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Appendix C
Data Source and Accuracy Statements
Chapter 1 Extent, Condition, and Performance
TABLE 1-1. System Mileage Within the United States
Highway
The Highway Performance Monitoring System (HPMS) is the source of road mileage
data and is considered reliable. (See box
1-1 for detailed information about the HPMS.) The Federal Highway Administration
(FHWA) of the U.S. Department of Transportation (USDOT) collects and reviews state-reported
HPMS data for completeness, consistency, and adherence to specifications. Some
inaccuracy may arise from variations across states in their adherence to federal
guidelines in the Traffic Monitoring Guide and the Highway Performance Monitoring
System Field Manual for the Continuing Analytical and Statistical Database.
Beginning with the 1997 issue of Highway Statistics, FHWA instituted a new
method for creating mileage-based tables derived from the HPMS. Previously, adjustments
to tables developed from sample data were made using area-wide mileage information
provided by states. These adjustments are now being made using universe totals
from the HPMS dataset. In addition, FHWA has discontinued the process of spreading
rounding and other differences across table cells. Thus, users may note minor
differences in table-to-table totals. FHWA considers mileage totals from table
HM-20, "Public Road Length, Miles by Functional System" to be the controlling
totals should a single value be required.
Reliability may be diminished for comparisons with pre-1980 data, which were
collected via different methods and special national studies. For instance, pre-1980
mileage data included some nonpublic roadways (95,000 miles in 1979) while post-1980
data reports only public road mileage (roads or streets governed and maintained
by a public authority and open to public travel).
Class I Rail
These data are from Railroad Facts, published annually by the Association of
American Railroads (AAR). AAR data are based on 100-percent reporting by Class
I railroads to the Surface Transportation Board (STB) via Schedule 700 of the
R1 Annual Report. The STB defines Class I railroads as having operating revenues
at or above a threshold indexed to a base of $250 million (1991) and adjusted
annually in concert with changes in the Railroad Freight Rate Index published
by the Bureau of Labor Statistics. In 1999, the adjusted threshold for Class I
railroads was $258.5 million. Declassification from Class I status occurs when
a railroad falls below the applicable threshold for three consecutive years. Although
Class I railroads encompasses only 2 percent of the number of railroads in the
country, they account for over 71 percent of the industry's mileage operated.
To obtain railway mileage, AAR subtracts trackage rights from miles of rail
traveled on line 57 in the Schedule 700 report. Historical reliability may vary
due to changes in the railroad industry, including bankruptcies, mergers, and
declassification by the STB. Small data errors may also exist because of because
of independent rounding of this series by AAR.
Amtrak
These statistics originate from the Statistical Appendix to Amtrak’s Annual
Report. Amtrak estimates track mileage based on point-to-point city timetables
that railroad companies provide for engineers. The figures are estimates, but
are considered reliable.
Transit
These figures are based on information in the U.S. Department of Transportation,
Federal Transit Administration (FTA), National Transit Database. Section 15 of
the Federal Transit Act requires federally funded transit agencies to provide
detailed financial and operating data, including
vehicle inventories and directly operated mileage. Transit operators that do
not report to FTA are those that do not receive federal funding, typically private,
small, and rural operators. The data are generally considered accurate because
FTA reviews and validates information submitted by individual transit agencies.
Reliability may vary because some transit agencies cannot obtain accurate information
or may misinterpret certain data definitions.
Navigable Channels
These statistics originate from a mid-1950s U.S. Army Corps of Engineers (USACE)
estimate that there were approximately 25,000 miles of commercially important
navigable channels in the United States. That number has been adjusted from time
to time, for example, by addition of the 234-mile Tennessee-Tombigbee Waterway
in the early 1980s. The 25,000 plus mile number has been universally quoted for
decades, but has definitional and methodological uncertainties. USACE is currently
developing a rigorous, Global Information System (GIS)-based approach to facilitate
tabulation of the lengths of shallow and deep-draft commercially navigable waterways
in the United States; this calculation will be available in several years.
