The
EPA Automotive
Trends Report
Greenhouse Gas Emissions,
Fuel Economy, and
Technology since 1975
Executive Summary
United States
Environmental Protection
Agency
EPA-420-S-21-002 November 2021
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This technical report does not necessarily represent final EPA decisions, positions, or validation of
compliance data reported to EPA by manufacturers. It is intended to present technical analysis of issues
using data that are currently available and that may be subject to change. Historic data have been
adjusted, when appropriate, to reflect the result of compliance investigations by EPA or any other
corrections necessary to maintain data integrity.
The purpose of the release of such reports is to facilitate the exchange of technical information and to
inform the public of technical developments. This edition of the report supersedes all previous versions.
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Executive Summary
This annual report is part of the U.S. Environmental Protection Agency's (EPA) commitment
to provide the public with information about new light-duty vehicle greenhouse gas (GHG)
emissions, fuel economy, technology data, and auto manufacturers' performance in meet-
ing the agency's GHG emissions standards.
EPA has collected data on every new light-duty vehicle model sold in the United States since
1975, either from testing performed by EPA at the National Vehicle and Fuel Emissions
Laboratory in Ann Arbor, Michigan, or directly from manufacturers using official EPA test
procedures. These data are collected to support several important national programs,
including EPA criteria pollutant and GHG standards, the U.S. Department of Transportation's
National Highway Traffic Safety Administration (NHTSA) Corporate Average Fuel Economy
(CAFE) standards, and vehicle Fuel Economy and Environment labels. This expansive data
set allows EPA to provide a uniquely comprehensive analysis of the automotive industry
over the last 45 years.
The carbon dioxide (C02) emissions and fuel economy data in this report fall into one of
two categories. The first is compliance data, which are measured using laboratory tests
required by law for CAFE and adopted by EPA for GHG compliance. The second is estimated
real-world data, which are measured using additional laboratory tests to capture a wider
range of operating conditions (including hot and cold weather, higher speeds, and faster
accelerations) encountered by an average driver. This report shows real-world data, except
for discussions specific to GHG compliance on pages ES-9 to ES-12 in this summary and
Section 5 of the report.
All data in this report for model years 1975 through 2020 are final and based on official
data submitted to EPA and NHTSA as part of the regulatory process. In some cases, this
report will show data for model year 2021, which are preliminary and based on data
provided to EPA by automakers prior to the model year, including projected production
volumes. Given the impacts of COVID-19 and worldwide supply chain issues, and their
associated impacts on the automobile industry, the projected model year 2021 data may
change significantly before being finalized.
This report reflects the current light-duty GHG and fuel economy regulations as finalized
by EPA and NHTSA. In August 2021, EPA and NHTSA proposed rules to revise the existing
light-duty GHG and fuel economy standards for model years 2023-2026 and 2024-2026,
respectively. Since these proposals have not been finalized, they are not reflected in this
report. Any applicable regulatory changes finalized by EPA and NHTSA will be included in
future versions of this report. To download the full report, or to explore the data using
EPA's interactive data tools, visit the report website at www.epa.gov/automotive-trends.
ES-1
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New vehicle estimated real-world CO2 emissions are
at a record low and fuel economy is at a record high
In model year 2020, the average
estimated real-world C02 emission rate
for all new vehicles fell by 7 g/mi to 349
g/mi, the lowest ever measured. Fuel
economy increased by 0.5 mpg to 25.4,
achieving a record high.
Since model year 2004, C02 emissions
have decreased 24%, or 112 g/mi, and
fuel economy has increased 32%, or 6.1
mpg. Over that time, C02 emissions and
fuel economy have improved in thirteen
out of sixteen years. The trends inC02
emissions and fuel economy since 1975
are shown in Figure ES-1.
Preliminary data suggest that C02
emissions and fuel economy in model
year 2021 will remain near the levels
achieved in 2020. These data are shown
in Figure ES-1 as a dot because the
values are based on manufacturer
projections rather than final data.
