle.176
As is shown later in the discussion of
preemption, compliance with the GHG
standards will be based primarily on the
CO2 emission rates of vehicles. The
States will measure the amounts of
emissions of these four gases and then
convert them into ‘‘CO2-equivalent’’
emissions.177 This reflects the status of
CO2 as the reference gas for measuring
the global warming potential of
greenhouse gases.
because of a conflict with a congressional
enactment.178
Constitutional basis for preemption
[49 U.S.C.] 32919. Preemption
(a) General. When an average fuel economy
standard prescribed under this chapter [49
U.S.C.S. §§ 32901 et seq.] is in effect, a State
or a political subdivision of a State may not
adopt or enforce a law or regulation related
to fuel economy standards or average fuel
economy standards for automobiles covered
by an average fuel economy standard under
this chapter.
Preemption results from Article VI of
the U.S. Constitution, which provides
that federal law ‘‘shall be the supreme
Law of the Land; and the Judges in
every State shall be bound thereby, any
Thing in the Constitution or Laws of any
State to the Contrary notwithstanding.’’
Principles of preemption
The Supreme Court has held that
preemption may be express or implied:
State law may be preempted by express
language in a congressional enactment,* * *
by implication from the depth and breadth of
a congressional scheme that occupies the
legislative field * * *, or by implication
Connecticut, Rhode Island, Vermont, and Maine
have adopted the California GHG emissions
standard. In addition, Washington State has
adopted the standard contingent upon Oregon’s
adoption of it. Oregon ‘‘has adopted temporary
rules . . . and is scheduled to propose permanent
rules in the summer of 2006.’’ State and Federal
Standards for Mobile Source Emissions,
prepublication copy, 145 (2006).
This discussion of preemption focuses on the
details of the California standard in order to provide
the clearest possible expression of the underlying
technical rationale for why that standard is not
consistent with NHTSA’s authority to regulate fuel
economy. This specific discussion should not be
interpreted to mean that other standards would be
acceptable.
176 Title 13, California Code of Regulations (CCR)
§ 1961.1(a)(1)(B)1.a. For vehicles certified on
conventional fuels (e.g., gasoline), CARB’s
regulation does not encompass upstream emissions
(i.e., emissions associated with the production and
transportation of the fuel used by the vehicle).
California Environmental Protection Agency, Air
Resources Board, Regulations To Control
Greenhouse Gas Emissions From Motor Vehicles,
Final Statement Of Reasons (FSOR), at 6–7.
177 California Environmental Protection Agency,
Air Resources Board, Regulations To Control
Greenhouse Gas Emissions From Motor Vehicles,
Initial Statement Of Reasons (ISOR), p. 48.
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Discussion
In response to the public comments
and letters from members of Congress,
we have re-analyzed all issues carefully
as set forth below, and determined,
based on existing and foreseeable
technologies for reducing CO2 emissions
from motor vehicles, that the effect
under EPCA and the Supremacy Clause
of the U.S. Constitution is that State
regulation of those emissions is
preempted.
Any Regulation Governing Carbon
Dioxide Emissions From Motor Vehicles
Relates to Average Fuel Economy
Standards and Is Expressly Preempted
Under 49 U.S.C. Chapter 329
EPCA contains a broadly worded
provision expressly preempting any
State standard or regulation that is
‘‘related to’’ a fuel economy standard:179
(Emphasis added.)
While the express preemption
provision on its face uses expansive
language, any ambiguity regarding the
appropriate reading of the provision,
particularly in relation to other statutory
provisions, must be resolved in light of
the policy considerations embodied in
EPCA. In NHTSA’s judgment, this
language includes, but is not limited to,
explicit fuel economy standards issued
by States. Because the only
technologically feasible, practicable way
for vehicle manufacturers to reduce CO2
emissions is to improve fuel
economy,180 NHTSA’s considered view
is that a State regulation that requires
vehicle manufacturers to reduce those
emissions is a ‘‘regulation related to fuel
economy standards or average fuel
economy standards.’’ 181 This view is
consistent with the legislative history of
the preemption provision, and with the
178 Lorillard Tobacco Co. v. Reilly, 533 U.S. 525,
540 (2001).
179 70 FR, at 51457 (August 30, 2005).
180 NHTSA recognizes that regulating the
producers of motor vehicle fuels can contribute to
the reduction of CO2 emissions. The preemption
provision of EPCA does not preempt State
regulation of those fuels. However, it does preempt
State regulation of the manufacturers of motor
vehicles directly related to fuel economy, including
regulation of CO2 emissions of their vehicles.
181 Id.
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Supreme Court’s interpretation of
similar provisions.
The legislative history of that
provision confirms that Congress
intended to be broadly preemptive in
the area of fuel economy regulation. The
Senate bill 182 would have preempted
State laws only if they were
‘‘inconsistent’’ with federal fuel
economy standards, labeling, or
advertising, while the House bill 183
would have preempted State laws only
if they were not ‘‘identical to’’ a Federal
requirement. The express preemption
provision as enacted preempts all State
laws that relate to fuel economy
standards. No exception is made for
State laws on the ground that they are
consistent with or identical to federal
requirements.
In interpreting the express
preemption provisions of other statutes
containing the identical ‘‘relates to’’
language found in EPCA, the Supreme
Court has found this language to be very
expansive. A State law relates to a
Federal law if the State law ‘‘has a
connection with or refers to’’ the subject
of the Federal law. The Court made the
latter finding first under ERISA 184 and
then, based on its ERISA cases and the
use of identical language, under the
Airline Deregulation Act (ADA).185
‘‘Since the relevant language of the ADA
is identical, we think it appropriate to
adopt the same standard here * * * ’’186
Particularly since the Airline
Deregulation Act’s situation is a law
involving transportation, we think its
interpretation of the phrase ‘‘relates to’’
is instructive here.
In particular, the Court has provided
guidance on the ultimate limits of a
strictly textual approach in interpreting
either the phrase ‘‘relates to’’ or the
phrase ‘‘has a connection with,’’ given
the existence of unending relationships
and ‘‘infinite connections’’ and the
resulting potential for an overly
extensive application of ERISA’s
preemption provision, the Court
declined to take that approach in
interpreting that provision in Blue Cross
& Blue Shield Plans v. Travelers Ins.
Co.187 The Court said that to determine
whether a State law has a forbidden
connection, it would instead look ‘‘both
to the objectives of the ERISA statute as
a guide to the scope of the state law that
Congress understood would survive, as
182 S.
1883, 94th Cong., 1st Sess., Section 509.
7014, 94th Cong., 1st Sess., Section 507
as introduced, Section 509 as reported.
184 Shaw v. Delta Airlines, Inc., 463 U.S. 85, 97
(1983).
185 Morales v. Trans World Airlines, Inc., 504 U.S.
374, 384 (1992).
186 Ibid.
187 514 U.S. 645, 656, 658–662 (1995),
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well as to the nature of the effect of the
state law on ERISA plans. California
Div. of Labor Standards Enforcement v.
Dillingham Constr., N.A., Inc., 519 U.S.
316, 325 (1997), quoting Travelers,
* * * , at 656 * * * ’’ (Emphasis
added.) (Internal quotations omitted.) 188
Even under that sort of analysis,
however, the results would be
unchanged here. Congress had a variety
of interrelated goals in enacting EPCA
and has charged NHTSA with balancing
and achieving them. Among them was
the overarching one of improving motor
vehicle fuel economy.189 To achieve
that goal, Congress did not simply
mandate the issuance of fuel economy
standards set at whatever level NHTSA
deemed appropriate. Nor did it simply
say that levels must be set consistent
with the criteria it specified in Section
32902(f). It went considerably further,
mandating the setting of standards at the
maximum feasible level.
Congress also sought national uniform
fuel economy standards ‘‘[i]n order to
avoid any manufacturer being required
to comply with differing State and local
regulations with respect to automobile
or light-duty truck fuel economy.’’ 190
To that end, it expressly preempted
State and local laws and regulations
relating to fuel economy standards.
Other congressional objectives
underlying EPCA include avoiding
serious adverse economic effects on
manufacturers and maintaining a
reasonable amount of consumer choice
among a broad variety of vehicles.
Congress was explicitly concerned that
the CAFE program be carefully drafted
so as to require levels of average fuel
economy that do not have the effect of
either ‘‘imposing impossible burdens or
unduly limiting consumer choice as to
capacity and performance of motor
vehicles.’’ 191 These concerns are
equally applicable to the manner in
which that program is implemented.
To guide the agency toward the
selection of standards meeting these
competing objectives, Congress
specified four factors that NHTSA must
consider in determining which level is
the maximum feasible level of average
fuel economy and thus the level at
which each standard must be set.
These are technological feasibility,
economic practicability, the effect of
other Government standards on fuel
economy, and the need of the Nation to
conserve energy. In addition, ‘‘NHTSA
has always examined the safety
188 Egelhoff
v. Egelhoff, 532 U.S. 141, 147 (2001).
for Auto Safety v. NHTSA, 793 F.2d
1322, 1340 (D.C. Cir. 1986).
190 S. Rep. No. 94–179, 25 (1975).
191 H. Rep. No. 94–340, 87 (1975).
189 Center
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17657
consequences of the CAFE standards in
its overall consideration of relevant
factors since its earliest rulemaking
under the CAFE program.’’ 192
While the Court in Travelers said
State laws found to have ‘‘only a
tenuous, remote, or peripheral
connection’’ to ERISA’s purposes,
especially in areas of traditional State
regulation, are not preempted,193
NHTSA has concluded that a State GHG
standard is not such a law. As explained
at length below, to the extent that it
regulates tailpipe CO2 emissions, a State
GHG standard has a direct and very
substantial effect on EPCA’s objectives,
placing it virtually at the very center of
the reach of EPCA’s express preemption
provision, not at or even near its
periphery. Thus, there is no need here
to address issues about the definition or
location of the outer reaches of the
provision’s application.
As explained below, CO2 emissions
account for over 90 percent of all CO2
equivalent emissions from a motor
vehicle. Accordingly, a State standard
regulating GHG emissions expressed as
CO2 equivalent emissions is, to a very
substantial extent, a State CO2 emissions
standard. To that extent, a State GHG
standard is fuel economy standard in
almost all but name and stated purpose.
It would have virtually the same effects
as a fuel economy standard. Thus,
NHTSA has concluded that a State GHG
standard does not incidentally affect
vehicle manufacturers; it directly targets
them.
Likewise, in NHTSA’s view, such a
standard does not incidentally affect
decisions by manufacturers to add fuel
saving technologies to their vehicles.
Because the only currently practical
way for vehicle manufacturers to reduce
CO2 tailpipe emissions is through
application of fuel saving
technologies 194 and no technologies are
even under development that would
make possible reduction of CO2
emissions independent of reducing fuel
consumption,195 such a standard
directly targets manufacturers and
compels the use of those technologies.
Therefore, the agency has concluded
192 Competitive Enterprise Institute v. NHTSA,
901 F.2d 107, 120 at n.11 (D.C. Cir. 1990).
193 Blue Cross & Blue Shield Plans v. Travelers
Ins. Co., 514 U.S. 645, 658–662 (1995).
194 Essentially all of the technologies identified by
the California Air Resources Board for reducing CO2
emissions are among the technologies listed by the
National Academy of Science in its 2002 report on
reforming the CAFE program and improving fuel
economy. The essential identity of the two lists
confirms the fact that, currently, the only method
for reducing CO2 emissions is to reduce fuel
consumption.
195 EPA has reached a similar conclusion. See 68
FR 52922, 52929.
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that the effect of a State GHG standard
on vehicle design and performance is
the same as that of fuel economy
standards.
Commenters opposing preemption
suggested that the purpose of a State
law, not its effects, should determine
whether there is preemption. Since the
purpose of a State GHG regulation for
motor vehicles is regulating CO2 and
other GHG emissions from motor
vehicles, not fuel economy, they suggest
that there can be no preemption under
EPCA’s express preemption provision.
This limited view regarding the extent
of preemption under that provision is
inconsistent with NHTSA’s expert
analysis, which is guided by and
comports with the Supreme Court’s
discussion of the similarly worded
express preemption provisions in ERISA
and the ADA. As noted above, in
resolving ambiguity regarding
preemption under a Federal law, the
Court looks at the effects of a State law
on the subject addressed by the Federal
law to aid in determining if there is
preemption.196
A federal statute’s broadly worded
express preemption provision does not
lose its preemptive effect because a
State cites a purpose other than or in
addition to the purpose of that federal
statute.197 In Gade, the Supreme Court
said that ‘‘[i]n assessing the impact of a
state law on the federal scheme, we
have refused to rely solely on the
legislature’s professed purpose and have
looked as well to the effects of the
law.’’ 198
The agency’s conclusions here that
the EPCA preemption provision is
expansive and preempts State emissions
regulations that have the practical effect
of regulating fuel economy are fully in
keeping with earlier views expressed by
the government. Further, they are
consistent with views that EPA has
articulated.
In June 2002, the U.S. District Court
for the Eastern District of California
issued an order granting plaintiff
196 Egelhoff,
at 147.
v. National Solid Wastes Management
Ass’n., 505 U.S. 88, 105 (1992).
198 Id., at 106; see also Morales, at 386: ‘‘petitioner
advances the notion that only state laws specifically
addressed to the airline industry are pre-empted,
whereas the ADA imposes no constraints on laws
of general applicability. Besides creating an utterly
irrational loophole (there is little reason why state
impairment of the federal scheme should be
deemed acceptable so long as it is effected by the
particularized application of a general statute), this
notion similarly ignores the sweep of the ‘relating
to’ language. We have consistently rejected this
precise argument in our ERISA cases: ‘[A] state law
may ‘‘relate to’’ a benefit plan, and thereby be preempted, even if the law is not specifically designed
to affect such plans, or the effect is only indirect.’ ’’
(Citations omitted.)
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automobile manufacturers’ and dealers’
motion for preliminary injunction and
issuing a preliminary injunction in
Central Valley Chrysler-Plymouth v.
California Air Resources Bd., No. CV–F–
02–5017 REC/SMS, 2002 U.S. Dist.
LEXIS 20403 (E.D. Cal. June 11, 2002)
(enjoining California zero-emissionvehicle (ZEV) rule). The court found
that the plaintiffs had shown that the
ZEV rule was ‘‘related to’’ fuel economy
standards because it had the purpose
and practical effect of regulating fuel
economy. The court also found that
‘‘preemption cannot be avoided by
intertwining preempted requirements
with nonpreempted requirements.’’
In October 2002, the United States
filed an amicus curiae brief in support
of affirming the June 2002 order in
Central Valley Chrysler-Plymouth, Inc.
et al. v. Michael P. Kenny, No. 02–
16395, (9th Cir. 2002), pointing out that
EPCA contains a broadly stated
provision expressly preempting state
regulations ‘‘related to’’ fuel economy
standards. The government further
pointed out that, unlike the Clean Air
Act, EPCA does not contain an
exception allowing a state law that
regulates fuel economy, regardless of the
purpose of the law. Given that Congress
had included some exceptions, but not
that particular one, the government said
that it would be inappropriate to read in
or imply that exception.
In December 2002, NHTSA published
a CAFE NPRM for MY 2005–2007 light
trucks in which the agency addressed
certain court filings by the State of
California relating to CAFE preemption.
The agency noted that California had:
[I]n recent court filings, asserted that
NHTSA has not treated the CAFE statute as
preempting state efforts to engage in CAFE
related regulation, stating that ‘‘time and time
again, NHTSA in setting CAFE standards has
commented on the fuel economy effects of
California’s emissions regulations, and not
once has it even suggested that these were
preempted.’’ See Appellants Opening Brief
filed on behalf Michael P. Kenny in Central
Valley Chrysler-Plymouth, Inc. et. al. v.
Michael P. Kenny, No. 02–16395, at p. 33
(9th Cir. 2002). As a result, the State suggests
that it may, consistent with federal law, issue
regulations that relate to fuel economy.
The State misses the point. The agency
reviews emissions requirements to ensure
that we do not establish a standard that is
infeasible in light of other public policy
considerations, including federal and state
efforts to regulate emissions. Thus, we
consider potential fuel economy losses due to
more stringent emissions requirements when
we determine maximum feasible fuel
economy levels.
This does not mean that a state may issue
a regulation that relates to fuel economy and
which addresses the same public policy
concern as the CAFE statute. Our statute
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contains a broad preemption provision
making clear the need for a uniform, federal
system: ‘‘When an average fuel economy
standard prescribed under this chapter is in
effect, a State or a political subdivision of a
State may not adopt or enforce a law or
regulation related to fuel economy standards
or average fuel economy standards for
automobiles covered by an average fuel
economy standard under this chapter.’’ 49
U.S.C. 32919(a).
The fact that NHTSA had not expressly
addressed this particular aspect of
California’s requirements should not have
been interpreted as tacit acceptance. Indeed,
the United States has taken the express
position in the Kenny case that it has a
substantial interest in enforcing the federal
fuel economy standards and in ensuring that
states adhere to the Congressional directive
prohibiting them from adopting or enforcing
any law or regulation related to fuel economy
or average fuel economy standards.199
In its CAFE final rule for MY 2005–
07 light trucks, NHTSA stated that its
‘‘position with regard to the relationship
between state laws and our federal fuel
economy responsibility was set forth in
the [December 2002] NPRM and has not
changed. The EPCA statute contains a
preemption provision intended to
ensure a unified federal program to
address motor vehicle fuel economy.’’
In September 2003, the
Environmental Protection Agency
specifically discussed the relationship
between CO2 standards and fuel
economy. In denying an October 1999
petition by the International Center for
Technology Assessment (ICTA) asking
the EPA to regulate CO2 and other
greenhouse gas emissions from motor
vehicles under the Clean Air Act for the
purpose of addressing global climate
change, the EPA included a discussion
of how regulating CO2 emissions would
cause ‘‘[i]nterference with Fuel
Economy Standards:’’
Even if GHGs were air pollutants generally
subject to regulation under the CAA,
Congress has not authorized the Agency to
regulate CO2 emissions from motor vehicles
to the extent such standards would
effectively regulate the fuel economy of
passenger cars and light duty trucks. No
technology currently exists or is under
development that can capture and destroy or
reduce emissions of CO2, unlike other
emissions from motor vehicle tailpipes. At
present, the only practical way to reduce
tailpipe emissions of CO2 is to improve fuel
economy. Congress has already created a
detailed set of mandatory standards
governing the fuel economy of cars and light
duty trucks, and has authorized DOT—not
EPA—to implement those standards. The
only way for EPA to proceed with CO2
emissions standards without upsetting this
199 Light Truck Average Fuel Economy Standards
Model Years 2005–2007, 67 FR 77015, at 77025
(Proposal to establish standards December 16,
2002).
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statutory scheme would be to set a standard
less stringent than CAFE for cars and light
duty trucks. But such an approach would be
meaningless in terms of reducing GHG
emissions from the U.S. motor vehicle
fleet.200
EPA further explained this position in
its brief filed in early 2005 in the Court
of Appeals for the D.C. Circuit in
Commonwealth of Massachusetts v.
EPA, No. 03–1361, in which 12 states
and a number of environmental groups
filed a petition for review challenging
EPA’s denial of ICTA’s petition:
Further reinforcing both the legal and policy
rationales for the ICTA Petition Denial is the
fact that at present, the only practical way of
making a meaningful reduction in motor
vehicle emissions of CO2 (the most
significant greenhouse gas) is by increasing
fuel economy. See 68 FR at 52929.
Consequently, even if EPA possessed CAA
authority to regulate CO2 for climate change
purposes, any motor vehicle standard EPA
might set under the Act that required
meaningful reductions in CO2 emissions
would effectively require a corresponding
increase in fuel economy. However, in the
Energy Policy and Conservation Act
(’’EPCA’’), 49 U.S.C. 32901–18, Congress
established a detailed program for regulating
the fuel economy of passenger cars and light
trucks—the bulk of the motor vehicle fleet—
and it authorized DOT, not EPA, to
implement that program. EPA thus
reasonably concluded that it would be
inconsistent with EPCA for EPA to set CO2
emission standards under the CAA that
would effectively require significant
increases in the fuel economy of vehicles
subject to EPCA. 68 FR at 52929. In arguing
that EPCA does not expressly abrogate EPA’s
authority under the CAA, see Pet. Br. at 38–
43, Petitioners ignore those EPCA provisions
that clearly signal Congress’ intent that
regulation of motor vehicle fuel economy be
governed by EPCA alone.
NHTSA Has Concluded That Any Effort
to Regulate Carbon Dioxide Emissions
From Motor Vehicles Is Related to
Average Fuel Economy Standards for
Motor Vehicles Under 49 U.S.C. Chapter
329
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1. Motor Vehicle Fuel Economy Is
Directly Related to Emissions of Carbon
Dioxide
Fossil fuels such as petroleum contain
mostly hydrocarbons (compounds
containing hydrogen and carbon). In the
combustion process, these fuels are
oxidized to produce heat. In perfect
combustion, the oxygen (O2) in the air
combines with all of the carbon (C) in
the fuel to form carbon dioxide (CO2)
and all of the hydrogen (H) in the fuel
to form water (H2O).
200 Control of Emissions from New Highway
Vehicles and Engines, 68 FR 52922, 52929 (denial
of petition September 8, 2003).
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Most light trucks are powered by
gasoline internal combustion engines.
The combustion of gasoline produces
CO2 in amounts that can be readily
calculated. Based on its content (carbon
and hydrogen), as a matter of basic
chemistry, the burning of a gallon of
gasoline produces about 20 pounds of
CO2.201 202
In practice, the combustion process is
not 100 percent efficient and engines
produce several types of emissions as
combustion byproducts or as a result of
incomplete combustion. In an internal
combustion engine, these include
nitrogen oxides (NOX) (from nitrogen
and oxygen in the atmosphere), carbon
monoxide (CO) and hydrocarbons (HC),
including methane. These emissions do
not alter the fact that combustion of
gasoline produces CO2. Moreover, the
amounts of CO2 emitted per mile are far
greater than the amounts of HC, CO, and
NOX, singly or combined.203 204
CO2 emissions are always and directly
linked to fuel consumption because CO2
is the ultimate end product of burning
gasoline.205 The more fuel a vehicle
201 Most of that weight comes from the oxygen in
the air. A carbon atom has an atomic weight of 12,
and each oxygen atom has an atomic weight of 16,
giving each single molecule of CO2 an atomic
weight of 12 + (16 × 2) or 44. Therefore, to calculate
the weight of the CO2 produced from a gallon of
gasoline, the weight of the carbon in the gasoline
is multiplied by 44/12 or 3.7. Since gasoline is
about 87% carbon and 13% hydrogen by weight,
and since a gallon of gasoline weighs about 6.3
pounds, the carbon in a gallon of gasoline weighs
(6.3 lbs. × .87) or 5.5 pounds. If the weight of the
carbon (5.5 pounds) is then multiplied by 3.7, the
answer is about 20 pounds. (Source: https://
www.fueleconomy.gov/feg/co2.shtml. The website,
https://www.fueleconomy.gov, is operated jointly by
the Department of Energy and the Environmental
Protection Agency.)