Oil Pipeline
The data are from Transportation in America, published by the Eno Transportation
Foundation, Inc. (Eno). The numbers reprinted here for 1960, 1965, 1970, and 1975
are Eno estimates from the U.S. Department of Energy (DOE) Energy Data Report
issues labeled "Crude-oil and Refined Products Mileage in the United States."
Eno estimated the 1980 number based on the assumption that refinement of old,
less profitable, and smaller lines exceeded in mileage the construction of new,
larger, and more profitable lines. Post-1985 data were calculated using a base
figure reported in a 1982 USDOT study entitled Liquid Pipeline Director and then
combined with data from the Association of Oil Pipe Lines and the Oil Pipeline
Research Institute. Lack of additional information raises definitional and methodological
uncertainties for the data’s reliability. Moreover, the three different information
sources introduce data discontinuities, making time comparisons unreliable.
Gas Pipeline
These statistics originate from annual editions of Gas Facts, published by
the American Gas Association (AGA). The data reported by the AGA are based on
gas utilities participation and reporting to the Uniform Statistical Report. Utilities
reporting represented 98 percent of gas utility industry sales while the remaining
2 percent was estimated for nonreporting companies based on recent historical
experience. Varying percentages of nonreporters from year to year introduce minor
reliability problems for time-series comparisons.
TABLE 1-3. Number of U.S. Airports
The Federal Aviation Administration (FAA), Office of Airport Safety and Standards
Administrator’s Fact Book (annual issues) furnished the data shown in this table
and includes airports certified for air carrier operations with aircraft that
seat 30 or more passengers. These airports include civil and joint civil-military
use airports, heliports, STOLports (short takeoff and landing), and seaplane facilities.
The FAA obtained this data via physical inspections and mail solicitations of
all federally regulated landing facilities. Since this is a census of all U.S.
airports, reliability should be high. Data, however, may be subject to reporting
errors typical of administrative recordkeeping.
TABLE 1-4. Public Road and Street Mileage in the United States by Type of Surface
TABLE 1-5. U.S. Public Road and Street Mileage by Functional System
TABLE 1-6. Estimated U.S. Roadway Lane-Miles by Functional Class
The Highway Performance Monitoring System (HPMS) is the source of road mileage
data and is considered reliable.(See box 1-1 for detailed
information about the HPMS.) The U.S. Department of Transportation, Federal Highway
Administration collects and reviews state-reported HPMS data for completeness,
consistency, and adherence to specifications. Some inaccuracy may arise from variations
across states in their adherence to federal guidelines in the Traffic Monitoring
Guide and the Highway Performance Monitoring System Field Manual for the Continuing
Analytical and Statistical Database.
Beginning with the 1997 issue of Highway Statistics, FHWA instituted a new
method for creating mileage-based tables derived from the HPMS. Previously, adjustments
to tables developed from sample data were made using area-wide mileage information
provided by states. These adjustments are now being made using universe totals
from the HPMS dataset. In addition, FHWA has discontinued the process of spreading
rounding and other differences across table cells. Thus, users may note minor
differences in table-to-table totals. FHWA considers mileage totals from table
HM-20, "Public Road Length, Miles by Functional System" to be the controlling
totals should a single value be required.
Lane-miles are calculated by multiplying the centerline length by the number
of through lanes. Because the HPMS requires that the number of lanes be reported
for all principal arterials, other National Highway System (NHS) roads, and all
standard samples, lane length can be computed for the Interstate, other principal
arterials, and the NHS on a 100-percent basis. For minor arterials, rural major
collectors, and urban collectors, lane length is calculated based on standard
sample sections using the reported number of through lanes, length of section,
and an expansion factor. FHWA uses the expanded sample to check that the centerline
length of a state’s functional system matches the universe functional system length.
If the centerline length and functional system length do not match, FHWA may ask
a state to make adjustments.