Figure ES-1. Estimated Real-World Fuel
Economy and C02 Emissions
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1975
1985
1995
2005
2015
2025
All vehicle types are at record low CO2 emissions;
however, market shifts away from cars and towards
sport utility vehicles (SUVs] and pickups have offset
some of the fleetwide benefits
In this report, vehicles are disaggregated into five vehicle types: sedan/wagon, car SUV,
truck SUV, pickup truck, and minivan/van. The distinction between car and truck SUVs is
based on regulatory definitions where SUVs that are 4WD or above a weight threshold
(6,000 pounds gross vehicle weight) are generally regulated as trucks and classified at truck
SUVs for this report. The remaining 2WD SUVs are subject to car standards and classified as
ES-2
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car SUVs. All five vehicle types are at record high fuel economy and record low C02
emissions in model year 2020. Minivan/Vans, car SUVs, and sedan/wagons all increased
fuel economy by 0.9 mpg, while truck SUVs increased by 0.3 mpg, and pickups increased
by 0.2 mpg.
The overall new vehicle market continues to move away from the sedan/wagon vehicle
type towards a combination of truck SUVs and car SUVs. Sedans and wagons fell to 31 % of
the market, well below the 50% market share they held as recently as model year 2013, and
far below the 80% market share they held in 1975. Conversely, truck SUVs reached a record
39% of the market in model year 2020, and car SUVs reached a record 13% of the market.
The trend away from sedan/wagons, which remain the vehicle type with the highest fuel
economy and lowest C02 emissions, and towards vehicle types with lower fuel economy
and higher C02 emissions has offset some of the fleetwide benefits that otherwise would
have been achieved from the improvements within each vehicle type.
Figure ES-2. Production Share and Fuel Economy by Vehicle Type
75% H
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1975 1985 1995 2005 2015 2025
Model Year
Sedan/Wagon
Car SUV
100% -
Sedan
Wagon
Car
SUV
Truck
SUV
Minivan
Van
Average new vehicle fuel economy, horsepower,
weight, and footprint are all at record highs
Overall vehicle trends are influenced both by vehicle technology and design, and by the
changes in the distribution of vehicles being produced. For a specific vehicle, increased
weight or horsepower is likely to result in higher C02 emissions and lower fuel economy,
ES-3
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all else being equal. Larger vehicles, in this case measured by footprint or the area enclosed
by the four tires, also tend to have higher C02 emissions and lower fuel economy. Footprint
is also the basis for determining regulatory standards under the GHG and CAFE regulations.
Electric vehicles produce zero tailpipe emissions; however, weight, horsepower, and vehicle
size can still impact the vehicle fuel economy (as measured in miles per gallon of gasoline
equivalent).
In the two decades prior to 2004,
technology innovation and mar-
ket trends generally resulted
in increased vehicle power and
weight (due to increasing vehicle
size and content) while average
new vehicle fuel economy steadily
decreased and C02 emissions
correspondingly increased. Since
model year 2004, the combina-
tion of technology innovation
and market trends have resulted
in average new vehicle fuel
economy increasing 32%, horse-
power increasing 17%, and weight
increasing 1%. Footprint has
increased 4% since EPA began
tracking it in model year 2008.
These metrics are all at record
highs, and horsepower, weight,
and footprint are projected to in-
crease again in model year 2021,
as shown in Figure ES-3.
Between model year 2008 and 2020, fuel economy and footprint increased within each of the
five vehicle types, and horsepower increased in four. Weight decreased within each of the
vehicle types. These trends within vehicle types are largely attributable to design and tech-
nology changes over that time span. In addition to technology changes, the market shifted
towards car and truck SUVs, which are often larger, heavier, more powerful, and less fuel
efficient than sedan/wagons they replaced. These market changes increased the overall
horsepower and footprint of the average new vehicle, compared to technology-driven changes
alone. The trend towards larger, heavier, and more powerful vehicles has also offset some
of the fleetwide fuel economy and C02 emission benefits that otherwise would have been
achieved through improving technology. Market trends led to an increase in the weight of a
new average vehicle, even as weight fell within each vehicle type.