202 In addition, CO emissions can be determined
2
from the carbon content of the fuel by using a
carbon content coefficient that reflects the amount
of carbon per unit of energy in each fuel. CO2
emissions = energy consumption [e.g., in Btu] ×
carbon content coefficient for the fuel × fraction of
carbon oxidized [99% for petroleum] × 3.67
[conversion of carbon to carbon dioxide (44/12)
based on molecular weights]. T.J. Blasing, G.
Marland and C. Broniak, Estimates of Annual
Fossil-Fuel CO2 Emitted for Each State in the U.S.A.
and the District of Columbia for Each Year from
1960 through 2001, at https://cdiac.ornl.gov/trends/
emis_mon/stateemis/emis_state.htm. The carbon
content coefficients for petroleum products have
varied very little over time—less than one percent
per year since 1990. Id. Reformulated gasoline
introduced in the 1990s pursuant to the Clean Air
Act Amendments of 1990 has a carbon emissions
coefficient approximately one percent smaller than
that of standard gasoline.
203 U.S. EPA, Average Annual Emissions and Fuel
Consumption for Passenger Cars and Light Trucks,
EPA420–F–00–013, April 2000. Available on the
Internet at https://www.epa.gov/otaq/consumer/
f00013.pdf.
204 Good, David, U.S. EPA, 2006 test-car-list-and
analysis for DD 206.xls, February 2006.
(unpublished analysis of 2006 test car list available
at https://www.epa.gov/otaq/tcldata.htm).
205 See also EPA’s denial of petition to regulate
CO2 tailpipe emissions from motor vehicles, 68 FR
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17659
burns or consumes, the more CO2 it
emits.206 Viewed another way, fuel
economy is directly related to emissions
of greenhouse gases such as CO2.207
Fuel consumption and CO2 emissions
from a vehicle are two ‘‘indissociable’’
parameters.208
2. The Most Significant Factor in
Determining the Compliance of Motor
Vehicles With NHTSA’s Fuel Economy
Standards Is Their Rate of Carbon
Dioxide Emissions
A manufacturer’s compliance with the
federal average fuel economy standards
is based on the collective fuel
economies of its covered vehicles. For
purposes of determining compliance
with federal fuel economy standards,
EPA and manufacturers measure the
amount of CO2, CO, and HC emitted
from the vehicle. The regulations
requiring this approach do so because of
the scientific relationship between fuel
consumption and carbon emissions.
As noted above, gasoline is comprised
of carbon and hydrogen in the form of
HC compounds. Carbon and hydrogen
are basic elements that are not
converted to other elements in either
internal combustion engines or catalytic
converters. As a component of the fuel,
the carbon is conveyed to the engine,
where combustion occurs. Thereafter,
the carbon, largely in different
compounds than in gasoline, is emitted
through the tailpipe. Thus, if the carbon
content of the fuel is known, the amount
of fuel consumed by the engine can be
determined by measuring tailpipe
emissions of carbon-containing
compounds.209 Fully combusted carbon
52922, 52931, September 8, 2003; Center for
Biological Diversity (November 22, 2005, NHTSA
2005–22223–1382) (p. 2–3); RAND Europe,
Preparation of Measures to Reduce CO2 Emissions
from N1 Vehicles, Final Report, at 4, prepared for
the European Commission, 11th April 2003.
206 ‘‘Vehicles with lower fuel economy burn more
fuel, creating more CO2. Your vehicle creates about
20 pounds of CO2 (170 cu. ft.) per gallon of gasoline
it consumes. Therefore, you can reduce your
contribution to global climate change by choosing
a vehicle with higher fuel economy. By choosing a
vehicle that achieves 25 miles per gallon rather than
20, you can prevent the release of about 17 (260
thousand cu. ft.) tons of greenhouse gases over the
lifetime of your vehicle.’’ Model Year 2006 Fuel
Economy Guide, at 2, Department of Energy and
Environmental Protection Agency, DOE/EE–0309.
207 68 FR 52922, 52931; Light-Duty Automotive
Technology and Fuel Economy Trends: 1975
through 2005—Executive Summary, EPA420–S–05–
0001, July 2005, at https://www.epa.gov/otaq/cert/
mpg/fetrends/420s05001.htm.
208 P. Leduc, B. Dubar, A. Ranini and G. Monnier,
Downsizing of Gasoline Engine: an Efficient Way to
Reduce CO2 Emissions, at 2, Institut Francais du
¸
´
Petrole, Division Techniques d’Applications
´
Energetiques, 92852 Rueil-Malmaison Cedex—
France).
209 DOT FHWA, Perspectives on Fuel
Consumption and Air Contaminant Emission Rates
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Federal Register / Vol. 71, No. 66 / Thursday, April 6, 2006 / Rules and Regulations
takes the form of CO2. Partially
combusted carbon takes the form of CO
or HC (generally unburned
hydrocarbons). Therefore, fuel
consumption may be determined by
measuring tailpipe emissions of CO2,
CO, and HC.
As a result of incomplete combustion,
CO and HC are emitted from a vehicle’s
engine. However, in the years since
vehicle manufacturers were first
required to meet federal fuel economy
standards, the manufacturers have also
been required under the Clean Air Act
to meet increasingly stringent standards
for emission of CO, HC, NOX, and
particulates.210 They have been able to
meet these standards because fuels have
been reformulated to burn cleaner, and
vehicle manufacturers have applied
many significant technological advances
to the engines and vehicles (e.g.,
multipoint fuel injection, closed-loop
computer-controlled mixture control,
and close-coupled 3-way exhaust
catalysts). As a result, emissions of CO
and HC have fallen dramatically.
Moreover, the technologies that produce
these reductions in air pollution do so
by more completely converting CO and
HC to CO2 (and water).211 Over the same
time period, there has not been a
corresponding decline in CO2
emissions, which, as noted above, are
the necessary result of gasoline
consumption. CO and HC play an
increasingly and extremely minor role
in the measurement of fuel economy,
such that fuel economy has become
virtually synonymous with CO2
emission rates.
The fuel economy of a particular
vehicle is determined by a formula
promulgated by EPA. That formula (an
equation) calculates fuel economy based
on carbonaceous emissions from the
vehicle, taking into account the
normalization of the fuel to a
standardized test fuel. Under the
formula, in determining fuel economy,
all carbon emissions—i.e., the CO2
emission rate, HC emission rate, and CO
emission rate—are considered.
Significantly, as demonstrated by the
example below, in determining fuel
economy the role of CO2 emissions
greatly outweighs that of these other
exhaust gases. This is reflected by the
relative magnitudes of the CO2 term and
non-CO2 terms in the equation. In other
words, calculating fuel economy is
largely a function of CO2 emissions.
Under 40 CFR 600.113, fuel economy
(mpg) is calculated using the following
equation:
Where:
HC = hydrocarbon emission rate (grams
per mile)
CO = carbon monoxide emission rate
(grams per mile)
CO2 = carbon dioxide emission rate
(grams per mile)
CWF = carbon weight fraction of test
fuel
NHV = net heating value (by mass) of
test fuel
SG = specific gravity of test fuel
Under the regulation, separate
measurements and calculations under
the Federal Test Procedure (i.e., city
cycle) and Federal Highway Fuel
Economy Test Procedure (i.e., highway
cycle) are required, with the resultant
city (mpgc) and highway (mpgh) fuel
economy values being harmonically
averaged using weights of 0.55 and 0.45,
respectively.212
Determining the characteristics of a
test fuel and inserting them into the
above equation is a preliminary step
toward assessing the relative importance
of CO2 emissions in determining
compliance with the fuel economy
standards.
For this purpose, we will use the
characteristics of a test fuel set forth in
the sample calculation in Appendix II to
40 CFR part 600:
CWF = 0.868
NHV = 18,478 Btu per pound
SG = 0.745
These values are within about 8
percent of other values in the record
(given relatively minor variations,
particularly in heating value, in
gasolines) and are reasonable for the
purposes of this assessment, although
very precise data would be collected for
a test for compliance with the rule.213
Substituting these values into EPA’s
general equation for fuel economy
shown above yields
211 Because carbon dioxide is, like water, an
ultimate byproduct of combustion, it cannot be
further converted on the vehicle to some other
compound through any practical means.
212 40 CFR 600.206–93.
213 See, e.g., Fuel economy impact of
reformulated gasoline (energy (NHV) of fuel, at
https://www.epa.gov/otaq/rfgecon.htm; Motor
Gasolines Technical Review, at https://
www.chevron.com/products/prodserv/fuels/
bulletin/motorgas/; Carbon Coefficients, at https://
www.eia.doe.gov/oiaf/1605/87-92rpt/appa.html;
and Specific Gravity—Liquids, at https://
www.engineeringtoolbox.com/specific-gravityliquids-d_336.html.
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by Highway Vehicles.
https:// www.tfhrc.gov/structur/pdf/01100.pdf.
210 As explained below in the final section of the
discussion of preemption, NHTSA does not believe
that regulation of these emissions is preempted by
EPCA since it is the agency’s judgment that such
regulation only tangentially affects fuel economy.
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which algebraically reduces to the
following:
Federal Register / Vol. 71, No. 66 / Thursday, April 6, 2006 / Rules and Regulations
Based on EPA data 214 averaged across
all MY 2006 truck test data available at
https://www.epa.gov/otaq/tcldata.htm
(which does not include production
data), model year 2006 light trucks have
17661
the following city cycle emission rates
as determined by testing by the Federal
Test Procedure:
HC = 0.042 g/mi
CO = 0.056 g/mi
CO2 = 471 g/mi
Substituting these values and the fuel
characteristics noted above into the
algebraically reduced equation shown
above,
The average model year 2006 light
truck emission rates on the highway
cycle were as follows: 215
HC = 0.011 g/mi
CO = 0.17 g/mi
CO2 = 316 g/mi
which, using the formula above, yields
the following highway fuel economy in
miles per gallon:
For both the city and highway
calculations, the controlling
independent variable is the large
number (term) in the denominator,
given that the numerator is a fixed
number. That number is the CO2 term
(86.268). The other numbers
(denominated the HC term and the CO
term) are not significant. More
particularly, for the 2006 model year
light trucks, the typical city and
highway CO2 terms for light trucks are
more than four hundred and one
thousand, respectively, times the
magnitude of the corresponding nonCO2 terms. NHTSA has concluded that
this proportion will not change,
especially in light of its conclusion that
emission limitations on the other types
of emissions are permissible under
EPCA.
As shown above, in the measurement
and calculation of a given vehicle
model’s fuel economy for purposes of
federal fuel economy standards, the role
of CO2 is controlling and far greater than
the combined role of the other two
relevant exhaust gases (CO and HC). A
manufacturer’s compliance with the
applicable CAFE standard is determined
by averaging model-specific fuel
economy values. This demonstrates that
compliance with federal fuel economy
standards is based primarily on CO2
emission rates of covered vehicles.216
3. NHTSA Has Concluded That a
Reduction of CO2 Emissions From
Motor Vehicles Is Possible Only
Through the Incorporation of the same
Technologies That Would Be Employed
To Increase Fuel Economy
The technologies that would be
employed to reduce CO2 emissions are,
in all relevant ways, the same
technologies as underlie NHTSA’s
judgment about the appropriate CAFE
standards for light trucks, as explained
below.217
The CAFE standards promulgated by
NHTSA are performance standards. As
such, they do not require the
employment of any particular
technology. But the standards are the
maximum feasible average fuel economy
level that NHTSA decides the
manufacturers can achieve in a
particular year. 218 They are based on
various technologies. Those
technologies are addressed in the
NHTSA CAFE rulemaking record. In
large measure, they are summarized in
Table 3–2 of the 2002 National
Academy of Sciences (NAS) CAFE
study, which is reproduced below in
Tables 18 and 19 (numbered as Tables
3–2 and 3–3, respectively, in the NAS
study).
vehicles will have a minor effect on the average fuel
economy of the overall fleet of new vehicles.
217 The agency has not identified any
technologies, let alone realistic ones, that could be
added to vehicle exhaust pipes to reduce CO2
emissions. Above and beyond the application of the
technologies addressed in this discussion of
preemption, to meet CO2 standards, in theory the
manufacturer could make the vehicle much smaller
or substantially reduce the size of its engine,
depending on the stringency of the CO2 regulation.
P. Leduc et al., op cit. see fn above; see also, https://
www4.nationalacademies.org/news.nsf/isbn/
0309076013?OpenDocument
218 See 49 U.S.C. 32902(a).
216 The vast majority of vehicles covered by
NHTSA’s light truck CAFE standard are powered by
gasoline fueled engines. Hybrids are expected to
comprise from 1.7 to 2.9 percent of the fleet of new
vehicles, while diesels are expected to comprise
from 0 to 2.6 percent. These non-gasoline fueled
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David, op. cit.
215 Ibid.
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214 Good,
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which produces the following city fuel
economy in miles per gallon:
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Federal Register / Vol. 71, No. 66 / Thursday, April 6, 2006 / Rules and Regulations
2005, CARB adopted amendments to its
regulations that it referred to as
‘‘California Exhaust Emission Standards
and Test Procedures for 2001 and
Subsequent Model Passenger Cars, Light
Duty Trucks and Medium Duty
Vehicles.’’219 In support of its
regulations, CARB released a report that
listed more than 20 technologies that
219 See https://www.arb.ca.gov/regact/grnhsgas/
grnhsgas.htm. The regulations are codified at Title
13 of the California Code of Regulations (CCR). See
13 CCR § 1961.1 (2006).
220 California Environmental Protection Agency,
Air Resources Board, Regulations To Control
Greenhouse Gas Emissions From Motor Vehicles,
Initial Statement of Reasons.
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manufacturers could be applied in order
to achieve compliance with its CO2based standards.220 The technologies
identified in the State’s report with
respect to large trucks are identified in
the second column of the table
reproduced below from its report, which
employs acronyms that are explained
below.
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If a state regulation required
manufacturers to reduce CO2 emissions
from motor vehicles, the state regulation
would be predicated on the
manufacturers’ employment of the same
technologies they would employ to meet
federal fuel economy standards. As an
example, for discussion purposes, we
will consider a California regulation. In
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TABLE 20.—CARB ‘‘TECHNOLOGY PACKAGES’’ TO REDUCE CO2 EMISSIONS FROM A LARGE TRUCK 221
CO2
(g/mi)
Light truck
Combined technology packages
Near ............................
Term 2009–2012 ........
CCP, A6, (2009 baseline) ...............................
DVVL, DCP, A6 ..............................................
CCP, DeAct, A6 ..............................................
DCP, DeAct, A6 ..............................................
DeAct, DVVL, CCP, A6, EHPS, ImpAlt ..........
DeAct, DVVL, CCP, AMT, EHPS, ImpAlt .......
CCP, DeAct, GDI–S, AMT, EHPS, ImpAlt ......
DeAct, DVVL, CCP, A6, ISG, EHPS, eACC ..
ehCVA, GDI–S, AMT, EHPS, ImpAlt ..............
GDI–L, AMT, EHPS, ImpAlt ............................
Mod HEV .........................................................
dHCCI, AMT, ISG, EPS, eACC ......................
GDI–L, AMT, ISG, EPS, ImpAlt ......................
HSDI, AdvHEV ................................................
AdvHEV ...........................................................
Mid Term 2013–2015
Long Term 2015– .......
The acronyms in the table above refer
to the following technologies: 222
A5: 5-speed automatic transmission
A6: 6-speed automatic transmission
AdvHEV: Advanced hybrid
AMT: Automatic Manual Transmission
CCP: Coupled cam phasing
CVVL: Continuous variable valve lift
DCP: Dual cam phasing
DeAct: Cylinder deactivation
dHCCI: Diesel homogeneous charge
compression ignition
DVVL:Discrete variable valve lift
eACC: Improved electric accessories
ehCVA: Electrohydraulic camless valve
actuation
EHPS: Electrohydraulic power steering
EPS: Electric power steering
GDI–S: Stoichiometric gasoline direct
injection
GDI–L: Lean-burn gasoline direct
injection
HSDI: High-speed (diesel) direct
injection
ImpAlt: Improved efficiency alternator
ISG: Integrated starter-generator systems
ModHEV: Moderate hybrid
Turbo: Turbocharging
As is evident from a comparison of
the excerpt from the NAS report above
Potential
CO2 reduction from
2002
baseline
(percent)
Retail price
equivalent
2002
Potential
CO2 reduction from
2009
baseline
(percent)
Retail price
equivalent
2009
¥5.5
¥13.6
¥15.4
¥15.9
¥18.4
¥22.6
¥18.6
¥26.2
¥25.5
¥24.4
¥44.5
¥29.3
¥30.7
¥52.2
¥52.5
$126
549
480
845
789
677
827
1885
1621
1460
2630
2705
2537
8363
5311
0
¥8.6
¥10.5
¥11.0
¥13.6
¥18.1
¥13.9
¥21.9
¥21.2
¥20.0
¥41.3
¥25.2
¥26.7
¥49.5
¥49.8
0%
$423
354
931
663
551
701
1759
1495
1334
2504
2579
2411
8237
5185
484
442
433
430
418
396
416
378
381
354
372
362
354
244
241
with the excerpt from the CARB
statement of reasons above, nearly all of
the technologies relied upon by CARB
are technologies that NHTSA largely
relies on in formulating the federal
average fuel economy standards. Thus,
vehicle manufacturers would have to
install many of the same types of
technologies under the NHTSA CAFE
rule and under the CARB greenhouse
gas rule.
California’s Regulation of Greenhouse
Gas/Carbon Dioxide Equivalent
Emissions From Motor Vehicles Is
Related to Average Fuel Economy
Standards for Motor Vehicles Under 49
U.S.C. Chapter 329 and Therefore
Preempted
California’s GHG regulations include
new requirements on greenhouse gas
emissions from motor vehicles
including model year 2009 and
subsequent model year light duty trucks
(LDT) and medium duty passenger
vehicles (MDPV). The CARB greenhouse
gas rules include two sets of standards
for motor vehicles. One set applies to all
passenger cars and to LDTs with a
loaded vehicle weight (LVW) up to 3750
pounds. The other set applies to LDTs
with a loaded vehicle weight of greater
than 3750 pounds and to MDPVs with
a gross vehicle weight of less than
10,000 pounds.
NHTSA’s CAFE rulemaking covers
MY 2008–2011 light trucks. It also
includes MY 2011 MDPVs. Thus, the
CARB regulations cover vehicles
covered by NHTSA’s rulemaking.
As noted above, CARB’s regulations
govern the emission of greenhouse gases
from passenger cars, light duty trucks
and medium duty passenger vehicles.
Greenhouse gases (GHG) is defined to
‘‘mean[] the following gases: CO2,
methane, nitrous oxide, and
hydrofluorocarbons.’’ 223
CARB’s GHG regulation states that the
fleet average greenhouse gas exhaust
emission values from passenger cars,
light-duty trucks and medium-duty
passenger vehicles that are produced
and delivered for sale in California shall
not exceed specified values.224 Table 21
provides the following requirements for
Fleet Average Greenhouse Gas Exhaust
Emissions, specified in terms of grams
per mile CO2—equivalent:
TABLE 21.—CARB FLEET AVERAGE GREENHOUSE GAS EXHAUST EMISSION REQUIREMENTS
[In grams/mi CO2-equivalent]
LDTs 0–3750 lbs
LVW and passenger cars
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Model
year
LDTs 3751 LVW–
8500 GVW and
MDPVs
323
301
267
439
420
390
2009 .............................................................................................................................................................
2010 .............................................................................................................................................................
2011 .............................................................................................................................................................
221 California Environmental Protection Agency,
Air Resources Board, Regulations To Control
Greenhouse Gas Emissions From Motor Vehicles
Initial Statement of Reasons (CARB ISOR) at 68.
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222 The acronyms appear in the CARB ISOR
report at 205–06.
223 13 CCR §§ 1961.1(d), (e)(4)
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TABLE 21.—CARB FLEET AVERAGE GREENHOUSE GAS EXHAUST EMISSION REQUIREMENTS—Continued
[In grams/mi CO2-equivalent]
LDTs 0–3750 lbs
LVW and passenger cars
Model
year
LDTs 3751 LVW–
8500 GVW and
MDPVs
233
227
222
213
205
361
355
350
341
332
2012 .............................................................................................................................................................
2013 .............................................................................................................................................................
2014 .............................................................................................................................................................
2015 .............................................................................................................................................................
2016+ ...........................................................................................................................................................
As explained in CARB’s ‘‘Final
Statement of Reasons’’ for its vehicular
GHG regulations, the following emission
sources are covered:
Vehicle climate change emissions comprise
four main elements (1) CO2, CH4, and N2O
emissions resulting directly from the
operation of the vehicle, (2) CO2 emissions
resulting from operating the air conditioning
system (indirect AC emissions), (3)
refrigerant emissions from the air
conditioning system due to either leakage,
losses during recharging, sudden releases due
to accidents, or release from scrappage of the
vehicle at the end of life (direct AC
emissions), and (4) upstream emissions
associated with the production of the fuel
used by the vehicle. The climate change
emission standard incorporates all of these
elements.225
production and transportation of the
fuel used by the vehicle).226
More particularly, under the CARB
regulation, for each GHG vehicle test
group, a manufacturer shall calculate
both a ‘‘city’’ grams per mile average of
CO2 equivalent value and a ‘‘highway’’
grams per mile average of CO2
equivalent value.227 The use of CO2
equivalence is an approximation that
CARB used to place the gases included
in CARB’s definition of greenhouse gas
on the same scale so that they could be
added together. CARB based this on a
statement of global warming
potential: 228
For vehicles certified on conventional
fuels (e.g., gasoline), CARB’s regulation
does not encompass upstream emissions
(i.e., emissions associated with the
Where:
GHG = CO2-equivalent greenhouse gas
emission rate (per FTP and highway
tests)
CO2 = tailpipe carbon dioxide emission
rate
N2O = tailpipe nitrous oxide emission
rate
CH4 = tailpipe methane emission rate
DACdirect = credit for reducing direct
emissions from air conditioning
system (refrigerant emissions from
the air conditioning system)
DACindirect = credit for reducing indirect
emissions from air conditioning
system use CO2 emissions resulting
from operating the air conditioning
system,
As detailed in its ‘‘Initial Statement of
Reasons,’’ CARB estimates
demonstrated that of the total covered
GHG emissions, vehicle tailpipe CO2
TABLE 22.—GWP VALUES FROM
CARB INITIAL STATEMENT OF REASONS, P. 48
Greenhouse gas compound
Global
warming
potential
Carbon Dioxide .........................