Reliability may be diminished for comparisons with pre-1980 data, which were
collected via different methods and special national studies. For instance, pre-1980
mileage data included some nonpublic roadways (95,000 miles in 1979) while post-1980
data reports only public road mileage (roads or streets governed and maintained
by a public authority and open to public travel).
TABLE 1-7. Number of Stations Served by Amtrak and Rail Transit, Fiscal Year
These numbers originate from Amtrak’s Statistical Appendix to Amtrak’s Annual
Report and the U.S. Department of Transportation, Federal Transit Administration’s
National Transit Database.
Amtrak maintains a computer database with a record of every station, locomotive,
and car it operates. Those records include for each vehicle the year built, its
service status (operating or not on a daily basis), and location. These data should
be considered very reliable.
TABLE 1-8. U.S. Oil and Gas Pipeline Mileage
Oil Pipeline
The data are from Transportation in America, published by the Eno Transportation
Foundation, Inc. (Eno). The numbers reprinted here for 1960, 1965, 1970, and 1975
are Eno estimates from the U.S. Department of Energy’s Energy Data Report issues
labeled "Crude-oil and Refined Products Mileage in the United States."
Eno estimated the 1980 number based on the assumption that refinement of old,
less profitable, and smaller lines exceeded in mileage the construction of new,
larger, and more-profitable lines. Figures from 1985 and later years are calculated
from a base figure that Eno obtained from the 1982 U.S. Department of Transportation
study Liquid Pipeline Director and then incorporated that figure with data from
the Association of Oil Pipe Lines and the Oil Pipeline Research Institute. Lack
of additional information raises definitional and methodological uncertainties
for the data’s reliability. Moreover, the three different information sources
introduce data discontinuities making time comparisons less reliable.
Gas Pipeline
These statistics originate from annual editions of Gas Facts published by the
American Gas Association (AGA). The data reported by AGA are based on gas utilities
participation and reporting to the Uniform Statistical Report. Utilities reporting
in 1991 represented 98 percent of total gas utility industry sales while the remaining
2 percent was estimated for the nonreporting companies based on recent historical
experience. Varying percentages of nonreporters from year to year introduce minor
reliability problems for time-series comparisons.
TABLE 1-2. Number of Air Carriers, Railroads, Interstate Motor Carriers, Marine
Operators, and Pipeline Operators
Air Carriers
The data are from the Air Carrier Financial Statistics Quarterly, published
by the Office of Airline Information of the U.S. Department of Transportation,
Bureau of Transportation Statistics (BTS). The Alphabetical List of Air Carriers
by Carrier Group at the beginning of each fourth quarter edition is used to determine
the number of major air carriers and other air carriers in operation at the end
of each calendar year. The publication draws its data from the T-100 and T-100(f)
databases maintained by BTS. These databases include data obtained from a 100-percent
census of BTS Form 41 schedule submissions by large certificated air carriers,
which are carriers that hold a certificate issued under section 401 of the Federal
Aviation Act of 1958 and that (1) operate aircraft designed to have a maximum
passenger seating capacity of more than 60 seats or a maximum payload capacity
of more than 18,000 pounds or (2) that conduct international operations. Carriers
are grouped as major, national, large regional, or medium regional based on their
annual operating revenues. The thresholds were last adjusted July 1, 1999 and
the threshold for major air carriers is currently $1 billion. The table combines
the number of national, large regional, and medium regional air carriers into
the other air carrier category.
Railroads
The Association of American Railroads (AAR)’s Railroad Ten-Year Trends series
is the source for the number of railroads. The number of Class I railroads is
based on 100-percent reporting by Class I railroads to the Surface Transportation
Board (STB) via Schedule 700 of the R1 Annual Report. The STB defines Class I
railroads as having operating revenues at or above a threshold indexed to a base
of $250 million (1991) and adjusted annually in concert with changes in the Railroad
Freight Rate Index published by the Bureau of Labor Statistics. In 1999, the adjusted
threshold for Class I railroads was $258.5 million. Declassification from Class
I status occurs when a railroad falls below the applicable threshold for three
consecutive years. Although Class I railroads encompasses only 2 percent of the
number of railroads in the country, they account for over 71 percent of the industry's
mileage operated.