8S ESz4
Figure ES-3. Percent Change in Real-World Fuel
Economy, Horsepower, Weight, and Footprint
100%-
75% -
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Real-World Fuel Economy
HorseDower
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-ootprint
1975 1980 1985 1990 1995 2000 2005 2010 2015 2020 2025
Model Year
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Most manufacturers have improved CO2 emissions
and fuel economy over the last 5 years
Manufacturer trends over the last five years are shown in Figure ES-4. This span covers
the approximate length of a vehicle redesign cycle, and it is likely that most vehicles
have undergone design changes in this period, resulting in a more accurate depiction
of recent manufacturer trends than focusing on a single year. Changes over this time
period can be attributed to changes in both vehicle design and the significant change to
the mix of vehicle types produced, as shown in ES-2.
Over the last five years, eight of the fourteen largest manufacturers selling vehicles
in the U.S. decreased new vehicle estimated real-world C02 emission rates. Tesla was
unchanged because their all-electric fleet produces no tailpipe C02 emissions. Between
model years 2015 and 2020, Toyota achieved the largest reduction in C02 emissions, at
27 g/mi. Toyota decreased emissions in all vehicle types, and their mix of vehicle types
produced in model years 2015 and 2020 was similar. Kia achieved the second largest
reduction in overall C02 tailpipe emissions, even as their production share of more
efficient sedan/wagons fell from 75% to 53%, and less efficient truck SUVs increased
from 3% to 36% of all production. GM had the third largest reduction in overall C02
tailpipe emissions, while their production share of sedan/wagons fell from 31 % to 13%
and truck SUVs increased from 28% to 39% of all production.
Five manufacturers increased new vehicle C02 emission rates between model years
2015 and 2020. Volkswagen and Mazda tied for the largest increase at 15 g/mi. Volks-
wagen achieved reductions in C02 emissions in both sedan/wagon and truck SUVs
vehicle types; however, that was more than offset by a reduction in their production
share of sedan/wagons, from 79% to 40%, and a corresponding increase in truck SUVs
from 19% to 58%. Mazda had similar trends, as a drop in sedan/wagon production
share from 57% to 24%, a corresponding increase in car and truck SUV production
share, and an increase in sedan/wagon C02 emissions offset reductions in C02
emissions from both car SUVs and truck SUVs.
For model year 2020 alone, Tesla's all-electric fleet had by far the lowest tailpipe C02
emissions and highest fuel economy of all large manufacturers. Tesla was followed by
Honda, Subaru, and Hyundai. Stellantis had the highest new vehicle average C02
emissions and lowest fuel economy of the large manufacturers in model year 2020,
followed by Ford and GM.
ES-5
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Figure ES-4. Changes in Estimated Real-World Fuel Economy1 and C02 Emissions for Large Manufacturers
Fuel Economy (MPG), 2015 - 2020
CO Emissions (g/mi), 2015 - 2020
Tesla
Honda
Subaru
Hyundai
Nissan
Mazda
Kia
Toyota
BMW
VW
Mercedes
GM
Ford
Stellantis
All Manufacturers
97.1 119.1
60
80
100
120
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1 Electric vehicles, including Tesla's all-electric fleet, are measured in terms of miles per gallon of gasoline equivalent, or mpge.
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Manufacturers continue to adopt a wide array of
advanced technologies
Innovation in the automobile industry has led to a wide array of technology available
to manufacturers to achieve C02 emissions, fuel economy, and performance goals.
Figure ES-5 illustrates manufacturer-specific technology adoption for model year 2020,
with larger circles representing higher adoption rates. The technologies in Figure ES-5
are all being adopted by manufacturers to in part reduce C02 emissions and increase
fuel economy. Each of the fourteen largest manufacturers have adopted several of
these technologies into their vehicles, with many manufacturers achieving very high
penetrations of several technologies. It is also clear that manufacturers' strategies to
develop and adopt new technologies are unique and vary significantly. Each manufac-
turer is choosing technologies that best meet the design requirements of their vehicles,
and in many cases, that technology is changing quickly.