Methane ....................................
Nitrous Oxide ............................
HFC 134a .................................
HFC 152a .................................
1
23
296
1300
120
Under the CARB GHG regulation, the
basic calculation of a given vehicle
model’s GHG emission rate is as
follows: 229
CO2 equivalent value = CO2 + 296 × N2O
+ 23 × CH4 ¥ A/C Direct Emissions
Allowances ¥ A/C Indirect
Emissions Allowances.
This calculation may be expressed as
follows:
emissions would be a much larger
component than CO2-equivalent
baseline emission rates for all the other
components combined. The following
table shows CARB’s estimates of the
baseline emission rate for each covered
GHG component 230 (column 2) along
with the NHTSA’s arithmetic
calculation of corresponding shares of
baseline emissions reported by CARB
(column 3).
TABLE 23.—CARB ESTIMATES OF BASELINE GREENHOUSE GAS EMISSION RATES
Rate (CO2equiv. g/mi)
CO2 emissions resulting directly from the operation of the vehicle ........................................................................
CH4 emissions resulting directly from the operation of the vehicle ........................................................................
N2O emissions resulting directly from the operation of the vehicle ........................................................................
225 California Environmental Protection Agency,
Air Resources Board, Regulations To Control
Greenhouse Gas Emissions From Motor Vehicles,
Final Statement Of Reasons (FSOR), at 7–8.
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226 CARB,
FSOR at 8.
CCR 1961.1(a)(1)(B)1.a.
228 The global warming potential is a relative
index used to compare the climate impact of an
227 13
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291–512
0.1
1.8
Calculated
share (percent
total)
92–95
0.02–0.03
0.3–0.6
emitted greenhouse gas, relative to an equal amount
of carbon dioxide.
229 Ibid.
230 CARB
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TABLE 23.—CARB ESTIMATES OF BASELINE GREENHOUSE GAS EMISSION RATES—Continued
Rate (CO2equiv. g/mi)
GHG emissions component
CO2 emissions resulting from operating the air conditioning system .....................................................................
Refrigerant emissions from the air conditioning system .........................................................................................
13.5–19.0
8.5
Calculated
share (percent
total)
4
2–3
which reduces, with rounding, to:
emissions resulting directly from
vehicle operation would be 285 and 408
grams per mile, respectively:
GHG regulation primarily by applying
technologies that increase fuel economy.
With only one exception—
improvements to air conditioning
systems—those technologies would
have a parallel impact on fuel economy
as measured for purposes of
determining compliance with federal
fuel economy standards.237 For
purposes of determining compliance
with federal CAFE standards, testing is
run with the air conditioning turned off.
Thus, the federal CAFE rules do not
‘‘credit’’ improved air conditioning
efficiency or reduced losses from air
conditioners. CARB has included
reductions in emissions associated with
air conditioning (direct and indirect) in
its GHG regulation, so the technologies
it relies upon are in this one limited
respect broader than those NHTSA
relies on. However, those technologies
are nevertheless fuel economy
technologies in that they reduce CO2
emissions by reducing the load on a
vehicle’s engine and in turn reduce fuel
consumption. Further, air conditioning
improvements are not the predominant
factor in reducing CO2-equivalent
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Therefore, for a typical light truck, the
term representing CO2 emissions that
are also subject to regulation under
federal CAFE standards (in the above
equation, the term labeled ‘‘CO2 term’’)
would have a magnitude about 200
times that of the term representing its
other emissions (‘‘non-CO2 term’’ in the
above), and about 20 times that of the
term account for improvements to its air
conditioning system (‘‘AC term’’ in the
above). Consistent with CARB’s
estimate, discussed above, that tailpipe
CO2 emissions dominate total GHG
emissions considered by CARB, this
calculation indicates that CO2 emissions
account for on the order of 95 per cent
(1 ¥22/(401 + 2 + 20) = 0.95) of the
emissions that enter into the calculation
of total GHG emissions under CARB’s
regulation.
Alternatively, using the MY2011
values of CARB’s standards for total
GHG emissions—267 and 390 grams per
mile for lighter and heavier vehicles,
respectively, corresponding CO2
231 A CARB memorandum recognizes that CO
2
emissions are by far the largest amount of emissions
produced by motor vehicles. https://www.arb.ca.gov/
msei/on-road/downloads/pubs/co2final.pdf.
232 13 CCR 1961.1.
233 ISOR at 48.
234 13 CCR § 1961.1(a)(1)(B)1.a.
235 California Code of Regulations, Title 13,
§ 1961.1(a)(1)(B)(1)(b) allows a direct emissions
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Solving these two equations for CO2
yields values of 285 and 408 grams per
mile, respectively. At these rates, CO2
accounts for either 93% (1 ¥22/(285 +
2 + 20) = 0.93) or 95% (1¥22/(408 + 2
+ 20) = 0.95) of the emissions that enter
into the calculation of total GHG
emissions under CARB’s regulation.
Just as in the case of compliance with
federal fuel economy standards,
compliance with CARB’s regulation is
largely a function of tailpipe CO2
emissions.236 The same emissions
provide the primary basis for
determining compliance with federal
fuel economy standards. In addition,
CARB’s own analysis anticipates that
manufacturers would comply with its
allowance of up to 9 grams per mile. Section
1961.1(a)(1)(B)(1)(c) allows an indirect emissions
allowance of up to 11 grams per mile.
236 This conclusion follows even if the CO
2
emission rates in the examples are changed
considerably, in line with the baseline estimates in
CARB’s ISOR.
237 As demonstrated above, the CARB regulation
would have the substantially the same effect as the
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Federal fuel economy regulation in terms of many
of the technologies that manufacturers likely would
have to install to meet the requirements. In addition
to covered large trucks, addressed above, CARB’s
ISOR addressed the technologies that likely would
be installed in small trucks and minivans. (ISOR,
pp. 66–7). In general, those technologies are the
same as in the NAS report referred to above.
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per mile for N2O in lieu of actually
measuring emissions of that gas.234 Also
according to the regulation,
manufacturers could be granted as much
as 9 and 11 grams per mile in direct and
indirect emissions allowances,
respectively, for improvements to air
conditioners.235
Therefore, the CO2-equivalent GHG
emission rate for a typical light truck
granted the maximum credit for air
conditioner improvements might be
computed as follows:
ER06AP06.036</GPH>
truck emits 471 g/mi and 316 g/mi of
CO2 on the city and highway test cycles
respectively. Like federal fuel economy
standards, CARB’s GHG regulation
weights these cycles at 55% and 45%
respectively,232 such that representative
CO2 value would be 401 gr/mile for a
MY 2006 light truck. According to
CARB’s ‘‘Initial Statement of
Reasons’’,233 a typical baseline vehicle
emits 0.005 grams per mile of CH4.
Under the regulation, manufacturers
may use a default value of 0.006 grams
ER06AP06.035</GPH>
As is evident from the above table,
CO2 emissions resulting directly from
the operation of the vehicle account for
more than ninety two percent of the
emissions potentially covered by
CARB’s vehicular GHG regulation.231
This demonstrates that CO2 emissions
from the operation of the vehicle are the
predominant factor under CARB’s
greenhouse gas regulation.
This is corroborated by data in the
record. As discussed above, a
reasonably representative MY2006 light
Federal Register / Vol. 71, No. 66 / Thursday, April 6, 2006 / Rules and Regulations
emissions under the CARB
regulation.238
CARB’s vehicle greenhouse gas
regulation is, therefore, clearly related to
fuel economy standards 239 and thus
subject to the preemption provision in
EPCA.
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NHTSA Has Also Concluded That
Regulation of Carbon Dioxide Emissions
From Motor Vehicles Conflicts With and
Is Impliedly Preempted Under 49 U.S.C.
Chapter 329
Pre-emption principles also provide
that if a state law or regulation stands
as an obstacle to the accomplishment
and execution of the full purposes and
objectives of Congress in enacting a
statute, that law or regulation may be
preempted.240 The presence of an
238 Based on its own analysis of warmingpotential weighted emissions, CARB estimates that
upgrading to a low-leak HFC–152a air conditioning
system or a CO2 system would reduce GHG
emissions by ‘‘approximately 8.5 or 9 CO2equivalent grams per mile, respectively.’’ (ISOR, p.
72). CARB further states that ‘‘upgrading to a VDC
with external controls, air recirculation, and HFC–
152a as the refrigerant, the estimated indirect
emission reduction is 7 CO2-equivalent grams per
mile for a small car, 8 CO2-equivalent grams per
mile for a large car, and 9.8 CO2-equivalent grams
per mile for minivans, small trucks, and large
trucks.’’ (ISOR, p. 75). According to the regulation,
combined direct and indirect emissions allowances
for air conditioners could total as much as CO2equivalent 20 grams per mile. California Code of
Regulations, Title 13, section 1961.1(a)(1)(B)(1)(b)
allows a direct emissions allowance of up to 9
grams per mile. Section 1961.1(a)(1)(B)(1)(c) allows
an indirect emissions allowance of up to 11 grams
per mile.
239 A CARB memorandum recognizes that CO
2
emissions are related to fuel economy. It points out
that CO2 emissions can be modeled to estimate fuel
economy. It also noted in the context of CO2 that
emission rates for vehicles from a certain period
(MY 1990—MY 1997) were assumed to be the same
as the preceding model year (1989) because CAFE
standards did not change dramatically after the
initial model year (MY 1989). https://
www.arb.ca.gov/msei/on-road/downloads/pubs/
co2final.pdf (this document apparently was
prepared in the late 1990s, based on its reference
to the EMFAC7G model, which was approved by
EPA on April 16, 1998.) Similarly, a National
Academies Press (NAP) release on Automotive Fuel
Economy, recognized the relationship between
automotive fuel economy and CO2 emission rates:
‘‘Fuel economy improvements in new light-duty
vehicles will reduce carbon dioxide emissions per
mile because less fuel will be consumed per vehicle
mile driven.’’ https://www.nap.edu/openbook/
0309045304/html/7html. (NAP was created by the
National Academies to publish the reports issued
by the National Academy of Sciences, the National
Academy of Engineering, the Institute of Medicine,
and the National Research Council.) See also NAP
report at https://www.nap.edu/books/0309076013/
html/7.html. In addition, CARB recognized that the
GHG (CO2-equivalent emission standards are
related to fuel economy in another way. CARB
recognized that the standards would result in
savings in reduced operating costs. Those lower
costs are based on lower costs for fuel based on
improved fuel efficiency. (ISOR, p. 196; FSOR, pp.
166, 168).
240 Spriestma v. Mercury Marine, 537 U.S. 51, 64–
5 (2002).
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express preemption provision in a
statute neither precludes nor limits the
ordinary working of conflict preemption principles, particularly in the
absence of a saving clause.241 Therefore,
NHTSA has concluded that these
principles are also fully operative under
EPCA, in addition to its express
preemption provision.
NHTSA has concluded that the State
GHG standard, to the extent that it
regulates tailpipe CO2 emissions, would
frustrate the objectives of Congress in
establishing the CAFE program and
conflict with the efforts of NHTSA to
implement the program in a manner
consistent with the commands of EPCA.
Congress had a variety of interrelated
objectives in enacting EPCA and has
charged NHTSA with balancing and
achieving them. Among them was
improving motor vehicle fuel economy.
To achieve that objective, Congress did
not simply mandate the issuance of fuel
economy standards set at whatever level
NHTSA deemed appropriate. Nor did it
simply say that levels must be set
consistent with the criteria it specified
in Section 32902(f). It went considerably
further, mandating the setting of
standards at the maximum feasible
level.
Other congressional objectives
underlying EPCA include avoiding
serious adverse economic effects on
manufacturers and maintaining a
reasonable amount of consumer choice
among a broad variety of vehicles.
Congress was explicitly concerned that
the CAFE program be carefully drafted
so as to require levels of average fuel
economy that do not have the effect of
either ‘‘imposing impossible burdens or
unduly limiting consumer choice as to
capacity and performance of motor
vehicles.’’ 242 These concerns are
equally applicable to the manner in
which that program is implemented.
To guide the agency toward the
selection of standards meeting these
competing objectives, Congress
specified four factors that NHTSA must
consider in determining which level is
the maximum feasible level of average
fuel economy and thus the level at
which each standard must be set. These
are technological feasibility, economic
practicability, the effect of other
Government standards on fuel economy,
and the need of the Nation to conserve
energy.243 In addition, the agency had
traditionally considered the safety
consequences in selecting the level of
future CAFE standards.
241 Geier
v. Honda, 529 U.S. 861, 869 (2000).
Rep. No. 94–340, 87 (1975).
243 49 U.S.C. 32902(f).
242 H.
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Congress expected the agency to
balance these factors in a fashion that
ensures the standards are neither too
low, nor too high. The Conference
Report for EPCA states that the fuel
economy standards were to be the
product of balancing the benefits of
higher fuel economy levels against the
difficulties individual manufacturers
would face in achieving those levels:
Such determination should take industrywide considerations into account. For
example, a determination of maximum
feasible average fuel economy should not be
keyed to the single manufacturer which
might have the most difficulty achieving a
given level of average fuel economy. Rather,
the Secretary must weigh the benefits to the
nation of a higher average fuel economy
standard against the difficulties of individual
automobile manufacturers. Such difficulties,
however, should be given appropriate weight
in setting the standard in light of the small
number of domestic automobile
manufacturers that currently exist, and the
possible implications for the national
economy and for reduced competition
association [sic] with a severe strain on any
manufacturer. However, it should also be
noted that provision has been made for
granting relief from penalties under Section
508(b) in situations where competition will
suffer significantly if penalties are
imposed.244
NHTSA has concluded that were a
State to establish a fuel economy
standard or de facto fuel economy
standard, e.g., a CO2 emission standard,
it would not choose one that has the
effect of requiring lower levels of
average fuel economy than the CAFE
standards applicable under EPCA or
even one requiring the same level of
average fuel economy. Given that the
only practical way to reduce tailpipe
emissions of CO2 is to improve fuel
economy, such a State standard would
be meaningless since it would not
reduce CO2 emissions to an extent
greater than the CAFE standards.245
Instead, a State would establish a
standard that has the effect of requiring
a higher level of average fuel economy.
Setting standards that are more
stringent than the fuel economy
standards promulgated under EPCA
would upset the efforts of NHTSA to
balance and achieve Congress’s
competing goals. Setting a standard too
high, above the level judged by NHTSA
to be consistent with the statutory
consideration after careful consideration
of these issues in a rulemaking
proceeding, would negate the agency’s
analysis and decisionmaking. NHTSA
makes its judgments only after
considering extensive technical
244 S.
Rep. No. 94–516, 154–155 (1975).
is also EPA’s conclusion. See 68 FR
52922, 52929.
245 This
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information such as detailed product
information submitted by the vehicle
manufacturers and NAS’ report on the
future of the CAFE program and
conducting analyses of potential
impacts on employment and safety.
As noted above, manufacturers
confronted with requirements for the
reduction of tailpipe CO2 emissions
would look at the same pool of
technology used to reduce fuel
consumption. NHTSA concludes that it
is disruptive to the orderly
implementation of the CAFE program,
and to NHTSA’s reasonable balancing of
competing concerns, to have two
different governmental entities assessing
the need to conserve energy,
technological feasibility, economic
practicability, employment, vehicle
safety and other concerns, and making
inconsistent judgments made about how
quickly and how much of that single
pool of technology could and should be
required to be installed consistent with
those concerns. EPCA does not specify
how to weight each concern; thus,
NHTSA determines the appropriate
weighting based on the circumstances in
each CAFE standard rulemaking. More
important, ignoring the judgments made
by NHTSA at the direction of Congress
could result in setting standards at
levels higher than NHTSA can legally
justify under EPCA, increasing the risk
of the harms that that body sought to
avoid, e.g., serious adverse economic
consequences for motor vehicle
manufacturers and unduly limited
choices for consumers.
Through EPCA, Congress committed
the reasonable accommodation of these
conflicting policies and concerns to
NHTSA.246 ‘‘Congress did not prescribe
a precise formula by which NHTSA
should determine the maximallyfeasible fuel economy standard, but
instead gave it broad guidelines within
which to exercise its discretion.’’ 247 A
state’s adoption and enforcement of a
CO2 standard for motor vehicles would
infringe on NHTSA’s discretion to
establish CAFE standards consistent
with Congress’ guidance and threaten
the goals that Congress directed NHTSA
to achieve. The process of achieving
those goals involves great expertise and
care. The fuel economy standards
delegated to NHTSA are to be the
product of balancing the benefits of
higher fuel economy levels against the
difficulties individual manufacturers
would face in achieving those levels.248
As EPA observed in its notice denying
the petition to regulate motor vehicle
CO2 emissions, its issuance of standards
for those emissions would ‘‘abrogate
EPCA’s regime,’’ 249 rendering NHTSA’s
careful balancing of consideration a
nullity. This is equally true for State
standards for those emissions.
There appear to be two
misconceptions that have clouded
proper analysis of these implied
preemption issues. One is that since the
term ‘‘average fuel economy standard’’
is defined in EPCA as meaning ‘‘a
performance standard specifying a
minimum level of average fuel economy
applicable to a manufacturer in a model
year’’ 250 (emphasis added), there can be
no conflict or incompatibility between
CO2 standards and CAFE standards.
Indeed, it has been suggested that in
defining this term in this fashion,
Congress endorsed the setting of other
standards having the effect of regulating
fuel economy.251 NHTSA does not
interpret the statute in this manner,
because EPCA requires that CAFE
standards be set at the maximum
feasible level, consistent with the
agency’s assessment of impacts on the
nation, consumers and industry.
An interpretation that allowed more
stringent State fuel economy standards
would nullify the statutory limits that
Congress placed in EPCA on the level of
CAFE standards, and the efforts of
NHTSA in its CAFE rulemaking to
observe those limits. Congress expressly
listed four analytical, decision guiding
factors in EPCA because fuel economy
was not the only value that Congress
sought to protect and promote in the
mandating the setting of CAFE
standards. Congress did not want
improved fuel economy to come at the
price of adverse effects on sales, jobs,
and consumer choice. Further, in
choosing the level of future CAFE
standards, NHTSA has traditionally
considered the potential impact on
safety.
In selecting the maximum feasible
level, NHTSA strives to set the
standards as high as it can without
causing significant adverse
consequences for the manufacturers or
consumers. Since NHTSA should not, as
a matter of sound public policy, and in
fact may not as a matter of law, set
standards above the level it determines
to be the maximum feasible level, EPCA
should not be interpreted as permitting
the States to do so. Indeed, NHTSA has
concluded that, under EPCA, States may
249 Id.
250 49
U.S.C. 32901(a)(6).
suggestion cannot be reconciled with
Congress’ decision to include an express
preemption provision in EPCA. 49 U.S.C. 32919(a).
246 901
F.2d 107, 120–21.
247 901 F.2d 107, 120–21.
248 793 F.2d 1322, 1338.
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not set actual or de facto fuel economy
standards at any level.
Second, as noted above, regulating
fuel economy and regulating CO2
emissions are inextricably linked, given
current and foreseeable automotive
technology. There are not two different
pools of technology, one for reducing
tailpipe CO2 emissions, and the other
for improving fuel economy. Thus, there
is nothing to be gained by setting both
tailpipe CO2 standards and CAFE
standards.
If the technology does not improve
fuel economy, it does not reduce
tailpipe CO2 emissions. The
technologies listed in Part 5 of CARB’s
Initial Statement of Reasons for its GHG
standard for reducing tailpipe CO2
emissions reduce those emissions by
improving fuel economy.
This dichotomy of perception or
characterization about fuel economy
and CO2 emissions does not appear to
exist in other countries. According to
the International Energy Agency:
The existing approaches for achieving CO2
reduction through fuel economy
improvement in new cars vary considerably,
with both regulatory approaches (China,
Japan, US, CA) and voluntary approaches
(EU). Some systems include financial
incentives as well (Japanese tax credit for
hybrids, U.S. gas guzzler tax, various EU
member country differential taxation
schemes based on fuel economy, such as in
the UK and Denmark).252
Further, in Europe, the studies
conducted for the European
Commission in support of efforts to
provide public information on fuel
economy and CO2 emissions to induce
consumers to purchase vehicles with
lower CO2 emissions uniformly reflect
the view that fuel economy and CO2
emissions are directly related.253
252 FUELING THE FUTURE: Workshop on
Automobile CO2 Reduction and Fuel Economy
Improvement Policies, WORKSHOP REPORT, 13
October, 2004, Shanghai, China, https://
www.iea.org/textbase/work/2004/shanghai/
UNEP_IEA.PDF.
253 RAND Europe, at 4; D. Elst, N. Gense, I.J.
Riemersma, H.C. van de Burgwal, Z. Samaras, G.
Frontaras, I. Skinner, D. Haines, M. Fergusson, and
P. ten Brink, Measuring and preparing reduction
measures for CO2-emissions from N1 vehicles-final
report the European Commission, DirectorateGeneral for Environment, at 90, TNO TPD, (part of
the Netherlands Organisation for Applied Scientific
Research TNO), in partnership with Aristotle
University of Thessaloniki and Institute for
European Environmental Policy, Contract no. B4–
3040/2003/364181/MAR/C1, December 2004
(observing that ‘‘ * * * reduction of CO2 is
equivalent to fuel economy improvement * * * ’’);
and A. Gartner, Study on the effectiveness of
Directive 1999/94/EC relating to the availability of
consumer information on fuel economy and CO2
emissions in respect of the marketing of new
passenger cars, Final report to the European
Commission, Directorate-General for Environment,
Contract No.: 07010401/2004/377013/MAR/C1, at
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Similarly, in 2001, one of the leading
U.S. environmental groups participating
in this rulemaking issued a report that
identified a vehicle’s fuel consumption
rate as the single vehicle design factor
determining the amount of a vehicle’s
CO2 emissions:
The CO2 emitted by a motor vehicle is the
product of three factors: the amount of
driving, the vehicle’s fuel consumption rate
and the carbon intensity of the fuel
consumed. The fuel consumption rate (e.g.,
the number of gallons needed to drive 100
miles) is the inverse of fuel economy (miles
per gallon, or mpg).254
Later, in the same report, it was
observed in a footnote (#26) that ‘‘it is
actual CAFE that determines fuel
consumption and CO2 emissions.’’ 255
EPCA’s Provision Specifying Factors To
Be Considered in Setting Average Fuel
Economy Standards Does Not Limit
Preemption Under 49 U.S.C. Chapter
329
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EPCA does not include any exception
to its preemption provision that would
cover State GHG and CO2 standards.