The Association of American Railroads determines the number of non-Class I
railroads through an annual survey sent to every U.S. freight railroad. By following
up with nonrespondents, the AAR obtains essentially a census of railroads. Use
of the current survey instrument began in 1986.
Interstate Motor Carriers
The Motor Carrier Management Information System (MCMIS), maintained by the
U.S. Department of Transportation, Federal Motor Carrier Safety Administration,
contains information on the safety of all commercial interstate motor carriers
and hazardous material (HM) shippers subject to the Federal Motor Carrier Safety
Regulations and the Hazardous Materials Regulations. All carriers operating in
interstate or foreign commerce within 90 days of beginning operations must submit
a Form MCS-150, Motor Carrier Identification Report. Carriers may also use the
form to update their information. The Motor Carrier Safety Improvement Act of
1999 requires that reports be periodically updated, but not more than once every
two years. MCMIS is updated as soon as information is provided and verified, and
periodic archives are made. Historical data are available from summary information
previously prepared, including tables and reports. MCMIS began operations in 1980.
Safety data since 1990 are available to the public.
Marine Vessel Operators
The U.S. Army Corps of Engineers (USACE) provides the data for marine vessel
operators through the Waterborne Transportation Lines of the United States. Data
are collected by the USACE’s Navigation Data Center (NDC) by various means, including
the U.S. Coast Guard’s registry, maritime service directories, and waterway sector
publications. However, an annual survey of companies that operate inland waterway
vessels is the principle source of data. More than 3,000 surveys are sent to these
companies and response rates are typically above 90 percent. However, a USACE
official did report that less than 10 percent of the total number of companies
operating inland water vessels either did not receive or respond to the annual
survey.
Pipeline Operators
The Office of Pipeline Safety (OPS) in the U.S. Department of Transportation’s
Research and Special Programs Administration collects annual report data from
natural gas transmission and distribution operators as required by 49 CFR 191.17
and 191.11, respectively. Annual data must be submitted by March 15 of the following
calendar year. No annual report is required for hazardous liquid pipeline operators.
However, information is available through the pipeline safety program. Since 1986,
the program has been funded by fees assessed to each OPS-regulated pipeline operator
based on per-mile of hazardous pipeline operated. Data for each operator and each
mile of pipeline are stored in the OPS user-fee database, which is revised annually
as updated fees are assessed.
Totals for pipeline operators in this table will differ from those in other
tables due to differences in the regulatory authority of USDOT and the Federal
Energy Regulatory Commission (FERC). FERC regulates only interstate pipelines,
whereas DOT regulates both interstate and intrastate pipelines, except for rural
gathering lines and some offshore pipelines, which fall under jurisdiction of
the U.S. Coast Guard or the U.S. Department of the Interior’s Minerals Management
Service. An OPS official stated that FERC regulates about two-thirds the amount
of pipeline mileage that USDOT regulates.
TABLE 1-9. Number of U.S. Aircraft, Vehicles, Vessels, and Other Conveyances
TABLE 1-11. Active Air Carrier and General Aviation Fleet by Type of Aircraft
Air Carrier, Certificated, All Services
Prior to 1995, data originated from the U.S. Department of Transportation,
Federal Aviation Administration (FAA), FAA Statistical Handbook of Aviation.
Later data are from the Aerospace Industries Association (AIA), Aerospace Facts
and Figures 2000/2001. However, Aerospace Facts and Figures is compiled from
the FAA Statistical Handbook of Aviation. U.S. air carrier fleet data are
based on reports collected by FAA field offices from carriers. The reports include
information on the number of aircraft by type used in air carrier service. The
FAA points out that this information is not an inventory of the aircraft owned
by air carriers, but represents the aircraft reported to the FAA as being used
in air carrier fleet service. The reported aircraft are all aircraft carrying
passengers or cargo for compensation or hire under 14 CFR 121 and 14 CFR 135.