Engine technologies such as turbocharged engines (Turbo) and gasoline direct injection
(GDI) allow for more efficient engine design and operation. Cylinder deactivation (CD)
allows for use of only a portion of the engine when less power is needed, while stop/
start systems can turn off the engine entirely at idle to save fuel. Hybrid vehicles use
a larger battery to recapture braking energy and provide power when necessary,
allowing for a smaller, more efficiently operated engine. The hybrid category includes
"full" hybrid systems that can temporarily power the vehicle without engaging the
engine and smaller "mild" hybrid systems that cannot propel the vehicle on their own.
Transmissions that have more gear ratios, or speeds, allow the engine to more fre-
quently operate near peak efficiency. Two categories of advanced transmissions are
shown in Figure ES-5: transmission with seven or more discrete speeds (7+Gears), and
continuously variable transmissions (CVTs).
ES-7
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Electric vehicles (EVs), plug-in hybrid vehicles (PHEVs), and fuel cell vehicles (FCVs) are
a small but growing percentage of new vehicles. Projected data for model year 2021
supports this, as EVs, PHEVs, and FCVs are projected to grow to 4% of all new vehicles. Hy-
brids (not including PHEVs) are also projected to grow significantly in model year 2021, to
9% of all vehicles produced. Hybrid production is expected to grow in most
vehicle types, including truck SUVs and pickups. Approximately one third of these
hybrids are projected to be mild hybrids.
Figure ES-5. Technology Share for Large Manufacturers, Model Year 2020
Tesla -
Honda -
Subaru -
Hyundai -
Nissan -
Mazda -
Kia -
Toyota -
BMW -
VW -
Mercedes -
GM -
Ford -
Stellantis -
All Manufacturers -
Turbo GDI CVT 7+Gears Non-hybrid CD Hybrid PHEV/
StopStart EV/FC
100%
50% 79% 64% 29% 11% 24% 5% 0%
24% 98% 94% 63% 1%
14% 65% 29% 44% 22% 2% 1%
4% 54% 89% 10% 1%
17% 100% 64%
5% 63% 35% 26% 33% 2% 1%
3% 1% 32% 42% 15% 13% 1%
99% 99% 98% 94% 2%
92% 98% 91% 88% 2% 6% 3%
99% 100% 100% 81% 6% 13% 0%
43% 87% 9% 56% 70% 44% 1%
79% 63% 4% 81% 88% 10% 3% 0%
10% 9% 1% 92% 56% 23% 10% 1%
35% 57% 28% 52% 46% 15% 5% 2%
ES-8
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All fourteen large manufacturers achieved compliance
with the GHG standards through model year 2020
EPA's GHG program is an averaging, banking, and trading (ABT) program. An ABT program
means that the standards may be met on a fleet average basis, manufacturers may earn
and bank credits to use later, and manufacturers may trade credits with other manufac-
turers. This provides manufacturers flexibility in meeting the standards while accounting
for vehicle design cycles, introduction rates of new technologies and emission improve-
ments, and evolving consumer preferences.
Within a model year, manufac-
turers with average fleet emis-
sions lower than the standards
generate credits, and manufac-
turers with average fleet emis-
sions higher than the standards
generate deficits. Any manufac-
turer with a deficit at the end of
the model year has up to three
years to offset the deficit with
credits earned in future model
years, or purchased from
another manufacturer.
The fourteen largest manufac-
turers ended model year 2020
with positive credit balances
and are thus in compliance for
model year 2020 and all previ-
ous years of the GHG program,
as credits may not be carried
forward unless deficits from all
prior model years have been
resolved.