Nevertheless, some commenters
opposing preemption suggested that
Section 32902(f), which lists the factors
that NHTSA must consider in
determining the level at which to set
fuel economy standards, prevents
preemption by requiring consideration,
by NHTSA, of the effect of other
Government standards, including
emissions standards, on fuel economy.
EPCA’s decisionmaking factor
provision is neither a saving clause nor
a waiver provision. Nor does NHTSA
interpret it as saving state emissions
standards that effectively regulate fuel
economy from preemption. The agency
interprets that provision only to direct
NHTSA to consider those State
standards that can otherwise be validly
adopted and enforced under State and
Federal law.
The decisionmaking factors provision
does reflect an expectation by Congress
that some state emissions standards
would not be preempted under the
express preemption provision. However,
as an initial matter, NHTSA does not
45 and 70, Allgemeine Deutsche Automobil-Club
ADAC e.V., March 2005 (observing ‘‘ * * * that
most consumers are not aware of the correlation of
fuel consumption and CO2 emissions of passenger
cars * * * ’’ and that ‘‘ * * * the CO2 emissions
(g/km) can be calculated from fuel consumption
* * * ’’).
254 J. DeCicco and A. Feng, Automakers’
Corporate Carbon Burden, Reframing Public Policy
on Automobiles, Oil and Climate, at 7–8,
Environmental Defense, 2001. The article explained
that carbon intensity is how much CO2 is emitted
per unit of fuel consumed. For gasoline, this
amounts to 19.4 pounds per gallon. Id. at 8.
255 Ibid, at 22–23.
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read the provision to imply a savings
clause. This is particularly so given that
Congress has considered and provided a
different saving clause, i.e., the one for
a State law or regulation on disclosure
of fuel economy or fuel operating costs
for an automobile.
Moreover, even if EPCA did contain
the saving clause desired by those
commenters, NHTSA would not give it
effect here, as doing so ‘‘would upset
the careful regulatory scheme
established by federal law.’’ 256
First, and most important in this
context, such a reading would upset the
carefully calibrated CAFE regulatory
program under which NHTSA is with
setting CAFE standards at the maximum
feasible level, taking care neither to set
them too high nor too low. Because of
the need to conserve energy, Congress
did not simply mandate the setting of
appropriate fuel economy standards.
Instead, it mandated the setting of
maximum feasible ones. At the same
time, Congress was aware that setting
overly stringent standards would
excessively reduce consumer choice
about vehicle design and performance
and threaten adverse economic
consequences. As noted by EPA in its
Federal Register document denying
ICTA’s petition to regulate CO2
emissions from motor vehicles, the
setting of standards for CO2 tailpipe
emissions would displace NHTSA and
upset EPCA’s regulatory regime for
CAFE.
Second, the requirement to consider
these decisionmaking factors must be
reconciled with the express preemption
provision. NHTSA has concluded that
reading the express preemption
provision in the manner suggested by
commenters opposing preemption
would irrationally limit that provision
and leave NHTSA’s role in
administering the CAFE program open
to a substantial risk of abrogation. By
the same token, in NHTSA’s view, it is
equally important that the ‘‘relates to’’
language in the express preemption
provision should not be given so broad
a reading that even State emissions
standards having only an incidental
effect on fuel economy standards are
deemed to be preempted by it.
NHTSA has concluded that these two
extreme readings, with their
unacceptable impacts on EPCA and on
the Clean Air Act, including its waiving
preemption provision, can be avoided
under a carefully calibrated
interpretation of EPCA’s express
preemption provision that harmonizes
the two acts to the extent possible.
256 Geier v. American Honda Motor Co., 529 U.S.
861, 869 (2000). (Citations omitted.)
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NHTSA does not interpret EPCA’s
express preemption provision as
preempting State emissions standards
that only incidentally or tangentially
affect fuel economy. These standards
include, for example, given current and
foreseeable technology, the existing
emissions standards for CO, HC, NOX,
and particulates. They also include the
limits on sulfur emissions that become
effective in 2007. NHTSA considers
such standards under the
decisionmaking factors provision of
EPCA since, under applicable law, they
can be adopted and enforced and
therefore can have an effect on fuel
economy.
However, two groups of State
emissions standards do not qualify
under NHTSA’s interpretation of the
decisionmaking factors provision, and
therefore would not be considered. One
is State standards that cannot be
adopted and enforced because there has
been no waiver for California under the
preemption waiver provision of the
Clean Air Act. The other is the State
emissions standards that are expressly
or impliedly preempted under EPCA,
regardless of whether or not they have
received such a waiver. Preempted
standards include, for example:
(1) A fuel economy standard; and
(2) A law or regulation that has
essentially all of the effects of a fuel
economy standard, but is not labeled as
one (example: State tailpipe CO2
standard).
This reading of EPCA’s express
preemption provision allows that
provision to function in a consistent
way, without irrational limitation, to
protect the national CAFE program from
interference by any State standard
effectively regulating fuel economy. It
also simultaneously maximizes the
ability of EPCA and the Clean Air Act
to achieve their respective purposes.
NHTSA’s judgment is that the agency
should distinguish between motor
vehicle emission standards for
emissions other than CO2 (e.g., HC, CO,
NOX and PM) and motor vehicle
emission standards for CO2. Those other
emissions are not directly and
inextricably linked to fuel economy.
NHTSA’s current view is that standards
for emissions other than CO2 merely
affect the level of CAFE that is
achievable and thus only incidentally
affect fuel economy standards.
Accordingly, we believe that regulation
of these emissions is not rulemaking
inconsistent with the operation of
preemption principles under EPCA.
HC, CO, and PM all result from
incomplete combustion. Therefore, the
first step toward controlling emissions
of these pollutants involves improving
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the combustion process. Doing so
increases the production and emission
of carbon dioxide. All three pollutants
can also be substantially eliminated
from tailpipe emissions by placing
catalytic converters between the engine
and the tailpipe. Catalytic converters
reduce emissions of these pollutants
through oxidation, which also increases
the production and emission of carbon
dioxide. PM emissions can also be
controlled using PM traps, which
temporarily trap and store PM. PM traps
periodically regenerate by oxidizing
away the stored PM. Doing so increases
the production and emission of carbon
dioxide.
NOX results from the oxidation of
nitrogen at the high peak temperatures
that occur in an efficiently-operating
engine. The exposure of nitrogen to
peak temperatures can be reduced by
increasing turbulence in the combustion
chamber, changing ignition and/or
injection timing, and recirculating some
exhaust gases through the engine.
Increased turbulence and changes to
ignition and/or injection timing tend to
increase the production and emission of
carbon dioxide. Catalytic converters can
substantially eliminate NOX from the
exhaust stream. However, doing so
requires chemical reduction—oxidation
in reverse. Modern catalytic converters
perform both reduction and oxidation,
reducing NOX to oxidize HC and CO,
and further oxidizing HC and CO with
oxygen available in the exhaust stream.
These processes increase the production
and emission of carbon dioxide.
Gasoline vehicles also emit HC
through the evaporation of fuel. These
emissions are controlled using canisters
that temporarily store evaporated fuel.
Periodically, these canisters are purged,
releasing the stored fuel vapors to the
engine to be combusted. Compared to
simply releasing evaporative emissions
to the atmosphere, these processes
increase the formation and emission of
carbon dioxide.
To summarize, the processes used to
control HC, CO, NOX, and PM emissions
increase the formation and emission of
carbon dioxide. Because carbon dioxide
is, like water, an ultimate byproduct of
combustion, it cannot be further
converted on the vehicle to some other
compound through any practical means.
Plants use sunlight to convert carbon
dioxide and water to biomass (and
oxygen) through photosynthesis, but
vehicles produce far too much exhaust
to be consumed by plants that could
conceivably be sustained by the amount
of sunlight to which vehicles are
exposed. Even if enough sunlight were
available, biomass would be produced
at a rate requiring impractically frequent
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removal from the vehicle. Theoretically,
on-board scrubbers could be used
separate carbon dioxide from the
exhaust stream. Chemical processes for
removing carbon dioxide are currently
used in underwater rebreathers and
space applications (e.g., the
international space station), and are
contemplated for stationary applications
(e.g., electric utilities). (See, e.g., https://
www.nas.nasa.gov/About/Education/
SpaceSettlement/teacher/course/
co2.html, https://www.frogdiver.com,
and https://www.netl.doe.gov/
publications/proceedings/01/
carbon_seq/5a5.pdf.) However, for a
variety of reasons (e.g., size, cost, energy
demands, use of dangerous reactants
such as calcium hydroxide), these
processes would not be even remotely
practical for motor vehicles.
Even if a practical process to separate
carbon dioxide from the exhaust stream
were available, the carbon dioxide
would, to prevent its release, need to be
compressed or solidified for temporary
onboard storage, and frequently
removed for disposal (e.g., in
underground facilities). For example if
fifteen gallons of gasoline are added at
each refueling of a vehicle, about 290
pounds of carbon dioxide (or, without
any separation of the carbon dioxide,
about 1,400 pounds of exhaust gases)
would be produced through the
combustion of that fuel. (This example
assumes gasoline with a density of 6
pounds per gallon and a carbon content
(by mass) of 87%. Each pound of carbon
dioxide contains 0.273 pounds of
elemental carbon. The combustion of 1
pound of gasoline requires about 14.7
pounds of air.) At these rates of
production, no practical means of
onboard storage and periodic removal
are foreseeable.
For these reasons, a CO2 emissions
standard stands apart from those other
emissions standards. NHTSA has
concluded that such a standard
functions as a fuel economy standard,
given the direct relationship between a
vehicle’s fuel economy and the amount
of CO2 it emits. In contrast, no such
relationship exists between a vehicle’s
fuel economy and the emissions
currently regulated by EPA.
Interpreting EPCA’s preemption
provision as preempting only those
State regulations that directly regulate
or have the effect of directly regulating
fuel economy gives, to the extent
possible, maximum effect both to EPCA
and to the preemption waiver provision
in the Clean Air Act. This is necessary
and appropriate, especially considering
the importance of the goals of the Clean
Air Act and the attention paid by
Congress in drafting EPCA to the
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relationship of the CAFE program to the
Clean Air Act. EPCA’s express
preemption provision cannot be
interpreted as preempting all State laws
relating to a fuel economy standard, no
matter how tangential the relationship.
Such an interpretation would largely, if
not wholly, negate the Clean Air Act’s
preemption waiver provision and leave
few, if any, emission standards to be
considered by NHTSA under EPCA’s
decisionmaking factor provision. Our
approach to reconciling EPCA and the
Clean Air Act appropriately
distinguishes between emissions other
than CO2 and CO2. The Clean Air Act
authorizes the States to regulate
emissions other than CO2, but not CO2
itself, because of the nature of
combustion and the availability of
different technologies for regulating
those other emissions.
Our approach also avoids interpreting
EPCA’s express preemption provision so
narrowly as to produce the absurd and
destructive result of preempting State
fuel economy standards, but not State
standards that are fuel economy
standards in effect, but not in name.
Giving EPCA this degree of primacy is
particularly appropriate given the
regulatory authority in this statute is
quite narrow and specific: fuel economy
standards, and their functional
equivalents, CO2 standards and GHG
standards, to the extent that the latter
regulate CO2 emissions.
XV. Rulemaking Analyses and Notices
A. Executive Order 12866 and DOT
Regulatory Policies and Procedures
Executive Order 12866, ‘‘Regulatory
Planning and Review’’ (58 FR 51735,
October 4, 1993), provides for making
determinations whether a regulatory
action is ‘‘significant’’ and therefore
subject to OMB review and to the
requirements of the Executive Order.
The Order defines a ‘‘significant
regulatory action’’ as one that is likely
to result in a rule that may:
(1) Have an annual effect on the
economy of $100 million or more or
adversely affect in a material way the
economy, a sector of the economy,
productivity, competition, jobs, the
environment, public health or safety, or
State, local or Tribal governments or
communities;
(2) Create a serious inconsistency or
otherwise interfere with an action taken
or planned by another agency;
(3) Materially alter the budgetary
impact of entitlements, grants, user fees,
or loan programs or the rights and
obligations of recipients thereof; or
(4) Raise novel legal or policy issues
arising out of legal mandates, the
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President’s priorities, or the principles
set forth in the Executive Order.
The rulemaking adopted in this
document is economically significant.
Accordingly, OMB reviewed it under
Executive Order 12866. The rule is also
significant within the meaning of the
Department of Transportation’s
Regulatory Policies and Procedures.
We estimate that the total benefits
under the Unreformed CAFE standards
for MYs 2008–2010 and the Reformed
CAFE standard for MY 2011 will be
approximately $7,554 million at a 7
percent discount rate and at fuel prices
(based on EIA long-term projections)
ranging from $1.96 to $2.39 per gallon:
$577 million for MY 2008, $1,876
million for MY 2009, $2,109 million for
MY 2010, and $2,992 million for MY
2011. We estimate that the total costs
under those standards, as compared to
the MY 2007 standard of 22.2 mpg, will
be a total of $6,440 million: $536
million for MY 2008, $1,621 million for
MY 2009, $1,752 million for MY 2010,
and $2,531 million for MY 2011.
Under the Reformed CAFE standards
for MYs 2008–2011, as compared to the
MY 2007 standard of 22.2 mpg, we
estimate the total benefits under the
Reformed CAFE system for MYs 2008–
2011 at $8,125 million: $782 million for
MY 2008, $2,015 million for MY 2009,
$2,336 million for MY 2010, and $2,992
million for MY 2011. We estimate the
total costs to be similar to the total costs
under the Unreformed CAFE system,
$6,711 million: $553 million for MY
2008, $1,724 million for MY 2009,
$1,903 million for MY 2010, and $2,531
million for MY 2011.
Because the final rule is significant
under both the Department of
Transportation’s procedures and OMB’s
guidelines, the agency has prepared a
Final Regulatory Impact Analysis and
placed it in the docket and on the
agency’s Web site.
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B. National Environmental Policy Act
Consistent with the requirements of
the National Environmental Policy Act
(NEPA),257 the regulations of the
Council on Environmental Quality,258
and relevant DOT regulations and
orders,259 the agency has prepared a
final Environmental Assessment (EA) of
this action and concludes that this
rulemaking action will not have a
significant effect on the quality of the
human environment. Both the final EA
257 42
U.S.C. 4321 et seq.
CFR part 1500.
259 49 CFR part 520, DOT Order 5610.1C, and
NHTSA Order 560–1.
258 40
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and a Finding of No Significant Impact
(FONSI) have been placed in the docket.
In comments on the draft EA, the
Attorneys General and the Center for
Biological Diversity challenged the
adequacy of the environmental analysis
performed by the agency. These
commenters stated that the agency is
required to prepare an EIS.
The agency disagrees that an EIS was
required. Although not required to do so
under NEPA, the agency first published
a draft EA for comment, and carefully
reviewed all comments.260 Appropriate
adjustments have been made in the final
EA.
Based on the analysis in the final EA,
which led to a determination that this
rulemaking action will not have a
significant effect on the quality of the
human environment, the agency
determined that it was not required to
prepare an Environmental Impact
Statement (EIS). The function of an EA
is to present and analyze various
alternatives so that an agency can
consider the environmental concerns
related to a particular action and other
possible actions ‘‘while reserving
agency resources to prepare full EISs for
appropriate cases.’’ Sierra Club v. DOT,
753 F.2d 120, 126 (D.C. Cir. 1985). An
EIS is required only when an agency has
first determined that a major federal
action will ‘‘significantly affect [] the
quality of the human environment.’’ 42
U.S.C. 4332(2)(C). See also Sierra Club,
753 F.2d at 126, Town of Cave Creek,
Arizona v. FAA, 325 F.3d 320, 327 (D.C.
Cir. 2003) and Fund for Animals v.
Thomas, 127 F.3d 80, 83 (D.C. Cir.
1997). This limitation reflects the
courts’ awareness of the time and
expense involved in the preparation of
an EIS. See River Road Alliance v. Corps
of Engineers of the United States Army,
764 F.2d 445, 449 (7th Cir. 1985) (the
decision to prepare an EIS is based on
‘‘whether the time and expense of
preparing an environmental impact
statement are commensurate with the
likely benefits from a more searching
evaluation than an environmental
assessment provides’’) and Metropolitan
Edison Co. v. People Against Nuclear
Energy, 460 U.S. at 766, 776 (1983)
(noting scarcity of time and resources in
limiting the scope of NEPA review). The
agency conducted a careful inquiry and
assessed the potential environmental
impacts of a variety of alternatives
including the action adopted in this
final rule. With respect to each
alternative, the agency determined that
260 None of the commenters provided specific
data to indicate that impacts from the proposed
rule, final rule, or considered alternatives, would be
significant.
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17671
projected impacts would be very small
and generally constitute improvements
compared to the baseline for this
rulemaking.261
The Attorneys General and the Center
for Biological Diversity stated that the
agency did not consider a reasonable
number of alternatives, and therefore
did not take the requisite ‘‘hard look’’
when analyzing environmental
impacts.262 In particular, they asserted
that Reformed CAFE creates incentives
for manufacturers to build larger
vehicles, ‘‘which will jeopardize air
quality and the climate’’ and that
NHTSA did not ‘‘consider the
environmental impact of its choices or
the possibility of making other choices.’’
In determining the impacts of this
rulemaking, the agency analyzed a
reasonable number of alternative
actions, as required under NEPA. As the
Supreme Court has recognized, an
agency is required to examine only
reasonable alternatives, not those that
might result in the worst-case scenario
and that are unlikely to occur. See
Robertson v. Methow Valley Citizens
Council, 490 U.S. 332, 354–55 (1989).
The agency recognizes that numerous
alternatives exist, including alternatives
with more stringent fuel economy
requirements.263 However, the agency
did not analyze these alternatives in the
final EA because we determined from
our analytical model that they would
not be consistent with the statutory
criteria of EPCA. We note that the
agency is required to set fuel economy
standards at the ‘‘maximum feasible’’
levels achievable by manufacturers in
the applicable model years, taking into
consideration four statutory factors:
Technological feasibility; economic
practicability; the impact of other
Federal standards on fuel economy; and
the need of the nation to conserve
261 See Section 4 Environmental Consequences, in
the final EA, which has been placed in the docket
for this rulemaking.
262 The term ‘‘hard look’’ refers to whether the
agency fully evaluated, rather than cursorily
examined, a particular issue. See Marsh v. Oregon
Natural Resources Council, 490 U.S. 360, 374
(1989). Elements of a hard look include whether an
agency demonstrated that ‘‘it had responded to
significant points made during the public comment
period, had examined all relevant factors, and had
considered significant alternatives to the course of
action ultimately chosen.’’ Merrick B. Garland,
Deregulation and Judicial Review, 98 Harv. L. Rev.
505, 526 (1985). See also Home Box Office v. FCC,
567 F.2d 9, 35 (D.C. Cir.) (requiring agencies to
consider all relevant factors and demonstrate a
‘‘rational connection between the facts found and
the choice made’’) (citing Burlington Truck Lines v.
United States, 311 U.S. 156, 168 (1962)), cert.
denied, 434 U.S. 829 (1977).
263 Commenters suggested that the agency
consider more stringent standards, but provided no
substantive data to support the general assertion
that unspecified, but more stringent, standards be
adopted.
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energy. EPCA does not permit the
agency to establish fuel economy
standards at any chosen level, but
instead requires NHTSA to balance
these factors when setting an
appropriate standard. For example, a
fuel economy standard ‘‘with harsh
economic consequences for the auto
industry * * * would represent an
unreasonable balancing of EPCA’s
policies.’’ Center for Auto Safety v.
NHTSA, 793 F.2d 1322, 1340 (D.C. Cir.
1986).
The evaluated alternatives represent
standards set under the traditional
Unreformed CAFE process and under
the marginal cost-benefit analysis
previously described. These alternatives
analyzed by the agency, which are
described in greater detail in the final
EA (see EA pp. 8–15), represent options
that were reasonable, given the agency’s
authority under EPCA. All of these
options were projected to result
primarily in small emission reductions.
We evaluated the selected alternatives
against a reasonable baseline and we
have evaluated the estimated
cumulative impacts resulting from the
alternative ultimately adopted in the
final rule.264 The alternative adopted
today reflects the technological
capabilities of the industry within the
applicable time frame and does not
result in harsh economic consequences
for the industry. After carefully
considering the statutory criteria, the
agency has determined that the
standards adopted today represent the
‘‘maximum feasible’’ levels achievable
by manufacturers.265
264 While a baseline typically represents the
impact that would occur if an agency took no action
(i.e., if NHTSA did not establish standards at all for
MYs 2008–2011), 49 U.S.C. § 32902(a) precludes
this possibility by affirmatively requiring the
Secretary of Transportation to prescribe, by rule,
average fuel economy standards for light trucks—
in other words, the agency must promulgate some
standard to apply to light trucks. For these
purposes, we chose to use the MY 2007 (22.2 mpg)
standard as the baseline to assess the impacts of the
various alternatives.
265 Separately, NRDC provided several scenarios
purportedly demonstrating the impact of upsizing
on fleet-wide fuel economy. While the agency does
not agree that the scenarios presented by NRDC are
probable, we note that the fleet-wide fuel economy
estimates for each one remains within the range of
alternatives considered in the Environmental
Assessment. That is, under NRDC’s analysis, the
fleet-wide fuel economy was not lower than the No
Action Alternative evaluated in the final EA.
Additionally, as discussed in the final EA, the range
of impacts from the considered alternatives is very
narrow and minimal. The projections for each of the
alternatives examined by the agency indicated that
none of them would result in a significant impact.
An agency is only required to examine reasonable
alternatives, not those that might result in the
worst-case scenario and that are unlikely to occur.