General Aviation
The 1960-1980 figures originated from the FAA Statistical Handbook of Aviation.
Later data are from FAA annual issues of the General Aviation and Air Taxi Activity
(GAATA) Survey report, table 3.1.The FAA collects both aircraft registration data
and voluntary information about aircraft operation, equipment, and location. Before
1978, the FAA mandated owners to annually register their aircraft for the Aircraft
Registration Master File. This was a complete enumeration of operating aircraft.
Registrants were also asked to voluntarily report information on hours flow, avionics
equipment, base location, and use. The FAA changed their data collection methodology
in 1978. The annual registration requirement became triennial and the General
Aviation Activity and Avionics Survey was initiated to sample aircraft operation
and equipment data.
The General Aviation Activity and Avionics Survey was renamed the General Aviation
and Air Taxi Activity Survey in 1993 to reflect the fact that the survey includes
air taxi aircraft. This survey is conducted annually and encompasses a stratified,
systematic design from a random start to generate a sample of all general aviation
aircraft in the United States. It is based on the FAA registry as the sampling
frame. FAA established three stratification design variables in the survey: 1)
the average annual hours flown per aircraft by aircraft type, 2) the aircraft
manufacturer/model characteristics, and 3) the state of aircraft registration.
Data Reliability
Because of the change in 1978, the reliability of comparisons over time will
be affected. The FAA asserted that the change to a triennial registration deteriorated
the Aircraft Registration Master File in two ways. First, the resulting lag in
registration updates caused the number of undeliverable questionnaires to steadily
increase over the three-year period. Second, inactive aircraft would remain in
the registry, inflating the general aviation fleet count. In addition, a new regulation
added two categories of aircraft to the general aviation fleet. However, FAA concluded
that these changes resulted in no more than a five-percent error in the fleet
population estimate.
The reliability of the GAATA survey can be impacted by two factors: sampling
and nonsampling error. A measure, called the standard error, is used to indicate
the magnitude of sampling error. Standard errors can be converted for comparability
by dividing the standard error value by the estimate (derived from sample survey
results) and multiplying it by 100.This quantity, referred to as the percent standard
error, totaled seven-tenths of a percent in 1997 for the general aviation fleet.
A large standard error relative to an estimate indicates lack of precision and,
inversely, a small standard error indicates precision.
Nonsampling errors could include problems such as nonresponse, respondent’s
inability or unwillingness to provide correct information, differences in interpretation
of questions, and data-entry mistakes. Readers should note that nonresponse bias
might be a component of reliability errors in the data from 1980 to 1990.The FAA
conducted telephone surveys of nonrespondents in 1977, 1978, and 1979 and found
no significant differences or inconsistencies in respondents’ and nonrespondents’
replies. The FAA discontinued the telephone survey of nonrespondents in 1980 to
save costs. Nonresponse surveys were resumed in 1990, and the FAA found notable
differences and thus adjusted its fleet estimates. The 1991 through 1996 data
have been revised to reflect nonresponse bias. In 1997, a sample of 29,954 aircraft
was identified and surveyed from an approximate population of 251,571 registered
general aviation aircraft. Just over 65 percent of the sample responded to the
survey.
Highway, Total (registered vehicles)
The 1960 to 1980 figures are from the U.S. Department of Transportation, Federal
Highway Administration (FHWA) document, Highway Statistics, Summary to 1985, table
MV-201 and related tables. Data quality and consistency will be less reliable
for these years because of a diversity of registration practices from state to
state. Users should recognize that motor vehicle statistical information is not
necessarily comparable across all states or within a state from year to year.
For instance, the FHWA reported that separate data on single-unit trucks and combinations
was unobtainable from all states in 1990.
After 1980, the FHWA began to use the Highway Performance Monitoring System
(HPMS) database, which improved data reliability. FHWA reviews state-reported
HPMS data for completeness, consistency, and adherence to these specifications.