Figure ES-6. GHG Credit Balance for Large Manufacturers,
after Model Year 2020
Stellantis -
Honda -
Toyota -
GM -
Subaru -
Nissan -
Ford -
Hyundai -
Mazda
BMW
Mercedes
VW
Kia
Tesla
I
Credits Expiring 2025
| Credits Expiring 2024
Credits Expiring 2023
Credits Expiring 2022
Credits Expiring 2021
10 20 30
GHG Credits (Tg of CO,
40
50
Total credits in Figure ES-6 are shown in teragrams (one million Megagrams), and account
for manufacturer performance compared to their standards, expected vehicle lifetime
miles driven, and the number of vehicles produced by each manufacturer, for all years of
the GHG program. The credits accumulated by each manufacturer will be carried forward
for use in future model years or until they expire. Credit expiration dates are based on the
model year in which they were earned.
ES-9
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Most large manufacturers used banked or purchased
credits to maintain compliance in model year 2020
Manufacturers used different combinations of technology improvements, banked credits,
and purchased credits to achieve compliance in 2020. Tesla, Honda, and Subaru achieved
compliance based on the emission performance of their vehicles, without requiring
additional banked credits. All other large manufacturers used banked or purchased credits,
along with technology improvements, to achieve compliance in model year 2020.
Figure ES-7 illustrates the performance of individual large manufacturers in model year
2020 compared to their overall standard, in terms of an average vehicle grams per mile
emission rate. This "snapshot" provides insight into how the large manufacturers
performed against the standards in model year 2020. However, it does not account for
the fact that all large manufacturers had credits available from previous years, or they
were able to purchase credits to ensure their credit balance remained positive after
model year 2020.
Figure ES-7. C02 Performance and Standards by Manufacturer, Model Year 2020
Below Standard Above Standard
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Performance
ES-10
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The manufacturer performance values shown in Figure ES-7 are based on the average
new vehicle tailpipe emissions for each manufacturer and also include various
optional credits available to manufacturers in model year 2020. One notable provision
in the regulations is an incentive multiplier that increases the credits each electric
vehicle creates. The impact of this incentive is particularly evident for Tesla, since Tesla
produces only electric vehicles, and led to the negative performance value for Tesla
shown in Figure ES-7.
The overall industry used credits for the fifth year
in a row to maintain compliance, and there remains
a large bank of credits for future years
Under the GHG Program, manufacturers were able to accrue "early credits," before
the GHG standards took effect in model year 2012, for early deployment of efficient
vehicles and technology. For the next four years, manufacturers continued to generate
credits, as the industry GHG performance was below the industry-wide average standard.
In the last five years, the industry GHG performance has been above the industry-wide
average standard, resulting in net withdrawals from the bank of credits to maintain
compliance. In model year 2020, the industry decreased overall GHG performance to
245 g/mi, while the standard fell from 246 g/mi to 239 g/mi. The gap between the stan-
dard and GHG performance fell from 7 g/mi in model year 2019 to 6 g/mi in model year
2020. To maintain compliance the industry drew down their industry-wide total credit
bank by about 18 Tg, which was less than 10% of the total available credit balance. The
overall industry emerged from model year 2020 with a bank of 212 teragrams (Tg) of
GHG credits available for future use, as seen in Figure ES-8.
In addition to the balance of the industry-wide bank, the expiration date and distribution
of credits are also important factors. Credits earned in model year 2016 or beyond have
a five-year life, while all prior credits (half of the current bank) will expire at the end of
model year 2021. At the present time, an active credit market is enabling manufacturers
to purchase credits to demonstrate compliance, with nine manufacturers selling credits,
nine manufacturers purchasing credits, and approximately 80 credit trades since 2012.
ES-11
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Figure ES-8. Industry Performance and Standards, Credit Generation and Use
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(2009-2011) ,, 1W 2021
v ' Model Year
The automobile industry continues to innovate,
improve, and meet the GHG standards
The analysis here is a snapshot of the data collected by EPA in support of several important
regulatory programs and is presented with the intent of providing as much transparency
to the public as possible. The data show the change and innovation in the industry since
model year 1975, and the manufacturers' performance under EPA's GHG standards.
To download the full report, or to explore the data using EPA's interactive data tools, visit
the report webpage at www.epa.gov/automotive-trends.
If
ES-12
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