See Robertson v. Methow Valley Citizens Council,
490 U.S. 332, 354–55 (1989).
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Further, we considered, but did not
evaluate, an alternative that would
incorporate a backstop or ratcheting
mechanism. There are several reasons
for not including such a mechanism
within the context of the Reformed
CAFE system that we are adopting
today. The suggestion that NHTSA must
incorporate a backstop does not
consider the fact, noted above several
times, that CAFE does not command
that NHTSA, in administering the CAFE
program, either to ignore or seek to
preclude mix shifts and design changes
made due to consumer demand. NHTSA
has traditionally considered consumer
demand in setting new CAFE standards
and likewise has considered it as
necessary and appropriate in amending
existing standards. The proponents of a
backstop did not consider that the
proposed Reformed CAFE system
minimized the incentive for
manufacturers to upsize vehicles. The
Reformed system adopted in this final
rule reduces that incentive even more.
Further, manufacturers are limited in
their ability to increase vehicle size by
consumer demand and by other market
forces, such as potential fuel prices.
Adoption of a backstop would also
undermine the benefits of attributebased standards for some manufacturers
and perpetuate the shortcomings of the
Unreformed system.
The Attorneys General also expressed
concern about the potential for vehicle
upsizing and stated that the agency
should analyze the impact on fuel
savings that would occur if
manufacturers enlarged their vehicles,
making them subject to a less stringent
requirement. As explained above, the
agency chose footprint as the vehicle
metric on which to base the standard
because it would be difficult for
manufacturers to make short term
adjustments solely in response to the
fuel economy levels. We based our
analysis on manufacturer product plans,
which reflect vehicle designs through
MY 2011. As also explained above,
footprint is closely tied to a vehicle’s
platform, which manufacturers typically
rely upon without change for a multiyear product cycle.
The Center for Biological Diversity
argued that the agency did not properly
analyze the cumulative impacts of the
light truck rule relative to greenhouse
gas emissions and global warming. The
commenter asserts that past, present and
future actions must be adequately
catalogued and considered, including a
list and description of ‘‘sources of
United States [greenhouse gas]
emissions by category and percent of the
total to place the [greenhouse gas]
emissions into perspective.’’ The Center
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for Biological Diversity also stated that
the agency needs a full understanding of
how its proposed action impacts the
overall ability of the U.S. to reduce its
greenhouse gas emissions.
In the final EA, the agency has
provided a discussion of the greenhouse
gas emissions in the U.S. transportation
sector, as well as in the U.S. generally,
based on available data (see EA pp. 21,
31). Although the commenters urge the
agency to promulgate a standard that
results in larger reductions in CO2
emissions, such a course of action
would not be consistent with the EPCA
constraints discussed earlier. The extent
of NHTSA’s analysis is dictated by the
goals and requirements of EPCA.
Metropolitan Edison Co., 460 U.S. at 776
(noting that ‘‘[t]he scope of the agency’s
inquiries must remain manageable if
NEPA’s goal of ‘ensur[ing] a fully
informed and well considered decision’
* * * is to be accomplished.’’)
(citations omitted). The agency
considered the impacts to greenhouse
gas emissions from fuel economy
standards set according to the statutory
directive of EPCA. Moreover, as
illustrated in the final EA, all of the
analyzed alternatives were projected to
reduce CO2 emissions (see EA p. 30).
The commenters also contend that the
agency has not taken into account
changed circumstances that have
occurred since the last EIS was
completed. In addition to citing the
passage of time since the agency last
prepared an EIS for the CAFE program,
commenters said that higher gas prices,
heightened concerns about foreign oil
dependence, climate changes, and
advances in hybrid technologies
constitute ‘‘changed circumstances’’ that
dictate a full evaluation of
environmental impacts in an EIS.
While we appreciate that changes
have occurred since the last EIS was
performed, we note that there must be
sufficient information to show that this
action will affect the quality of the
human environment ‘‘in a significant
manner or to a significant extent not
already considered’’ to require an EIS.
Further, as explained in the FRIA,
higher gasoline prices were factored into
the model relied on by the agency (see
FRIA p. VIII–26). The incorporation of
hybrid technology is addressed
elsewhere in this notice and in the FRIA
(see FRIA p. V–12). Consideration of the
nation’s dependence on foreign oil
raises policy questions that lie outside
the scope of NEPA. We address that
matter elsewhere in this notice.
The setting of the MY 2005–2007 light
truck standards in April 2003 (68 FR
16868) was the agency’s first effort to set
CAFE standards since the lifting of prior
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Congressional restrictions (other than
the ministerial setting of standards at
already prescribed levels during the
intervening years). Based on the EA for
that action,266 the agency concluded
that no significant environmental
impact would result from the rule. As
explained in the MY 2005–2007 EA, we
believe that adopting that approach in
that rulemaking action is consistent
with our prior evaluations assessing the
impacts of changes to CAFE.
The final EA in the current action also
considered the effects of the different
alternatives on nonattainment areas as
well as on those areas that could be at
risk of nonattainment status (see EA p.
31). The agency determined that the
changes projected from the various
alternatives that were considered would
not increase the risk of any geographic
areas incurring nonattainment status. As
the projections in the final EA show, the
levels of criteria pollutants are expected
to decrease, with the exception of CO,
and the projected increases in CO are
not sufficient to result in an increase in
nonattainment areas (see EA p. 30).
NRDC and the Center for Biological
Diversity stated that the agency did not
consider the impacts of the regulation
on human health and endangered
species. The final EA addresses human
health issues. The final EA
demonstrates that the changes in the
emissions of criteria pollutants are not
projected to result in any additional
violations of the primary air standards,
which are set at levels intended to
protect against adverse effects on human
health (see EA p. 31).
With regard to endangered species,
the commenters expressed concern
about the potential impact of increased
greenhouse gas emissions and global
warming on various species and their
habitat. We first note that the
Endangered Species Act does not
require review in every instance that
could have an impact on a particular
endangered or threatened species,
however remote. 16 U.S.C. 1531 et seq.
Rather, review is triggered in instances
where it is likely that such an impact
will occur. See Babbitt v. Sweet Home
Chapter of Communities for a Great
Oregon, 515 U.S. 687, 703 (1995). As
noted in the final EA, the agency
projected that the final rule would
produce, compared to U.S. emissions of
CO2, a small decrease in emissions of
CO2, the primary component of
greenhouse gas emissions, under the
selected alternative (see EA p. 32).
Accordingly, the agency determined
266 See Docket NHTSA–2002–11419–18360 (Final
Environmental Assessment for MY 2005–2007 Light
Truck CAFE Standards).
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that the action we are adopting today
will not have a significant impact on the
environment.
In addition to commenting on the EA,
the Center for Biological Diversity
asserted that the Global Change
Research Act (GCRA) requires the
agency to rely on specific research in
our analysis. The agency disagrees. The
GCRA calls for the publication of a
study on the effects of global climate
changes every four years and to make
these research findings available to
agencies to use. It does not mandate,
however, that Federal agencies rely on
the research report. Instead, the statute
only imposes a requirement that the
report be made available to agencies.
See 15 U.S.C. 2938 (ensuring that
research findings are made available for
use by Federal agencies in formulating
policies addressing human-induced and
natural processes of global change).
C. Regulatory Flexibility Act
Pursuant to the Regulatory Flexibility
Act (5 U.S.C. 601 et seq., as amended by
the Small Business Regulatory
Enforcement Fairness Act (SBREFA) of
1996), whenever an agency is required
to publish a notice of rulemaking for
any proposed or final rule, it must
prepare and make available for public
comment a regulatory flexibility
analysis that describes the effect of the
rule on small entities (i.e., small
businesses, small organizations, and
small governmental jurisdictions). The
Small Business Administration’s
regulations at 13 CFR part 121 define a
small business, in part, as a business
entity ‘‘which operates primarily within
the United States.’’ (13 CFR 121.105(a)).
No regulatory flexibility analysis is
required if the head of an agency
certifies the rule will not have a
significant economic impact on a
substantial number of small entities.
I certify that the final rule will not
have a significant economic impact on
a substantial number of small entities.
The following is the agency’s statement
providing the factual basis for the
certification (5 U.S.C. 605(b)).
The final rule directly affects fourteen
single stage light truck manufacturers.
According to the Small Business
Administration’s small business size
standards (see 5 CFR 121.201), a single
stage light truck manufacturer (NAICS
code 336112, Light Truck and Utility
Vehicle Manufacturing) must have 1,000
or fewer employees to qualify as a small
business. None of the affected single
stage light truck manufacturers are small
businesses under this definition. All of
the manufacturers of light trucks have
thousands of employees. Given that
none of the businesses directly affected
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are small business for purposes of the
Regulatory Flexibility Act, a regulatory
flexibility analysis was not prepared.
D. Executive Order 13132 Federalism
Executive Order 13132 requires
NHTSA to develop an accountable
process to ensure ‘‘meaningful and
timely input by State and local officials
in the development of regulatory
policies that have federalism
implications.’’ The Order defines the
term ‘‘Policies that have federalism
implications’’ to include regulations
that have ‘‘substantial direct effects on
the States, on the relationship between
the national government and the States,
or on the distribution of power and
responsibilities among the various
levels of government.’’ Under the Order,
NHTSA may not issue a regulation that
has federalism implications, that
imposes substantial direct compliance
costs, and that is not required by statute,
unless the Federal government provides
the funds necessary to pay the direct
compliance costs incurred by State and
local governments, or NHTSA consults
with State and local officials early in the
process of developing the proposed
regulation. The agency has complied
with Order’s requirements.
The issue of preemption of State
emissions standard under EPCA is not
a new one; there is an ongoing dialogue
regarding the preemptive impact of
CAFE standards whose beginning predates this rulemaking. This dialogue has
involved a variety of parties (i.e., the
States, the federal government and the
public) and has taken place through a
variety of means, including rulemaking.
This issue was explored in the litigation
over the California ZEV regulations in
2002 (in which the federal government
filed an amicus brief) and addressed at
great length in California’s 2004–2005
rulemaking proceeding on its GHG
regulation.267 NHTSA first addressed
the issue in its rulemaking on CAFE
standards for MY 2005–2007 light
trucks.
In the current rulemaking proceeding,
we sought again to engage the public in
a discussion of the relationship between
CAFE standards and State CO2
standards and the applicability of
EPCA’s preemption provision to the
latter. In response to our discussion of
preemption in the August 2005 NPRM,
the agency received communications
from a variety of States and their
representative organizations.
States objected generally to the
preemption discussion in the NPRM.
CARB, New Jersey Department of
Environmental Protection, New York
267 FSOR,
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Department of Environmental
Conservation, STAPPA/ALAPCO,
NESCAUM, and the Attorneys General
(California et al.) each stated that the
preemption discussion was irrelevant or
beyond the scope of the light truck
CAFE rulemaking. These commenters
requested that the agency not address
this issue in the final rule. The
Connecticut Department of
Environmental Protection, Pennsylvania
Department of Environmental
Protection, and STAPPA/ALAPCO
made similar requests. These
commenters also asserted that the issue
of preemption should be left to the
courts.
The Attorneys General (California et
al.) stated that Executive Order 13132
directs the agency to be ‘‘deferential to
States when taking action that affects
the policymaking discretion of the
States and should act only with the
greatest caution where State or local
governments have identified
uncertainties regarding the
constitutional or statutory authority of
the national government.’’
We have carefully considered these
comments, as well as closely examined
our authority and obligations under
EPCA and that statute’s express
preemption provision. For those
rulemaking actions undertaken at an
agency’s discretion, Section 3(a) of
Executive Order 13132 instructs
agencies to closely examine their
statutory authority supporting any
action that would limit the
policymaking discretion of the States
and assess the necessity for such action.
This is not such a rulemaking action.
NHTSA has no discretion not to issue
the CAFE standards established by this
final rule. EPCA mandates that the
‘‘Secretary of Transportation * * *
prescribe by regulation average fuel
economy standards’’ for light trucks (49
U.S.C. 32902). Given that a State CO2
regulation is the functional equivalent
of a CAFE standard, there is no way that
NHTSA can tailor a fuel economy
standard for light trucks so as to avoid
preemption. Further, EPCA itself
precludes a State from adopting or
enforcing a law or regulation related to
fuel economy (49 U.S.C. 32919(a)).
For these reasons and those stated at
greater length in the section above on
preemption, we have not adopted the
views presented by the States.
Nevertheless, the agency continues to
examine these issues and welcomes
continued input.
E. Executive Order 12988 (Civil Justice
Reform)
Pursuant to Executive Order 12988,
‘‘Civil Justice Reform’’ (61 FR 4729,
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February 7, 1996), the agency has
considered whether this rulemaking
will have any retroactive effect. This
final rule does not have any retroactive
effect.
F. Unfunded Mandates Reform Act
Section 202 of the Unfunded
Mandates Reform Act of 1995 (UMRA)
requires Federal agencies to prepare a
written assessment of the costs, benefits,
and other effects of proposed or final
rules that include a Federal mandate
likely to result in the expenditure by
State, local, or tribal governments, in the
aggregate, or by the private sector, of
more than $100 million in any one year
(adjusted for inflation with base year of
1995 to $115 million for 2003). All cost
estimates in the FRIA are in 2003
economics. Before promulgating a rule
for which a written statement is needed,
NHTSA is generally required by section
205 of the UMRA to identify and
consider a reasonable number of
regulatory alternatives and adopt the
least costly, most cost-effective, or least
burdensome alternative that achieves
the objectives of the rule. The
provisions of section 205 do not apply
when they are inconsistent with
applicable law. Moreover, section 205
allows NHTSA to adopt an alternative
other than the least costly, most costeffective, or least burdensome
alternative if the agency publishes with
the final rule an explanation why that
alternative was not adopted.
This final rule will not result in the
expenditure by State, local, or tribal
governments, in the aggregate, of more
than $115 million annually, but it will
result in the expenditure of that
magnitude by vehicle manufacturers
and/or their suppliers. In promulgating
this proposal, NHTSA considered
whether average fuel economy
standards lower and higher than those
proposed would be appropriate. NHTSA
is statutorily required to set standards at
the maximum feasible level achievable
by manufacturers and has tentatively
concluded that the proposed standards
are the maximum feasible standards for
the light truck fleet for MYs 2008–2011
in light of the statutory considerations.
G. Paperwork Reduction Act
Under the procedures established by
the Paperwork Reduction Act of 1995
(44 U.S.C. 3501 et seq.), a person is not
required to respond to a collection of
information by a Federal agency unless
the collection displays a valid OMB
control number. For the transition
period reporting requirements, and the
additional pre-model year reporting
requirements, NHTSA is submitting to
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OMB a request for approval of the
following collection of information.
In compliance with the Paperwork
Reduction Act, this notice announces
that the Information Collection Request
(ICR) abstracted below has been
forwarded to the Office of Management
and Budget (OMB) for review and
comment. The ICR describes the nature
of the information collections and their
expected burden. This is a request for an
amendment of an existing collection.
Agency: National Highway Traffic
Safety Administration (NHTSA).
Title: 49 CFR Part 537, Automotive
Fuel Economy Reports (F.E.) Reports
Type of Request: Amended collection.
OMB Clearance Number: 2127–0019.
Form Number: This collection of
information will not use any standard
forms.
Requested Expiration Date of
Approval: Three years from the date of
approval.
Summary of the Collection of
Information: So that NHTSA can ensure
that light truck manufacturers are
complying with the CAFE requirements,
NHTSA would require light truck
manufacturers to provide information
on their election of a compliance option
during model years 2008–2010, and
provide light truck footprint data
beginning model year 2008.
NHTSA established a transition
period during MYs 2008–2010 during
which manufacturers may opt to comply
with light truck fuel economy standards
established under the Reformed CAFE
system. For each year of the transition
period, manufacturers must, within 45
days after the end of the model year,
provide to NHTSA information
identifying the light truck CAFE system
with which the manufacturer chooses to
comply. The choice is irrevocable.
Further, the Reformed CAFE system
relies on vehicle footprint to determine
a manufacturer’s required average fuel
economy level. Beginning in MY 2008,
the agency would need to collect data
on vehicle footprint to determine
manufacturers’ compliance with the
Reformed CAFE system and to evaluate
the new system.
Description of the Need for the
Information and Proposed Use of the
Information: NHTSA need this
information to ensure that vehicle
manufacturers are complying with the
light truck CAFE program and to
evaluate the Reformed CAFE system.
Description of the Likely Respondents
(Including Estimated Number, and
Proposed Frequency of Response to the
Collection of Information): NHTSA
estimates that 14 light truck
manufacturers will be impacted by this
amendment. The manufacturers are
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makers of light trucks have gross vehicle
weight ratings of 4,536 kg (10,000
pounds) or less. For each pre-model
report currently required under 49 CFR
537.7, the manufacturer will provide
data on vehicle footprint. Further,
during MYs 2008–2010, the
manufacturers will provide, in addition
to its identity, a statement as to which
light truck CAFE standard with which it
has chosen to comply, 49 CFR 533.5(f)
or 49 CFR 533.5(g).
During the transition period, each
manufacturer will provide 1 additional
report per year for three years, for a total
of 3 additional reports over 3 years.
Estimate of the Total Annual
Reporting and Recordkeeping Burden
Resulting from the Collection of
Information: NHTSA estimates that each
manufacturer will incur an additional
10 burden hours per year. This estimate
is based on the fact that data collection
will involve only computer tabulation.
Further, this is consistent with the range
of burden hours suggested by the
Alliance in its comments. Thus, as a
result of this final rule each
manufacturer will incur an additional
burden of ten hours or a total on
industry of an additional 140 hours a
year (assuming there are 14
manufacturers).
NHTSA estimates that the
recordkeeping burden resulting from the
collection of information will be 0 hours
because the information will be retained
on each manufacturer’s existing
computer systems for each
manufacturer’s internal administrative
purposes.
NHTSA estimates that the total
annual cost burden will be 0 dollars.
There would be no capital or start-up
costs as a result of this collection.
Manufacturers can collect and tabulate
the information by using existing
equipment. Thus, there would be no
additional costs to respondents or
recordkeepers.
Comments are invited on:
• Whether the collection of
information is necessary for the proper
performance of the functions of the
Department, including whether the
information will have practical utility.
• Whether the Department’s estimate
for the burden of the information
collection is accurate.
• Ways to minimize the burden of the
collection of information on
respondents, including the use of
automated collection techniques or
other forms of information technology.
A comment to OMB is most effective if
OMB receives it within 30 days of
publication.
Send comments to the Office of
Information and Regulatory Affairs,
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Office of Management and Budget, 725
17th Street, NW., Washington, DC
20503, Attention NHTSA Desk Officer.
PRA comments are due within 30 days
following the publication of this
document in the Federal Register.
The agency recognizes that the
amendment to the existing collection of
information contained in today’s final
rule may be subject to revision in
response to public comments and the
OMB review. For additional information
contact: Ken Katz, Lead Engineer, Fuel
Economy Division, Office of
International Policy, Fuel Economy, and
Consumer Programs, National Highway
Traffic Safety Administration, 400
Seventh St., SW., Washington, DC
20590. Mr. Katz can also be contacted
at: telephone number (202) 366–0846,
facsimile (202) 493–2290, electronic
mail kkatz@nhtsa.dot.gov.
H. Regulation Identifier Number (RIN)
The Department of Transportation
assigns a regulation identifier number
(RIN) to each regulatory action listed in
the Unified Agenda of Federal
Regulations. The Regulatory Information
Service Center publishes the Unified
Agenda in April and October of each
year. You may use the RIN contained in
the heading at the beginning of this
document to find this action in the
Unified Agenda.
I. Executive Order 13045
Executive Order 13045 (62 FR 19885,
April 23, 1997) applies to any rule that:
(1) Is determined to be economically
significant as defined under E.O. 12866,
and (2) concerns an environmental,
health or safety risk that NHTSA has
reason to believe may have a
disproportionate effect on children. If
the regulatory action meets both criteria,
we must evaluate the environmental
health or safety effects of the planned
rule on children, and explain why the
planned regulation is preferable to other
potentially effective and reasonably
feasible alternatives considered by us.
This rule does not have a
disproportionate effect on children. The
primary effect of this rule is to conserve
energy resources by setting fuel
economy standards for light trucks.
J. National Technology Transfer and
Advancement Act
Section 12(d) of the National
Technology Transfer and Advancement
Act (NTTAA) requires NHTSA to
evaluate and use existing voluntary
consensus standards in its regulatory
activities unless doing so would be
inconsistent with applicable law (e.g.,
the statutory provisions regarding
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17675
NHTSA’s vehicle safety authority) or
otherwise impractical.
Voluntary consensus standards are
technical standards developed or
adopted by voluntary consensus
standards bodies. Technical standards
are defined by the NTTAA as
‘‘performance-based or design-specific
technical specification and related
management systems practices.’’ They
pertain to ‘‘products and processes,
such as size, strength, or technical
performance of a product, process or
material.’’
In meeting the requirement of the
NTTAA, we are required to consult with
voluntary, private sector, consensus
standards bodies. Examples of
organizations generally regarded as
voluntary consensus standards bodies
include the American Society for
Testing and Materials (ASTM), the
Society of Automotive Engineers (SAE),
and the American National Standards
Institute (ANSI). If NHTSA does not use
available and potentially applicable
voluntary consensus standards, we are
required by the Act to provide Congress,
through OMB, an explanation of the
reasons for not using such standards.
The final rule incorporates a function
based on light truck footprint (average
track width X wheelbase). For the
purpose of this calculation, the agency
based these measurements on those by
the automotive industry. Determination
of wheelbase is consistent with L101wheelbase, defined in SAE J1100
SEP2005, Motor vehicle dimensions.
The agency adopted a definition of track
width consistent with SAE J1100 W101
SEP2005.
There are no voluntary consensus
standards on fuel economy
performance.
K. Executive Order 13211
Executive Order 13211 (66 FR 28355,
May 18, 2001) applies to any rule that:
(1) Is determined to be economically
significant as defined under E.O. 12866,
and is likely to have a significant
adverse effect on the supply,
distribution, or use of energy; or (2) that
is designated by the Administrator of
the Office of Information and Regulatory
Affairs as a significant energy action. If
the regulatory action meets either
criterion, we must evaluate the adverse
energy effects of the planned rule and
explain why the planned regulation is
preferable to other potentially effective
and reasonably feasible alternatives
considered by us.
The final rule establishes light truck
fuel economy standards that will reduce
the consumption of petroleum and will
not have any adverse energy effects.