Some inaccuracy may arise from variations across states in their adherence to
federal guidelines in the Highway Performance Monitoring System Field Manual for
the Continuing Analytical and Statistical Database.
If choosing to compare state data, the FHWA recommends that users carefully
select a set of peer states that have characteristics similar to the specific
comparison. Improperly selected peer states are likely to yield invalid data comparisons.
Characteristics that a user needs to consider in determining compatibility of
a peer state include similarities and differences in urban/rural areas, population
densities, degrees of urbanization, climate, geography, state laws and practices
that influence data definitions, administrative controls of public road systems,
state economies, traffic volumes, and degrees of centralization of state functions.
The FHWA has developed a set of variables that users may use to determine appropriate
peer states.
Other 2-Axle 4-Tire Vehicle (truck)
Sources for these figures included FHWA’s Highway Statistics, Summary to 1995
(table VM-201A) and annual issues of Highway Statistics (table VM-1). FHWA compiles
these figures from the U.S. Bureau of the Census’ Truck Inventory and Use Survey
(TIUS). Since 1963, Census has conducted the TIUS every five years with the last
survey completed in 1997.The Census Bureau changed the name of the survey to the
Vehicle Inventory and Use Survey (VIUS) in 1997.The VIUS collects data and the
physical and operational characteristics of the nation’s truck population. In
1997, 131,000 trucks were surveyed from an estimated universe of over 75 million
trucks. Chronological reliability may be diminished due to sampling design changes
in 1977, 1982, and 1992. In 1977, the sampling universe was first stratified by
the number of trucks in a state: large (> 1.5 million trucks), medium (700,000
to 1.5 million), and small (< 700,000); and then by two truck sizes.
Stratification in 1982 was then based on body type rather than vehicle weight.
In 1992 and 1997, the sampling universe was first subdivided geographically and
then into five strata: 1) pickups, 2) vans, 3) single-unit light, 4) single-unit
heavy, and 5) truck tractor. Cases were then selected randomly within each stratum.
Census delivered a mail-out/mail-back survey to the owner identified in the
vehicle registration records. Data collection is staggered as state records become
available. Owners report data only for the vehicles selected. In the 1992 survey,
a method was employed to also collect data on new truck purchases in the latter
half of the year to estimate the fleet for the calendar year. This adjustment
in the sampling frame had not been done in previous surveys and may diminish chronological
reliability. The sample for 1997 was some 22,500 vehicles smaller than for 1992.
The 1997 VIUS had two sampling stages. For the first stage, the Census Bureau
surveyed about 131,000 trucks registered as of July 1, 1997.The second stage sampled
a total of 3,000 truck owners with state mailing addresses different from the
state of truck registration.
The accuracy and reliability of the VIUS survey depends jointly on sampling
variability and nonsampling errors. Standard errors arising from sampling variability
can be converted for comparability by dividing the standard error value by the
estimate and multiplying it by 100. This quantity, referred to as the percent
standard error, totaled two-tenths of a percent in 1992 and 1997 for the VIUS
sample. A large standard error relative to an estimate indicates lack of precision
and, inversely, a small standard error indicates precision. The 1992 TIUS achieved
over 90.2 percent reporting and the 1997 response rate equaled 84.5 percent, thus
reliability may have decreased in the most recent survey.
Transit
The American Public Transit Association (APTA) provided these data, which are
based on the Federal Transit Administration (FTA), National Transit Database.
These data are generally accurate because the FTA reviews and validates information
submitted by individual transit agencies. Reliability may vary because some transit
agencies cannot obtain accurate information or may misinterpret data. APTA conservatively
adjusts FTA data to include transit operators that do not report to the database
(private, very small, and rural operators).
Railroad (all categories)
The data are from Railroad Facts, published annually by the Association of
American Railroads (AAR). AAR data are based on 100-percent reporting by Class
I railroads to the Surface Transportation Board (STB) via Schedule 700 of the
R1 Annual Report. Thus, data estimates are considered very reliable. The STB defines
Class I railroads as having operating revenues at or above a threshold indexed
to a base of $250 million (1991) and adjusted annually in concert with changes
in the Railroad Freight Rate Index published by the Bureau of Labor Statistics.