Accordingly, this rulemaking action is
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L. Department of Energy Review
In accordance with 49 U.S.C. 32902(j),
we submitted this rule to the
Department of Energy for review. That
Department did not make any comments
that we have not addressed.
M. Privacy Act
Anyone is able to search the
electronic form of all comments
received into any of our dockets by the
name of the individual submitting the
comment (or signing the comment, if
submitted on behalf of an association,
business, labor union, etc.). You may
review DOT’s complete Privacy Act
Statement in the Federal Register
published on April 11, 2000 (Volume
65, Number 70; Pages 19477–78) or you
may visit https://dms.dot.gov.
Regulatory Text
List of Subjects in 49 CFR Parts 523,
533, and 537
Fuel economy and Reporting and
recordkeeping requirements.
I In consideration of the foregoing, 49
CFR Chapter V is amended as follows:
PART 523—VEHICLE CLASSIFICATION
1. The authority citation for part 523
continues to read as follows:
I
Authority: 49 U.S.C. 32902; delegation of
authority at 49 CFR 1.50.
2. Section 523.2 is amended by adding
a definition of ‘‘footprint’’ and ‘‘medium
duty passenger vehicle’’ to read as
follows:
I
§ 523.2
Definitions.
*
*
*
*
Footprint means the product, in
square feet rounded to the nearest tenth,
of multiplying a vehicle’s average track
width (rounded to the nearest tenth) by
its wheelbase (rounded to the nearest
tenth). For purposes of this definition,
track width is the lateral distance
between the centerlines of the tires at
ground when the tires are mounted on
rims with zero offset. For purposes of
this definition, wheelbase is the
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*
Where:
N is the total number (sum) of light
trucks produced by a manufacturer,
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longitudinal distance between front and
rear wheel centerlines. In case of
multiple rear axles, wheelbase is
measured to the midpoint of the
centerlines of the wheels on the
rearmost axle.
*
*
*
*
*
Medium duty passenger vehicle
means a vehicle which would satisfy the
criteria in § 523.5 (relating to light
trucks) but for its gross vehicle weight
rating or its curb weight, which is rated
at more than 8,500 lbs GVWR or has a
vehicle curb weight of more than 6,000
pounds or has a basic vehicle frontal
area in excess of 45 square feet, and
which is designed primarily to transport
passengers, but does not include a
vehicle that:
(1) Is an ‘‘incomplete truck’’ as
defined in this subpart; or
(2) Has a seating capacity of more
than 12 persons; or
(3)Is designed for more than 9 persons
in seating rearward of the driver’s seat;
or
(4) Is equipped with an open cargo
area (for example, a pick-up truck box
or bed) of 72.0 inches in interior length
or more. A covered box not readily
accessible from the passenger
compartment will be considered an
open cargo area for purposes of this
definition.
*
*
*
*
*
I 3. Section 523.3(b) is amended by
adding (b)(3) to read as follows:
§ 523.3
Automobile.
*
*
*
*
*
(b) * * *
(3) Vehicles that are defined as
medium duty passenger vehicles, and
which are manufactured during the
2011 model year or thereafter.
I 4. Section 523.5(a)(5) is revised to
read as follows:
§ 523.5
Light Truck.
(a) * * *
(5) Permit expanded use of the
automobile for cargo-carrying purposes
or other nonpassenger-carrying
purposes through:
(i) For light trucks manufactured prior
to model year 2012, the removal of seats
Ni is the number (sum) of the ith model
light truck produced by the
manufacturer, and
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by means installed for that purpose by
the automobile’s manufacturer or with
simple tools, such as screwdrivers and
wrenches, so as to create a flat, floor
level, surface extending from the
forwardmost point of installation of
those seats to the rear of the
automobile’s interior; or
(ii) For light trucks manufactured in
model year 2008 and beyond, for
vehicles equipped with at least 3 rows
of designated seating positions as
standard equipment, permit expanded
use of the automobile for cargo-carrying
purposes or other nonpassengercarrying purposes through the removal
or stowing of foldable or pivoting seats
so as to create a flat-leveled cargo
surface extending from the forwardmost
point of installation of those seats to the
rear of the automobile’s interior.’’.
*
*
*
*
*
PART 533—LIGHT TRUCK FUEL
ECONOMY STANDARDS
5. The authority citation for part 533
continues to read as follows:
I
Authority: 49 U.S.C. 32902; delegation of
authority at 49 CFR 1.50.
6. Part 533.5 is amended by:
A. In paragraph (a) by revising Table
IV and adding Figure I and Table V; and
I B. Adding paragraphs (g) and (h).
The revisions and additions read as
follows:
I
I
§ 533.5
Requirements.
(a) * * *
TABLE IV
Model year
2001
2002
2003
2004
2005
2006
2007
2008
2009
2010
............................................
............................................
............................................
............................................
............................................
............................................
............................................
............................................
............................................
............................................
Standard
20.7
20.7
20.7
20.7
21.0
21.6
22.2
22.5
23.1
23.5
Ti is fuel economy target of the ith model
light truck, which is determined
according to the following formula,
rounded to the nearest hundredth:
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Where:
Parameters a, b, c, and d are defined in
§ 533.3 Table V;
e = 2.718; and
17677
x = footprint (in square feet, rounded to
the nearest tenth) of the vehicle
model
TABLE V.—PARAMETERS FOR THE REFORMED CAFE FUEL ECONOMY TARGETS
Parameters
Model year
a
2008
2009
2010
2011
.................................................................................................................
.................................................................................................................
.................................................................................................................
.................................................................................................................
*
*
*
*
*
(g) For model years 2008–2010, at a
manufacturer’s option, a manufacturer’s
light truck fleet may comply with the
fuel economy level calculated according
to Figure I and the appropriate values in
Table V, with said option being
irrevocably chosen for that model year
and reported as specified in § 537.8.
(h) For model year 2011, a
manufacturer’s light truck fleet shall
comply with the fuel economy level,
calculated according to Figure I and the
appropriate values in Table V.
7. Part 533 is amended by adding
Appendix A to read as follows:
28.56
30.07
29.96
30.42
19.99
20.87
21.20
21.79
Appendix A—Example of Calculating
Compliance Under § 533.5 Paragraph
(g)
Assume a hypothetical manufacturer
(Manufacturer X) produces a fleet of
light trucks in MY 2008 as follows:
Model
Fuel
economy
A ...........
B ...........
C ...........
D ...........
E ...........
F ............
27.0
25.6
25.4
22.1
22.4
20.2
Volume
1,000
1,500
1,000
2,000
3,000
1,000
c
Footprint
(ft 2)
42
44
46
50
55
66
49.30
48.00
48.49
47.74
5.58
5.81
5.50
4.65
Appendix A Figure 1
Model
A ...............
B ...............
C ...............
D ...............
E ...............
F ................
MY 2008
fuel economy
target (mpg)
Footprint
(ft 2)
42
44
46
50
55
66
26.2
25.5
24.8
23.3
21.7
20.3
Note to Appendix A Figure 1. Accordingly,
vehicle models A, B, C, D, E, and F would
be compared to fuel economy values of 26.2,
25.5, 24.8, 23.3, 21.7, and 20.3 mpg,
respectively. With the appropriate fuel
economy targets calculated, Manufacturer X’s
required fuel economy would be calculated
as illustrated in Appendix A Figure 2.
ER06AP06.040</GPH>
Note to Appendix A Table 1. Manufacturer
X’s required corporate average fuel economy
level under § 533.5(g) would be calculated by
first determining the fuel economy targets
applicable to each vehicle as illustrated in
Appendix A Figure 1.
d
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b
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Federal Register / Vol. 71, No. 66 / Thursday, April 6, 2006 / Rules and Regulations
Note to Appendix A Figure 2.
Manufacturer X’s required fuel economy
level is 23.1 mpg. Its actual fuel economy
level would be calculated as illustrated in
Appendix A Figure 3.
Note to Appendix A Figure 3. Since the
actual average fuel economy of Manufacturer
X’s fleet is 23.2 mpg, as compared to its
required fuel economy level of 23.1 mpg,
Manufacturer X complies with the Reformed
CAFE standard for MY 2008 as set forth in
§ 533.7(g).
(1) Interior volume index, determined
in accordance with subpart D of 40 CFR
part 600, and
(2) Body style;
(B) In the case of light trucks:
(1) Passenger-carrying volume,
(2) Cargo-carrying volume;
(3) Beginning model year 2008, track
width as defined in 49 CFR 523.2,
(4) Beginning model year 2008,
wheelbase as defined in 49 CFR 523.2,
and
(5) Beginning model year 2008,
footprint as defined in 49 CFR 523.2
(xvii) Performance of the function
described in § 523.5(a)(5) of this chapter
(indicate yes or no);
(xviii) Existence of temporary living
quarters (indicate yes or no);
(xix) Frontal area;
(xx) Road load power at 50 miles per
hour, if determined by the manufacturer
for purposes other than compliance
with this part to differ from the road
load setting prescribed in 40 CFR
86.177–11(d);
(xxi) Optional equipment that the
manufacturer is required under 40 CFR
parts 86 and 600 to have actually
PART 537—AUTOMOTIVE FUEL
ECONOMY REPORTS
8. The authority citation for part 537
reads as follows:
I
Authority: 49 U.S.C. 32907; 49 CFR 1.50.
9. Section 537.7 is amended by
revising paragraphs (c)(4)(xvi) through
(xxi) to read as follows:
I
§ 537.7 Pre-model year and mid-model
year reports.
*
*
*
*
*
(c) Model type and configuration fuel
economy and technical information
* * *
(4) * * *
(xvi)(A) In the case of passenger
automobiles:
installed on the vehicle configuration,
or the weight of which must be included
in the curb weight computation for the
vehicle configuration, for fuel economy
testing purposes.
*
*
*
*
*
10. Section 537.8 is amended by
adding paragraph (e) to read as follows:
I
§ 537.8
Supplementary reports.
*
*
*
*
*
(e) Reporting compliance option in
model years 2008–2010. For model
years 2008, 2009, and 2010, each
manufacturer of light trucks, as that
term is defined in 49 CFR 523.5, shall
submit a report, not later than 45 days
following the end of the model year,
indicating whether the manufacturer is
opting to comply with 49 CFR 533.5(f)
or 49 CFR 533.5(g).
Note: The following Appendices will not
appear in the Code of Federal Regulations
Appendix A—Comparison of
Engineering Constraints Employed by
the NPRM and the Final Rule Analyses
Engineering constraint
Technology
Reason for change
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Low-Friction Lubricants ..................
Variable Valve Timing (VVT) .........
Variable Valve Lift and Timing
(VVLT).
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Final
Do not apply if engine oil is 5W30
or better.
Do not apply to engines with displacement greater than 4.7 l.
Do not apply to engines with displacement greater than 3.0 l.
Do not apply if engine oil is better
than 5W30.
Do not apply to OHV engines ......
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Availability of lower friction (e.g.,
0W) oils.
OHV engines more likely to use
cylinder deactivation.
Next logical step from VVT.
06APR2
ER06AP06.041</GPH>
NPRM
Federal Register / Vol. 71, No. 66 / Thursday, April 6, 2006 / Rules and Regulations
17679
Engineering constraint
Technology
Reason for change
NPRM
Final
Cylinder Deactivation .....................
Do not apply to engines with VVT,
VVLT, and/or fewer than 6 cylinders.
Continuously
Variable
Transmission.
Front Axle Disconnect ....................
Do not apply to frame vehicles or
4WD SUVs.
Apply only to 4WD vehicles .........
Electric Power Steering .................
No universal constraints ...............
Integrated Starter-Generator ..........
No universal constraints ...............
Weight Reduction ..........................
Do not apply to vehicles with curb
weights below 3,900 pounds.
As a general rule, do not apply to
engines with VVT, VVLT,
multivalve OHC, and/or fewer
than 6 cylinders.
Apply only to FWD unibody vehicles.
Apply only to 4WD vehicles with
cylinder count greater than six.
For vehicles with curb weights
over 4,000 pounds, do not
apply unless 42-Volt systems
are already present.
Start application with the largest
vehicles, which have lower fuel
economy, prior to applying to
smaller, more fuel efficient vehicles.
Do not apply to vehicles with curb
weights below 5,000 pounds.
Multivalve OHC engines more
likely to use VVT or VVLT.
Less likely to mistakenly apply
CVT to some RWD SUVs.
Expected to be more applicable to
large vehicles.
Higher power demands for large
vehicle steering.
Mild hybridization expected to be
more suitable for large vehicles
due to packaging issues and
fuel savings potential.
Correction to placement of safety
threshold.
Appendix B—Changes to Technology
‘‘Phase-In Constraints’’ Employed by
the Volpe Model
NPRM
(percent)
Technology
Low Friction Lubricants ............................................................................................................................................
Improved Rolling Resistance ...................................................................................................................................
Low Drag Brakes .....................................................................................................................................................
Engine Friction Reduction .......................................................................................................................................
Front Axle Disconnect (for 4WD) ............................................................................................................................
Cylinder Deactivation ...............................................................................................................................................
Multi-Valve, Overhead Camshaft .............................................................................................................................
Variable Valve Timing ..............................................................................................................................................
Electric Power Steering ...........................................................................................................................................
Engine Accessory Improvement ..............................................................................................................................
5-Speed Automatic Transmission ............................................................................................................................
6-Speed Automatic Transmission ............................................................................................................................
Automatic Transmission w/Aggressive Shift Logic ..................................................................................................
Continuously Variable Transmission (CVT) ............................................................................................................
Automatic Shift Manual Transmission (AST/AMT) ..................................................................................................
Aero Drag Reduction ...............................................................................................................................................
Variable Valve Lift & Timing ....................................................................................................................................
Spark Ignited Direct Injection (SIDI) ........................................................................................................................
Engine Supercharging & Downsizing ......................................................................................................................
42 Volt Electrical Systems .......................................................................................................................................
Integrated Starter/Generator ....................................................................................................................................
Intake Valve Throttling .............................................................................................................................................
Camless Valve Actuation .........................................................................................................................................
Variable Compression Ratio ....................................................................................................................................
Advanced CVT .........................................................................................................................................................
Dieselization .............................................................................................................................................................
Material Substitution ................................................................................................................................................
Midrange Hybrid Vehicle .........................................................................................................................................
Issued: March 28, 2006.
Jacqueline Glassman,
Deputy Administrator.
[FR Doc. 06–3151 Filed 3–29–06; 1:29 pm]
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Final
(percent)
50
50
50
33
5
25
33
33
33
33
33
25
33
33
10
33
25
3
25
33
33
25
25
25
25
3
20
3
25
25
17
17
17
17
17
17
17
25
17
17
17
17
17
17
17
3
17
17
5
17
10
10
17
3
17
3
]]>Agencies
[Federal Register Volume 71, Number 66 (Thursday, April 6, 2006)]
[Rules and Regulations]
[Pages 17566-17679]
From the Federal Register Online via the Government Printing Office [www.gpo.gov]
[FR Doc No: 06-3151]
[[Page 17565]]
-----------------------------------------------------------------------
Part II
Department of Transportation
-----------------------------------------------------------------------
National Highway Traffic Safety Administration
-----------------------------------------------------------------------
49 CFR Parts 523, 533 and 537
Average Fuel Economy Standards for Light Trucks Model Years 2008-2011;
Final Rule
��Federal Register / Vol. 71, No. 66 / Thursday, April 6, 2006 / Rules
and Regulations��
[[Page 17566]]
-----------------------------------------------------------------------
DEPARTMENT OF TRANSPORTATION
National Highway Traffic Safety Administration
49 CFR Parts 523, 533 and 537
[Docket No. NHTSA 2006-24306]
RIN 2127-AJ61
Average Fuel Economy Standards for Light Trucks Model Years 2008-
2011
AGENCY: National Highway Traffic Safety Administration (NHTSA),
Department of Transportation.
ACTION: Final rule.
-----------------------------------------------------------------------
SUMMARY: This final rule reforms the structure of the corporate average
fuel economy (CAFE) program for light trucks and establishes higher
CAFE standards for model year (MY) 2008-2011 light trucks. Reforming
the CAFE program will enable it to achieve larger fuel savings, while
enhancing safety and preventing adverse economic consequences.
During a transition period of MYs 2008-2010, manufacturers may
comply with CAFE standards established under the reformed structure
(Reformed CAFE) or with standards established in the traditional way
(Unreformed CAFE). This will permit manufacturers and the agency to
gain experience with implementing the Reformed CAFE standards. In MY
2011, all manufacturers will be required to comply with a Reformed CAFE
standard.
Under Reformed CAFE, fuel economy standards are restructured so
that they are based on a measure of vehicle size called ``footprint,''
the product of multiplying a vehicle's wheelbase by its track width. A
target level of fuel economy is established for each increment in
footprint. Smaller footprint light trucks have higher targets and
larger ones, lower targets. A particular manufacturer's compliance
obligation for a model year will be calculated as the harmonic average
of the fuel economy targets for the manufacturer's vehicles, weighted
by the distribution of manufacturer's production volumes among the
footprint increments. Thus, each manufacturer will be required to
comply with a single overall average fuel economy level for each model
year of production.
The Unreformed CAFE standards are: 22.5 miles per gallon (mpg) for
MY 2008, 23.1 mpg for MY 2009, and 23.5 mpg for MY 2010. To aid the
transition to Reformed CAFE, the Reformed CAFE standards for those
years are set at levels intended to ensure that the industry-wide costs
of the Reformed standards are roughly equivalent to the industry-wide
costs of the Unreformed CAFE standards in those model years. For MY
2011, the Reformed CAFE standard is set at the level that maximizes net
benefits. Net benefits includes the increase in light truck prices due
to technology improvements, the decrease in fuel consumption, and a
number of other factors viewed from a societal perspective. All of the
standards have been set at the maximum feasible level, while accounting
for technological feasibility, economic practicability and other
relevant factors.
Since a manufacturer's compliance obligation for a model year under
Reformed CAFE depends in part on its actual production in that model
year, its obligation cannot be calculated with absolute precision until
the final production figures for that model year become known. However,
a manufacturer can calculate its obligation with a reasonably high
degree of accuracy in advance of that model year, based on its product
plans for the year. Prior to and during the model year, the
manufacturer will be able to track all of the key variables in the
formula used for calculating its obligation (e.g., distribution of
production and the fuel economy of each of its models). This final rule
announces estimates of the compliance obligations, by manufacturer, for
MYs 2008-2011 under Reformed CAFE, using the fuel economy targets
established by NHTSA and the product plans submitted to NHTSA by the
manufacturers in response to an August 2005 request for updated product
plans.
This rulemaking is mandated by the Energy Policy and Conservation
Act (EPCA), which was enacted in the aftermath of the energy crisis
created by the oil embargo of 1973-74. The concerns about reliance on
petroleum imports, energy security, and the effects of energy prices
and supply on national economic well-being that led to the enactment of
EPCA remain very much alive today. America is still overly dependent on
petroleum. Sustained growth in the demand for oil worldwide, coupled
with tight crude oil supplies, are the driving forces behind the sharp
price increases seen over the past several years and are expected to
remain significant factors in the years ahead. Increasingly, the oil
consumed in the U.S. originates in countries with political and
economic situations that raise concerns about future oil supply and
prices. In the long run, technological innovation will play an
increasingly larger role in reducing our dependence on petroleum.
We recognize that financial difficulties currently exist in the
motor vehicle industry and that a substantial number of job reductions
have been announced recently by large full-line manufacturers.
Accordingly, we have carefully balanced the costs of the rule with the
benefits of conservation. Compared to Unreformed CAFE, Reformed CAFE
enhances overall fuel savings while providing vehicle manufacturers
with the flexibility they need to respond to changing market
conditions. Reformed CAFE will also provide a more equitable regulatory
framework by creating a level-playing field for manufacturers,
regardless of whether they are full-line or limited-line manufacturers.
We are particularly encouraged that Reformed CAFE will reduce the
adverse safety risks generated by the Unreformed CAFE program. The
transition from the Unreformed CAFE to the Reformed CAFE system will
begin soon, but ample lead time is provided before Reformed CAFE takes
full effect in MY 2011.
DATES: Today's final rule is effective August 4, 2006. Petitions for
reconsideration must be received by May 22, 2006.
ADDRESSES: Petitions for reconsideration must be submitted to:
Administrator, National Highway Traffic Safety Administration, 400
Seventh Street, SW., Nassif Building, Washington, DC 20590-001.
FOR FURTHER INFORMATION CONTACT: For technical issues, call Ken Katz,
Lead Engineer, Fuel Economy Division, Office of International Vehicle,
Fuel Economy, and Consumer Standards, at (202) 366-0846, facsimile
(202) 493-2290, electronic mail kkatz@nhtsa.dot.gov. For legal issues,
call Stephen Wood or Christopher Calamita of the Office of the Chief
Counsel, at (202) 366-2992, or e-mail them at swood@nhtsa.dot.gov or
ccalamita@nhtsa.dot.gov.
SUPPLEMENTARY INFORMATION:
Table of Contents
I. Executive summary
A. Events leading to today's final rule
B. Today's final rule
C. Energy demand and supply and the value of conservation
II. Background
A. 1974 DOT/EPA report to Congress on potential for motor
vehicle fuel economy improvements
B. Energy Policy and Conservation Act of 1975
C. 1979-2002 light truck standards
D. 2001 National Energy Policy
E. 2002 NAS study of CAFE reform
F. 2003 final rule establishing MY 2005-2007 light truck
standards
[[Page 17567]]
G. 2003 comprehensive plans for addressing vehicle rollover and
compatibility
H. 2003 ANPRM
1. Need for reform
2. Reform options
I. Recent Developments
1. Factors underscoring need for reform
2. Revised Product Plans
III. Summary of the NPRM
IV. Summary of public comments
V. The Unreformed CAFE standards for MYs 2008-2010
A. Legal authority and requirements under EPCA
B. Establishing Unreformed standards according to EPCA--process
for determining maximum feasible levels
C. Baseline for determining manufacturer capabilities in MYs
2008-2010
D. Technologically feasible additions to product plans
E. Improved product plans
F. Economic practicability and other economic issues
1. Costs
2. Benefits
3. Comparison of estimated costs to estimated benefits
4. Uncertainty
G. Unreformed standards for MYs 2008-2010
VI. The Reformed CAFE standards for MYs 2008-2011
A. Overview of Reformed CAFE
B. Authority for Reformed CAFE
C. Legal issues related to Reformed CAFE
1. Maximum feasible
2. Backstop
3. Transition period
D. Structure of Reformed CAFE
1. Footprint based function
2. Continuous function
a. Overview of establishing the continuous function standard
b. Industry-wide considerations in defining the stringency of
the standard
c. Improving the light truck fleet
d. Defining the function and the preliminary shape of the curve
e. Final level of the curve (and the targets)
3. Application of the continuous function based standard
4. Why this approach to reform and not another?
a. Continuous function vs. the proposed step-function
(categories)
b. Continuous function and targets vs. classes and standards
c. Consideration of additional attributes
d. Backstop and ``fuel saving'' mechanisms
5. Benefits of reform
a. Increased energy savings
b. Reduced incentive to respond to the CAFE program in ways
harmful to safety
i. Reduces incentive to reduce vehicle size and to offer smaller
vehicles
ii. Reduces the difference between car and light truck CAFE
standards
c. More equitable regulatory framework
d. More responsive to market changes
E. Comparison of estimated costs to estimated benefits
1. Costs
2. Benefits
3. Uncertainty
F. MY 2008-2011 Reformed CAFE standards
VII. Technology issues
A. Reliance on the NAS report
B. Technologies included in the manufacturers' product plans
C. Lead Time
D. Technology effectiveness and practical limitations
E. Technology incompatibility
F. Weight reduction
VIII. Economic assumptions
A. Costs of technology
B. Fuel prices
C. Consumer valuation of fuel economy and payback period
D. Opportunity costs
E. Rebound effect
F. Discount rate
G. Import externalities (monopsony, oil disruption effects, and
costs of maintaining U.S. presence and strategic petroleum reserve)
H. Uncertainty analysis
I. The 15 percent gap
J. Pollution and greenhouse gas valuation
K. Increased driving range and vehicle miles traveled
L. Added costs from congestion, crashes, and noise
M. Employment impacts
IX. MY 2008-2010 Transition period
A. Choosing the Reformed or Unreformed CAFE system
B. Application of credits between compliance options
X. Impact of other Federal motor vehicle standards
A. Federal motor vehicle safety standards
1. FMVSS 138, Tire Pressure Monitoring System 2 FMVSS 202, Head
Restraints
3. FMVSS 208, Occupant Crash Protection (Rear Center Seat Lap/
Shoulder Belts)
4. FMVSS 208, Occupant Crash Protection (35 mph Frontal Impact
Testing)
5. FMVSS 301, Fuel System Integrity
B. Potential future safety standards and voluntary safety
improvements
1. Anti-lock Brakes and Electronic Stability Control (ESC)
2. Roof Crush, FMVSS 216
3. Side Impact and Ejection Mitigation Air Bags (Thorax and Head
Air Bags)
4. Offset Frontal Crash Testing
C. Cumulative weight impacts of the safety standards and
voluntary improvements
D. Federal Motor Vehicle Emissions Standards
1. Tier 2 requirements
2. Onboard vapor recovery
3. California Air Resources Board--Clean Air Act Section 209
standards
XI. Need of the Nation to Conserve Energy
XII. Comparison of the final and proposed standards
A. Changes in the Volpe model
B. Higher fuel price forecasts
C. Revisions to the Reformed CAFE system
D. Updated product plans
E. Evaluating the adopted Reformed CAFE
XIII. Applicability of the CAFE standards
A. Inclusion of MDPVs in MY 2011
B. ``Flat-floor'' provision
XIV. Additional issues
A. Limited-line manufacturer standard
B. Credit trading
C. Reporting requirements
D. Preemption
XV. Rulemaking analyses and notices
A. Executive Order 12866 and DOT Regulatory Policies and
Procedures
B. National Environmental Policy Act
C. Regulatory Flexibility Act
D. Executive Order 13132 Federalism
E. Executive Order 12988 (Civil Justice Reform)
F. Unfunded Mandates Reform Act
G. Paperwork Reduction Act
H. Regulation Identifier Number (RIN)
I. Executive Order 13045
J. National Technology Transfer and Advancement Act
K. Executive Order 13211
L. Department of Energy review
M. Privacy Act
XVI. Regulatory Text
I. Executive Summary
A. Events Leading to Today's Final Rule
In the notice of proposed rulemaking (NPRM) that the agency
published on August 30, 2005, the agency proposed to reform the light
truck CAFE program. The Reformed CAFE standard was to be based on a
step function.\1\ To aid the transition to the Reformed CAFE system, we
proposed to provide manufacturers with two alternative compliance
options (Unreformed and Reformed) for manufacturers in MYs 2008-2010.
The agency proposed requiring compliance with the Reformed CAFE system,
beginning in MY 2011. The agency noted in the NPRM that it was
publishing a separate notice inviting the manufacturers to submit more
updated product plans and stated that it recognized that the new plans
might differ enough from the previously submitted plans to necessitate
changes in the shape of the step function as well as in the levels of
stringency of the standards.
---------------------------------------------------------------------------
\1\ As proposed, the structure of Reformed CAFE for each model
year would have three basic elements--
(1)--six footprint categories of vehicles.
(2)--a target level of average fuel economy for each footprint
category, as expressed by a step function (see figure 1 below).
(3)--a Reformed CAFE standard based on the harmonic production-
weighted average of the fuel economy targets for each category.
---------------------------------------------------------------------------
In addition, the agency invited public comment on a number of
additional changes to the CAFE program. One was whether to base the
Reformed CAFE on a continuous function instead of a step function. A
second was whether to include large sport utility vehicles (SUVs) in
the CAFE standards. A third was whether to revise the ``flat floor''
criterion for classifying vehicles as light trucks so that minivans and
passenger vans would be treated as light trucks.
In response to the NPRM and request for new product plans, the
agency
[[Page 17568]]
obtained a great deal of new information. Compared to the plans that
the manufacturers submitted to the agency in early 2004, the new plans
submitted in November 2005 contained a significant increase in the
variety and amount of efforts to improve fuel economy. The agency also
received critiques of the analyses it performed to determine the fuel
economy capabilities of the manufacturers in MYs 2008-2011.
In response to the public comments, the agency revised its analyses
and assumptions including those related to the rate at which increased
amounts of fuel saving technologies can be added to a manufacturer's
fleet. The new assumptions are closer to the assumptions made by the
National Academies of Science in a 2002 study of the CAFE program, and
provide increased assurance that the standards adopted today will be
economically practicable.
NHTSA also made other changes. It decided to base Reformed CAFE on
a continuous function instead of a step function in order to reduce the
incentive under Reformed CAFE for manufacturers to downsize (thus
reducing safety) or upsize (thus reducing fuel economy) vehicles. It
also decided to add the larger SUVs and passenger vans to the mandatory
Reformed CAFE program in MY 2011 and beyond to increase long-term
energy savings.
B. Today's Final Rule
The final rule adopted today reforms the structure of the CAFE
regulatory program so that it achieves higher fuel savings while
enhancing safety and preventing adverse economic consequences. We have
previously set forth our concerns about the way in which the current
CAFE program operates and sought comment on approaches to reforming the
CAFE program. We have also previously increased light truck CAFE
standards, from the ``frozen'' level of 20.7 mpg applicable from MY
1996 through MY 2004, to a level of 22.2 mpg applicable to MY 2007. In
adopting those increased standards, we noted that we were limited in
our ability to make further increases without reforming the program.
The Reformed CAFE structure established and institutionalized in
this document minimizes those limitations by establishing a system
based on light truck size, which allows us to establish higher CAFE
standards for MY 2008-2011 light trucks and achieve greater fuel
savings across the industry. In addition to the improved energy
savings, this CAFE program enhances safety by eliminating the previous
regulatory incentive to downsize vehicles and by raising the light
truck standards so that there is no regulatory incentive from the CAFE
program to design small vehicles as light trucks instead of passenger
cars. It prevents adverse economic consequences by incorporating
greater consideration of economic practicability issues into the
projections of the timing and rate at which manufacturers can introduce
fuel economy improving technologies into their fleets, and by setting
the Reformed CAFE standards, beginning in MY 2011, at the level at
which marginal benefits equal marginal costs.
During a transition period of MYs 2008-2010, manufacturers may
comply with CAFE standards established under the reformed structure
(Reformed CAFE) or with standards established in the traditional way
(Unreformed CAFE). This will permit manufacturers to gain experience
with the Reformed CAFE standards. The Reformed CAFE standards for those
model years are set at levels intended to ensure that the industry-wide
costs of those standards are roughly equivalent to the industry-wide
costs of the Unreformed CAFE standards for those model years. The
additional lead time provided by the transition period will aid, for
example, those manufacturers that, for the first time, face a binding
CAFE standard (i.e., one set above their planned level of CAFE) and
will be required to make fuel economy improvements to achieve
compliance. In MY 2011, all manufacturers are required to comply with a
Reformed CAFE standard. The Reformed CAFE standard for that model year
is set at the level that maximizes net benefits by setting the fuel
economy targets at the point at which marginal benefits of the last
added increment of fuel savings equal the marginal costs of the added
technology that produced those savings.
As in prior CAFE rulemakings establishing Unreformed standards,
this final rule sets the Unreformed standards for MYs 2008-2010 with
particular regard to the capabilities of and impacts on the ``least
capable'' full line manufacturer (i.e., a full line manufacturer is one
that produces a wide variety of types and sizes of vehicles) with a
significant share of the market. A single CAFE level, applicable to
each manufacturer, is established for each model year.
The Unreformed CAFE standards for MYs 2008-2010 are:
MY 2008: 22.5 mpg
MY 2009: 23.1 mpg
MY 2010: 23.5 mpg
We estimate that compliance with these standards will save 4.4 billion
gallons of fuel over the lifetime of the vehicles sold during those
model years, compared to the savings that would occur if the standards
remained at the MY 2007 level of 22.2 mpg.
Under Reformed CAFE, each manufacturer's required level of CAFE is
based on target levels set according to vehicle size. The targets are
assigned according to a vehicle's ``footprint''--the product of the
average track width (the distance between the centerline of the tires)
and wheelbase (basically, the distance between the centers of the
axles). Each vehicle footprint value is assigned a target specific to
that footprint value. This differs from what we proposed. The proposed
reform was based on a discontinuous (or ``step'') function. The
proposal segmented the light truck fleet into six discrete categories
based on ranges of footprint and assigned a target fuel economy value
for each category. The reform adopted in today's final rule is based on
a continuous function. Under it, targets are assigned along the
continuum of footprint values in the light truck fleet. Each footprint
value has a different target. The target values reflect the
technological and economic capabilities of the industry. The target for
a given footprint value is the same for all manufacturers, regardless
of differences in their overall fleet mixes. Compliance is determined
by comparing a manufacturer's harmonically averaged fleet fuel economy
in a model year with a required fuel economy level calculated using the
manufacturer's actual production levels and the category targets.
The Reformed CAFE standards adopted today are more stringent than
those proposed in the NPRM. Under the Reformed CAFE system in the NPRM,
we estimated that the average CAFE level required of light truck
manufacturers would be 23.9 mpg. It is important to note that the MY
2011 standard as adopted in this rule applies to a larger population of
vehicles than that in the NPRM. Today's final rule includes medium duty
passenger vehicles (MDPVs) (i.e., larger passenger vans and SUVs) as
part of the MY 2011 regulated fleet. We estimate that the average CAFE
level required of manufacturers under this rule in MY 2011 will be 24.0
mpg. Thus, the MY 2011 standard is more stringent than that proposed
while regulating more vehicles, i.e., larger vehicles with typically
low fuel economy performance.
As stated above, manufacturers provided updated product plans that
[[Page 17569]]
reflect changes made to the evaluated light truck fleet used in the
NPRM, partly in response to changes in fuel prices. Changing market
conditions, a regulatory landscape revised by our proposal, and the
more stringent fuel efficiency levels required under Reform CAFE will
result in the production of MY 2008-2011 light truck fleets that will
consume approximately 11 billion fewer gallons of fuel over their
lifetimes than the fleets that were originally planned in 2004.
Apart from the updated product plans, the agency has revised some
of the assumptions inputted into the Reformed CAFE analysis. In
response to comments and consistent with the findings of the National
Academy of Sciences, we revised the phase-in rates to provide for
additional lead-time when projecting technology applications. The
agency also revised fuel prices and the vehicle miles traveled
schedule, which is used to calculate fuel savings, in response to
higher fuel price forecasts.
Given the revised product plans, the revisions to the model
assumptions, and the more stringent standards adopted in this rule, the
Reformed standards will save approximately 7.8 billion additional
gallons of fuel over the lifetime of the vehicles sold during those
four model years. The Reformed standards for MYs 2008-2010 will save
approximately 500 million more gallons of fuel than the Unreformed
standards for those model years. As noted above, the Reformed standard
for MY 2011 is the first Reformed standard set through a process the
explicitly maximizes net benefits. It will save more than 2.8 billion
gallons of fuel over the lifetime of vehicle sold in that model year.
In order to provide a comparison of the fuel savings of the final
rule versus the proposed rule, we recalculated the fuel savings from
the proposed Reformed CAFE standards using the updated product plans
and the final rule assumptions. Under this analysis, we calculated that
the proposed Reformed standards would save 5.4 billion gallons under
these more current assumptions. This compares to the 7.8 billion
gallons of fuel saved under the more stringent Reformed CAFE standards
adopted today.
If all manufacturers comply with the Reformed CAFE standards, the
total costs would be approximately $6.7 billion for MYs 2008-2011,
compared to the costs they would incur if the standards remained at the
MY 2007 level of 22.2 mpg. The resulting vehicle price increases to
buyers of MY 2008 light trucks would be paid back \2\ in additional
fuel savings in an average of 2.9 years and to buyers of MY 2011 light
trucks in an average of 4,4 years, assuming fuel prices ranging from
$1.96 to $2.39 per gallon (in 2003 dollars).\3\ We estimate that the
total benefits under the Unreformed CAFE standards for MYs 2008-2010
plus the Reformed CAFE standard for MY 2011 are approximately $7.6
billion (2003 dollars, discounted at 7%), and under the Reformed CAFE
standards for MYs 2008-2011 are approximately $8.1 billion (2003
dollars, discounted at 7%).
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\2\ The payback period represents the length of time required
for a vehicle buyer to recoup the higher cost of purchasing a more
fuel-efficient vehicle through savings in fuel use. When a more
stringent CAFE standard requires a manufacturer to improve the fuel
economy of some of its vehicle models, the manufacturer's added
costs for doing so are reflected in higher prices for these models.
While buyers of these models pay higher prices to purchase these
vehicles, their improved fuel economy lowers their owners' costs for
purchasing fuel to operate them. Over time, buyers thus recoup the
higher purchase prices they pay for these vehicles in the form of
savings in outlays for fuel. The length of time required to repay
the higher cost of buying a more fuel-efficient vehicle is referred
to as the buyer's ``payback period.''
The length of this payback period depends on the initial
increase in a vehicle's purchase price, the improvement in its fuel
economy, the number of miles it is driven each year, and the retail
price of fuel. We calculated payback periods using the fuel economy
improvement and average price increase for each manufacturer's
vehicles estimated to result from the proposed standard, the U.S.
Energy Information Administration's forecast of future retail
gasoline prices, and estimates of the number of miles light trucks
are driven each year as they age developed from U.S. Department of
Transportation data. Energy Information Administration, Annual
Energy Outlook 2005 (AEO 2005), Table 100, https://www.eia.doe.gov/
oiaf/aeo/supplement/; and U.S. Department of
Transportation, 2001 National Household Travel Survey, https://
nhts.ornl.gov/2001/index.shtml. Under these assumptions, payback
periods for the final rule alternatives (i.e., Unreformed and
Reformed CAFE) range from 2.9 to 4.9 years. .
\3\ The fuel prices used to calculate the length of the payback
periods are those expected over the life of the MY 2008-2011 light
trucks, not the current fuel prices. Those future fuel prices were
obtained from the AEO 2006 (Early Report).
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We have determined that the standards under both Unreformed CAFE
and Reformed CAFE represent the maximum feasible fuel economy level for
each system. In reaching this conclusion, we have balanced the express
statutory factors and other relevant considerations, such as safety
concerns, effects on employment and the need for flexibility to
transition to a Reformed CAFE program that can achieve greater fuel
savings in a more economically efficient way.
The Reformed CAFE approach incorporates several important elements
of reform suggested by the National Academy of Sciences in its 2002
report (Effectiveness and Impact of Corporate Average Fuel Economy
(CAFE) Standards). The agency believes that these reforms give the
Reformed CAFE approach four basic advantages over the Unreformed CAFE
approach.
First, Reformed CAFE increases energy savings. The energy-saving
potential of Unreformed CAFE is limited because only a few full-line
manufacturers are required to make improvements. In effect, the
capabilities of these full-line manufacturers, whose offerings include
larger and heavier light trucks, constrain the stringency of the
uniform, industry-wide standard. As a result, the Unreformed CAFE
standard is generally set below the capabilities of limited-line
manufacturers, who sell predominantly lighter and smaller light trucks.
Under Reformed CAFE, which accounts for size differences in product
mix, virtually all light-truck manufacturers will be required to use
advanced fuel-saving technologies to achieve the requisite fuel economy
for their vehicles. Thus, Reformed CAFE will continue to require full-
line manufacturers to improve the overall fuel economy of their fleets,
while also requiring limited-line manufacturers to enhance the fuel
economy of the vehicles they sell.
Second, Reformed CAFE offers enhanced safety. Due to the structure
of Unreformed CAFE standards, vehicle manufacturers that need to
supplement their product plans in order to comply with the standards
can increase their likelihood of compliance by pursuing a variety of
compliance strategies that entail safety risks: Downsizing of vehicles,
design of some vehicles to permit classification as ``light trucks''
for CAFE purposes, and offering smaller and lighter vehicles to offset
sales of larger and heavier vehicles. The adverse safety effects of
downsizing and downweighting have already been documented for passenger
cars in the CAFE program. For example, when a manufacturer designs a
vehicle to permit its classification as a light truck, it may increase
the vehicle's propensity to roll over.
Reformed CAFE is designed to lessen each of these safety risks.
Downsizing of vehicles is discouraged under Reformed CAFE since as
vehicles become smaller, the applicable fuel economy target becomes
more stringent. Moreover, Reformed CAFE lessens the incentive to design
smaller vehicles to achieve a ``light truck'' classification, since
many small light trucks are subject to targets that have at least the
same degree of stringency as passenger car standards, if not higher
stringency.
Third, Reformed CAFE provides a more equitable regulatory framework
for
[[Page 17570]]
different vehicle manufacturers. Under Unreformed CAFE, the cost
burdens and compliance difficulties have been imposed nearly
exclusively on the full-line manufacturers. Reformed CAFE spreads the
regulatory cost burden for fuel economy more broadly across the
industry.
Fourth, Reformed CAFE is more market-oriented because it more fully
respects economic conditions and consumer choice. Reformed CAFE does
not force vehicle manufacturers to adjust fleet mix toward smaller
vehicles unless that is what consumers are demanding. Instead, it
allows the manufacturers to adjust the mix of their product offerings
in response to the market place. As a result, as the industry's sales
volume and mix changes in response to economic conditions (e.g.,
gasoline prices and household income) and consumer preferences (e.g.,
desire for seating capacity or hauling capability), the level of CAFE
required of manufacturers under Reformed CAFE will, at least partially,
adjust automatically to these changes. Accordingly, Reformed CAFE
reduces the need that the agency might otherwise have to revisit
previously established standards in light of changed market conditions,
a difficult process that undermines regulatory certainty for the
industry. In the mid-1980's, for example, the agency relaxed several
Unreformed CAFE standards because fuel prices fell more than had been
expected when those standards were established and, as a result,
consumer demand for small vehicles with high fuel economy did not
materialize as expected.
In addition to reforming the structure of the light truck CAFE
program, we are also expanding its applicability. Starting in MY 2011,
the CAFE program will include MPDVs, light trucks that have a gross
vehicle weight rating (GVWR) less than 10,000 lbs., a GVWR greater than
8,500 lbs. or a curb weight greater than 6,000 lbs., and that primarily
transport passengers. We estimate this will bring an additional 240,000
vehicles into the CAFE program in that model year.
C. Energy Demand and Supply and the Value of Conservation
As we noted in the notice of proposed rulemaking (NPRM),\4\ many of
the concerns about energy security and the effects of energy prices and
supply on national economic well-being that led to the enactment of
EPCA in 1975 persist today.\5\ The demand for oil is steadily growing
in the U.S. and around the world. By 2030, U.S. demand for petroleum
products is expected to increase 33 percent compared to 2004.\6\ World
oil demand is expected to increase by nearly 44 percent between 2004
and 2025.\7\ Most of these increases would occur in the transportation
sector. To meet this projected increase in world demand, worldwide
productive capacity would have to increase by more than 36 million
barrels per day over current levels. OPEC producers are expected to
supply nearly 40 percent of the increased production. By 2025, 60
percent of the oil consumed in the U.S. would be imported oil. Strong
growth in the demand for oil worldwide, coupled with tight crude oil
supplies, is the driving force behind the sharp price increases seen
over the past four years. Increasingly, the oil consumed in the U.S.
originates in countries with political and economic situations that
raise concerns about future oil supply and prices.
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\4\ 70 FR 51414, August 30, 2005.
\5\ The sources of the figures in this section can be found
below in section VIII, ``Need for Nation to conserve energy.''
\6\ Annual Energy Outlook 2006 with projections to 2030 (Early
Release), https://www.eia.doe.gov/oiaf/aeo/.
\7\ Id.
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Energy is an essential input to the U.S. economy and having a
strong economy is essential to maintaining and strengthening our
national security. Conserving energy, especially reducing the nation's
dependence on petroleum, benefits the U.S. in several ways. Reducing
total petroleum use decreases our economy's vulnerability to oil price
shocks. Reducing dependence on oil imports from regions with uncertain
conditions enhances our energy security. Reducing the growth rate of
oil use will help relieve pressures on already strained domestic
refinery capacity, decreasing the likelihood of future product price
volatility.
Today's final rule is one piece of President Bush's strategy to
move the nation beyond a petroleum-based economy. Aside from the fuel
savings that will be realized by today's final rule, the Administration
is focusing research on bio-based transportation fuels, improved
batteries for hybrid vehicles, and the on-going hydrogen fuel
initiative. The President's Advanced Energy Initiative and today's
final rule will build on the progress made by the Administration's 2001
National Energy Policy and the increased CAFE standards for MY 2005-
2007 light trucks.
II. Background
In proposing the CAFE standards for MYs 2008-2011, the agency
provided a detailed summary of the history of fuel economy standards,
and in particular, fuel economy standards for light trucks. Below we
have provided a summary of that discussion. For more background on the
light truck CAFE program, refer to the NPRM.
A. 1974 DOT/EPA Report to Congress on Potential for Motor Vehicle Fuel
Economy Improvements
In 1974, the Department of Transportation (DOT) and Environmental
Protection Agency (EPA) submitted to Congress a report entitled
``Potential for Motor Vehicle Fuel Economy Improvement (1974
Report).\8\ This report was prepared in compliance with Section 10 of
the Energy Supply and Environmental Coordination Act of 1974, Public
Law 93-319 (the Act). In the 1974 Report, DOT/EPA said that performance
standards regulating fuel economy could take either of two modes: a
production-weighted average standard for each manufacturer's entire
fleet of vehicles or a fuel economy standard tailored to individual
classes of vehicles. Included as a possible form for a production-
weighted standard was a variable standard based on the costs or
potential to improve for each manufacturer (1974 Report, p. 77).
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\8\ The 1974 report is available in the docket for this
rulemaking.
---------------------------------------------------------------------------
DOT/EPA concluded in the 1974 Report that a production-weighted
standard establishing one uniform specific fuel economy average for all
manufacturers would, if sufficiently stringent to have the needed
effect, impact most heavily on manufacturers who have lower fuel
economy, while not requiring manufacturers of current vehicles with
better fuel economy to maintain or improve their performance. (1974
Report, p. 12) Production-weighted standards specifically tailored to
each manufacturer would eliminate some inequities, but were considered
to be difficult to administer fairly. (Ibid.)
B. Energy Policy and Conservation Act of 1975
Congress enacted the Energy Policy and Conservation Act (EPCA Pub.
L. 94-163) during the aftermath of the energy crisis created by the oil
embargo of 1973-74. The Act established an automobile fuel economy
regulatory program by adding Title V, ``Improving Automotive
Efficiency,'' to the Motor Vehicle Information and Cost Savings Act.
Title V has been amended from time to time and codified without
[[Page 17571]]
substantive change as Chapter 329 of title 49, United States Code.
Chapter 329 provides for the issuance of average fuel economy standards
for passenger automobiles and separate standards for automobiles that
are not passenger automobiles (light trucks).
For the purposes of the CAFE statute, ``automobiles'' include any
``4-wheeled vehicle that is propelled by fuel (or by alternative fuel)
manufactured primarily for use on public streets, roads, and highways
(except a vehicle operated only on a rail line), and rated at not more
than 6,000 pounds gross vehicle weight.'' They also include any such
vehicle rated at between 6,000 and 10,000 pounds gross vehicle weight
(GVWR) if the Secretary decides by regulation that an average fuel
economy standard for the vehicle is feasible, and that either such a
standard will result in significant energy conservation or the vehicle
is substantially used for the same purposes as a vehicle rated at not
more than 6,000 pounds GVWR.\9\
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\9\ In 1978, we extended the CAFE program to include vehicles
rated between 6,000 and 8,500 pounds GVWR (March 23, 1978; 43 FR
11995, at 11997). Vehicles rated at between 6,000 and 8,500 pounds
GVWR first became subject to the CAFE standards in MY 1980.
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The CAFE standards set a minimum performance requirement in terms
of an average number of miles a vehicle travels per gallon of gasoline
or diesel fuel. Individual vehicles and models are not required to meet
the mileage standard. Instead, each manufacturer must achieve a
harmonically averaged level of fuel economy for all specified vehicles
manufactured by a manufacturer in a given MY. The statute distinguishes
between ``passenger automobiles'' and ``non-passenger automobiles.'' We
generally refer to non-passenger automobiles as light trucks.
In enacting EPCA and after considering the variety of approaches
presented in the 1974 Report, Congress made a clear and specific choice
about the structure of the average fuel economy standard for passenger
cars. Congress established a common statutory CAFE standard applicable
to each manufacturer's fleet of passenger automobiles.
Congress was considerably less decided and prescriptive with
respect to what sort of standards and procedures should be established
for light trucks. It neither made a clear choice among the approaches
(or among the forms of those approaches) identified in the 1974 Report
nor precluded the selection of any of those approaches or forms.
Further, it did not establish by statute a CAFE standard for light
trucks. Instead, Congress provided the Secretary with a choice of
establishing a form of a production-weighted average standard for each
manufacturer's entire fleet of light trucks, as suggested in the 1974
Report, or a form of production-weighted standards for classes of light
trucks. Congress directed the Secretary to establish maximum feasible
CAFE standards applicable to each manufacturer's light truck fleet, or
alternatively, to classes of light trucks, and to establish them at
least 18 months prior to the start of each model year. When determining
a ``maximum feasible level of fuel economy,'' the Secretary is directed
to balance factors including the nation's need to conserve energy,
technological feasibility, economic practicability and the impact of
other motor vehicle standards on fuel economy.
C. 1979-2002 Light Truck Standards
NHTSA established the first light truck CAFE standards for MY 1979
and applied them to light trucks with a GVWR up to 6,000 pounds (March
14, 1977; 42 FR 13807). Beginning with MY 1980, NHTSA raised this GVWR
ceiling to 8,500 pounds. For MYs 1979-1981, the agency established
separate standards for two-wheel drive (2WD) and four-wheel drive (4WD)
light trucks without a ``combined'' standard reflecting the combined
capabilities of 2WD and 4WD light trucks. Manufacturers that produced
both 2WD vehicles and 4WD vehicles could, however, decide to treat them
as a single fleet and comply with the 2WD standard.
Beginning with MY 1982, NHTSA established a combined standard
reflecting the combined capabilities of 2WD and 4WD light trucks, plus
optional 2WD and 4WD standards. Manufacturers had the option of
complying under the combined fleet standard, or under the separate 2WD
and 4WD standards. Although the combined standard reflected the
combined capabilities of 2WD and 4WD light trucks, it did not
necessarily reflect the combined capabilities of the 2WD and 4WD fleets
of an individual manufacturer (e.g., a manufacturer may have found it
easier to comply with the combined standard than the 2WD and 4WD
standards separately, or vice versa). After MY 1991, NHTSA dropped the
optional 2WD and 4WD standards.
As explained in the NPRM, NHTSA twice found it necessary to reduce
a light truck standard when it received new information relating to the
agency's past projections. In 1979, the agency reduced the MY 1981 2WD
standard after Chrysler demonstrated that there were smaller than
expected fuel economy benefits from various technological improvements
and larger than expected adverse impacts from other federal vehicle
standards and test procedures (December 31, 1979; 44 FR 77199).
In 1984, the agency reduced the MY 1985 light truck standards after
we concluded that market demand for light truck performance, as
reflected in engine mix and axle ratio usage, had not materialized as
anticipated when the agency initially established the MY 1985
standards. The agency said that this resulted from lower than
anticipated fuel prices. The agency concluded that the only actions
then available to manufacturers to improve their fuel economy levels
for MY 1986 would have involved product restrictions likely resulting
in significant adverse economic impacts. The reduction of the MY 1985
standard was upheld by the U.S. Circuit Court of Appeals for the
District of Columbia. Center for Auto Safety v. NHTSA, 793 F.2d 1322
(D.C. Cir. 1986) (rejecting the contention that the agency gave
impermissible weight to the effects of shifts in consumer demand toward
larger, less fuel-efficient trucks on the fuel economy levels
manufacturers could achieve).\10\
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\10\ NHTSA similarly found it necessary on occasion to reduce
the passenger car CAFE standards in response to new information. The
agency reduced the MY 1986 passenger car standard because a
continuing decline in gasoline prices prevented a projected shift in
consumer demand toward smaller cars and smaller engines and because
the only actions available to manufacturers to improve their fuel
economy levels for MY 1986 would have involved product restrictions
likely resulting in significant adverse economic impacts. (October
4, 1985; 40 FR 40528) This action was upheld in Public Citizen v.
NHTSA, 848 F.2d 256 (D.C. Cir. 1988). NHTSA also reduced the MY
1987-88 passenger car standards (October 6, 1986; 51 FR 35594) and
MY 1989 passenger car standard (October 6, 1988; 53 FR 39275) for
similar reasons.
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On November 15, 1995, the Department of Transportation and Related
Agencies Appropriations Act for FY 1996 was enacted, which limited the
ability of the agency to establish CAFE standards for light trucks
(Section 330, Pub. L. 104-50). Pursuant to that Act, we then issued a
final rule limited to MY 1998, setting the light truck CAFE standard
for that year at 20.7 mpg, the same level as the standard we had set
for MY 1997 (61 FR 14680; April 3, 1996). The same limitation on the
setting of CAFE standards was included in the Appropriations Acts for
each of FYs 1997-2001. The agency followed the same process as for MY
1998, established the light truck CAFE standard at 20.7 mpg, for MYs
1999-2002.
[[Page 17572]]
While the Department of Transportation and Related Agencies
Appropriations Act for FY 2001 (Pub. L. 106-346) contained a
restriction on CAFE rulemaking identical to that contained in prior
appropriation acts, the conference committee report for that Act
directed NHTSA to fund a study by the NAS to evaluate the effectiveness
and impacts of CAFE standards (H. Rep. No. 106-940, at p. 117-118).
In a letter dated July 10, 2001, following the release of the
President's National Energy Policy, Secretary of Transportation Mineta
asked the House and Senate Appropriations Committees to lift the
restriction on the agency spending funds for the purposes of improving
CAFE standards. The Department of Transportation and Related Agencies
Appropriations Act for FY 2002 (Pub. L. 107-87), which was enacted on
December 18, 2001, did not contain a provision restricting the
Secretary's authority to prescribe fuel economy standards.
D. 2001 National Energy Policy
The National Energy Policy,\11\ released in May 2001, stated that
``(a) fundamental imbalance between supply and demand defines our
nation's energy crisis'' and that ``(t)his imbalance, if allowed to
continue, will inevitably undermine our economy, our standard of
living, and our national security.'' The National Energy Policy was
designed to promote dependable, affordable and environmentally sound
energy for the future. The Policy envisions a comprehensive long-term
strategy that uses leading edge technology to produce an integrated
energy, environmental and economic policy. It set forth five specific
national goals: ``modernize conservation, modernize our energy
infrastructure, increase energy supplies, accelerate the protection and
improvement of the environment, and increase our nation's energy
security.''
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\11\ https://www.whitehouse.gov/energy/National-Energy-
Policy.pdf.
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The National Energy Policy included recommendations regarding the
path that the Administration's energy policy should take and included
specific recommendations regarding vehicle fuel economy and CAFE. It
recommended that the President direct the Secretary of Transportation
to--
--Review and provide recommendations on establishing CAFE standards
with due consideration of the National Academy of Sciences study
released (in prepublication form) in July 2001. Responsibly crafted
CAFE standards should increase efficiency without negatively impacting
the U.S. automotive industry. The determination of future fuel economy
standards must therefore be addressed analytically and based on sound
science.
--Consider passenger safety, economic concerns, and disparate impact on
the U.S. versus foreign fleet of automobiles.
--Look at other market-based approaches to increasing the national
average fuel economy of new motor vehicles.
E. 2002 NAS Study of CAFE Reform
In response to direction from Congress, NAS published a lengthy
report in 2002 entitled ``Effectiveness and Impact of Corporate Average
Fuel Economy (CAFE) Standards.'' \12\
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\12\ The NAS submitted its preliminary report to the Department
of Transportation in July 2001 and released its final report in
January 2002.
---------------------------------------------------------------------------
The report concludes that the CAFE program has clearly contributed
to increased fuel economy and that it was appropriate to consider
further increases in CAFE standards. (NAS, p. 3 (Finding 1)) It cited
not only the value of fuel savings, but also adverse consequences
(i.e., externalities) associated with high levels of petroleum
importation and use that are not reflected in the price of petroleum
(e.g., the adverse impact on energy security). The report further
concluded that technologies exist that could significantly reduce fuel
consumption by passenger cars and light trucks within 15 years, while
maintaining vehicle size, weight, utility and performance. (NAS, p. 3
(Finding 5)) Light duty trucks were said to offer the greatest
potential for reducing fuel consumption. (NAS, p. 4 (Finding 5)) The
report also noted that vehicle development cycles--as well as future
economic, regulatory, safety and consumer preferences--would influence
the extent to which these technologies could lead to increased fuel
economy in the U.S. market. The report noted that the widespread
penetration of even existing technologies will probably require 4-8
years. To assess the economic trade-offs associated with the
introduction of existing and emerging technologies to improve fuel
economy, the NAS conducted what it called a ``cost-efficient
analysis''--``that is, the committee [that authored the report]
identified packages of existing and emerging technologies that could be
introduced over the next 10 to 15 years that would improve fuel economy
up to the point where further increases in fuel economy would not be
reimbursed by fuel savings.'' (NAS, p. 4 (Finding 6))
Recognizing the many trade-offs that must be considered in setting
fuel economy standards, the report took no position on what CAFE
standards would be appropriate for future years. It noted,
``(s)election of fuel economy targets will require uncertain and
difficult trade-offs among environmental benefits, vehicle safety,
cost, oil import dependence, and consumer preferences.''
The report found that, to minimize financial impacts on
manufacturers, and on their suppliers, employees, and consumers,
sufficient lead-time (consistent with normal product life cycles)
should be given when considering increases in CAFE standards. The
report stated that there are advanced technologies that could be
employed, without negatively affecting the automobile industry, if
sufficient lead-time were provided to the manufacturers.
The report expressed concerns about increasing the standards under
the CAFE program as currently structured. While raising CAFE standards
under the existing structure would reduce fuel consumption, doing so
under alternative structures ``could accomplish the same end at lower
cost, provide more flexibility to manufacturers, or address inequities
arising from the present'' structure. (NAS, pp. 4-5 (Finding 10))\13\
Further, the committee said, ``to the extent that the size and weight
of the fleet have been constrained by CAFE requirements * * * those
requirements have caused more injuries and fatalities on the road than
would otherwise have occurred.'' (NAS, p. 29) Specifically, they noted:
``the downweighting and downsizing that occurred in the late 1970s and
early 1980s, some of which was due to CAFE standards, probably resulted
in an additional 1300 to 2600 traffic fatalities in 1993.'' (NAS, p. 3
(Finding 2)).
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\13\ The report noted the following about the concept of equity:
Potential Inequities
The issue of equity or inequity is subjective. However, one
concept of equity among manufacturers requires equal treatment of
equivalent vehicles made by different manufacturers. The current
CAFE standards fail this test. If one manufacturer was positioned in
the market selling many large passenger cars and thereby was just
meeting the CAFE standard, adding a 22-mpg car (below the 27.5-mpg
standard) would result in a financial penalty or would require
significant improvements in fuel economy for the remainder of the
passenger cars. But, if another manufacturer was selling many small
cars and was significantly exceeding the CAFE standard, adding a 22-
mpg vehicle would have no negative consequences.
(NAS, p. 102).
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To address those structural problems, the report suggested various
possible
[[Page 17573]]
reforms.\14\ The report found that the ``CAFE program might be improved
significantly by converting it to a system in which fuel targets depend
on vehicle attributes.'' (NAS, p. 5 (Finding 12)). The report noted
that a system in which fuel economy targets were dependent on vehicle
weight, with lower fuel consumption targets set for lighter vehicles
and higher targets for heavier vehicles, up to some maximum weight,
would create incentives to reduce the variance in vehicle weights
between large and small vehicles, thus providing for overall vehicle
safety. (NAS, p. 5 (Finding 12)). The report stated that such a system
has the potential to increase fuel economy with fewer negative effects
on both safety and consumer choice.
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\14\ In assessing and comparing possible reforms, the report
urged consideration of the following factors:
Fuel use responses encouraged by the policy,
Effectiveness in reducing fuel use,
Minimizing costs of fuel use reduction,
Other potential consequences
--Distributional impacts
--Safety
--Consumer satisfaction
--Mobility
--Environment
--Potential inequities, and Administrative feasibility.
(NAS, p. 94).
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The report noted further that under an attribute-based approach,
the required CAFE levels could vary among the manufacturers based on
the distribution of their product mix. NAS stated that targets could
vary among passenger cars and among trucks, based on some attribute of
these vehicles such as weight, size, or load-carrying capacity. The
report explained that a particular manufacturer's average target for
passenger cars or for trucks would depend upon the fractions of
vehicles it sold with particular levels of these attributes (NAS, p.
87). For example, if weight were the criterion, a manufacturer that
sells mostly light vehicles would have to achieve higher average fuel
economy than would a manufacturer that sells mostly heavy vehicles.
The report illustrated an example of an attribute-based system
using a continuous function (NAS, p. 109). Essentially, as illustrated,
the continuous function was represented as a line, which graphed
``gallons per mile'' versus ``curb weight.'' Under the continuous
function example, a vehicle's target fuel economy would be determined
by locating the vehicle's curb weight along the line and identifying
the corresponding gallons per mile value.
In February 2002, Secretary Mineta asked Congress ``to provide the
Department of Transportation with the necessary authority to reform the
CAFE program, guided by the NAS report's suggestions.''
F. 2003 Final Rule Establishing MY 2005-2007 Light Truck Standards
On April 7, 2003, the agency published a final rule establishing
light truck CAFE standards for MYs 2005-2007: 21.0 mpg for MY 2005,
21.6 mpg for MY 2006, and 22.2 mpg for MY 2007 (68 FR 16868; Docket No.
2002-11419; Notice 3). The agency determined that these levels are the
maximum feasible CAFE levels for light trucks for those model years,
balancing the express statutory factors and other included or relevant
considerations such as the impact of the standard on motor vehicle
safety and employment. NHTSA estimated that the fuel economy increases
required by the standards for MYs 2005-2007 would generate
approximately 3.6 billion gallons of gasoline savings over the 25-year
lifetime of the affected vehicles.
We recognized in the final rule that the standard established for
MY 2007 could be a challenge for General Motors. We recognized further
that, between the issuance of the final rule and the last (MY 2007) of
the model years for which standards were being established, there was
more time than in previous light truck CAFE rulemakings for significant
changes to occur in external factors capable of affecting the
achievable levels of CAFE. These external factors include fuel prices
and the demand for vehicles with advanced fuel saving technologies,
such as hybrid electric and advanced diesel vehicles. We said that
changes in these factors could lead to higher or lower levels of CAFE,
particularly in MY 2007. Recognizing that it may be appropriate to re-
examine the MY 2007 standard in light of any significant changes in
those factors, the agency reaffirms its plans to monitor the compliance
efforts of the manufacturers.
G. 2003 Comprehensive Plans for Addressing Vehicle Rollover and
Compatibility
In September 2002, NHTSA completed a thorough examination of the
opportunities for significantly improving vehicle and highway safety
and announced the establishment of interdisciplinary teams to formulate
comprehensive plans for addressing the four most promising problem
areas.\15\ Based on the work of the teams, the agency issued detailed
reports analyzing each of the problem areas and recommending
coordinated strategies that, if implemented effectively, will lead to
significant improvements in safety.
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\15\ A fifth problem area was announced in 2004, improving
traffic safety data.
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Two of the problems areas are vehicle rollover and vehicle
compatibility. The reports on those areas identify a series of vehicle,
roadway and behavioral strategies for addressing the problems.\16\
Among the vehicle strategies, both reports identified reform of the
CAFE program as one of the steps that needed to be taken to reduce
those problems:
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\16\ See https://www-nrd.nhtsa.dot.gov/vrtc/ca/capubs/
IPTRolloverMitigationReport/; https://www-nrd.nhtsa.dot.gov/
departments/nrd-11/aggressivity/IPTVehicleCompatibilityReport/.
The current structure of the CAFE system can provide an
incentive to manufacturers to downweight vehicles, increase
production of vehicle classes that are more susceptible to rollover
crashes, and produce a less homogenous fleet mix. As a result, CAFE
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is critical to the vehicle compatibility and rollover problems.
Recognizing the role of CAFE, we stated:
It is NHTSA's goal to identify and implement reforms to the CAFE
system that will facilitate improvements in fuel economy without
compromising motor vehicle safety or American jobs. * * *
* * * NHTSA intends to examine the safety impacts, both positive and
negative, that may result from any modifications to CAFE as it now
exists. Regardless of the root causes, it is clear that the
downsizing of vehicles that occurred during the first decade of the
CAFE program had serious safety consequences. Changes to the
existing system are likely to have equally significant impacts.
NHTSA is determined to ensure that these impacts are positive.
H. 2003 ANPRM
On December 29, 2003, the agency published an ANPRM seeking comment
on various issues relating to reforming the CAFE program (68 FR 74908;
Docket No. 2003-16128).\17\ The agency sought comment on possible
enhancements to the program that would assist in further fuel
conservation, while protecting motor vehicle safety and the economic
vitality of the automobile industry. The agency indicated that it was
particularly interested in structural reform. That document, while not
espousing any particular form of reform, sought specific input on
various options aimed
[[Page 17574]]
at adapting the CAFE program to today's vehicle fleet and needs.
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\17\ On the same date, we also published a request for comments
seeking manufacturer product plan information for MYs 2008-2012 to
assist the agency in analyzing possible reforms to the CAFE program
which are discussed in a companion notice published today. (68 FR
74931) The agency sought information that would help it assess the
effect of these possible reforms on fuel economy, manufacturers,
consumers, the economy, motor vehicle safety and American jobs.
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1. Need for Reform
The 2003 ANPRM discussed the principal criticisms of the current
CAFE program that led the agency to explore light truck CAFE reform (68
FR 74908, at 74910-13). First, the energy-saving potential of the CAFE
program is hampered by the current regulatory structure. The Unreformed
approach to CAFE does not distinguish between the various market
segments of light trucks, and therefore does not recognize that some
vehicles designed for classification purposes as light trucks may
achieve fuel economy similar to that of passenger cars. The Unreformed
CAFE approach instead applies a single standard to the light truck
fleet as a whole, encouraging manufacturers to offer small light trucks
that will offset the larger vehicles that get lower fuel economy. A
CAFE system that more closely links fuel economy standards to the
various market segments reduces the incentive to design vehicles that
are functionally similar to passenger cars but classified as light
trucks.
Second, because weight strongly affects fuel economy, the current
light truck CAFE program encourages vehicle manufacturers to reduce
weight in their light truck offerings to achieve greater fuel
economy.\18\ As the NAS report and a more recent NHTSA study have
found, downweig