In 1999, the adjusted threshold for Class I railroads was $258.5 million. Declassification
from Class I status occurs when a railroad falls below the applicable threshold
for three consecutive years. Although Class I railroads encompasses only 2 percent
of the number of railroads in the country, they account for over 71 percent of
the industry's mileage operated.
AAR determines the number of non-Class I railroads through an annual, comprehensive
survey sent to every U.S. freight railroad. By following up with nonrespondents,
the AAR obtains essentially a 100 percent census of all railroads. Use of the
current survey instrument began in 1986.
Amtrak
Amtrak maintains a computer database with a record of every locomotive and
car it operates. For each vehicle, those records include the year built, service
status (operating or not operating on a daily basis), and location. This data
should be considered very reliable.
Water Transportation
The source for Inland Nonself-Propelled Vessels, Self-Propelled Vessels, and
flag passenger and cargo vessels is the U.S. Army Corps of Engineers (USACE),
Waterborne Transportation Lines of the United States, annual issues. Data are
collected by the USACE’s Navigation Data Center (NDC) by various means, including
the U.S. Coast Guard’s registry, maritime service directories, and waterway sector
publications. However, an annual survey of companies that operate inland waterway
vessels is the principle source of data. More than 3,000 surveys are sent to these
companies, and response rates are typically above 90 percent. However, a USACE
official did report that less than 10 percent of the total number of companies
operating inland vessels either did not receive or respond to the annual survey.
Oceangoing Steam Motor Ships
Merchant Fleets of the World, published annually by the U.S. Department of
Transportation, Maritime Administration (MARAD), is the source of these data.
MARAD, which classifies vessels as merchant based on size and type, compiles these
figures from a data service provided by Lloyd’s Maritime Information Service (LMIS).The
parent company, Lloyd’s Register (LR), collects data from 200 offices worldwide,
from data transfers and agreements with other classification societies, from questionnaires
to ship owners and ship builders, from feedback from government agencies, and
from input from port agents. According to an LR official, consistent data-gathering
methods have been maintained for more than 30 years. The same official did caution
that there are sometimes inconsistencies in groupings of ship types over time.
For example, propelled tank barges are now included in the tanker ship-type grouping.
Recreational Boats
Boating Statistics, published annually by the U.S. Coast Guard (USCG), is the
source. The USCG derives these figures from state and other jurisdictional reporting
of the actual count of valid boat numbers issued. In accordance with federal requirements,
all 55 U.S. states and territories require motor-powered vessels to be numbered.
However, over half the states do not require nonpowered vessels to be numbered.
Accuracy can also be diminished by noncompliance of boat owners with numbering
and registration laws. In 1996, the USCG estimated that approximately eight million
recreational boats are not numbered and, thus, are excluded from the reported
number of recreational vessels. The USCG did not provide estimates for the number
of boats without numbering in their reports after 1996. Some jurisdictions fail
to report by publication deadlines, and the USCG provided estimates based on the
previous year’s estimate.
TABLE 1-10. Sales or Deliveries of New Aircraft, Vehicles, Vessels, and Other
Conveyances
Civilian Aircraft
The Aerospace Industries Association (AIA) provided this data in their annual
issues Aerospace Facts and Figures, "Civil Aircraft Shipments." AIA
collects their data from aircraft company reports, the General Aviation Manufacturers
Association (GAMA), and the U.S. Department of Commerce’s (DOC) International
Trade Administration. DOC data provide total number of shipments and exports,
and the difference computed by AIA equals domestic shipments. DOC collects shipments
data separately for individual factories or establishments and not at the company
level. A potential limitation of this approach is when a factory producing aircraft
for shipment also makes aircraft parts. If the establishment has 80 percent of
its production in aircraft and 20 percent in parts, all of the output is attributed
to aircraft shipments.
Transport
The Aerospace Industries Association (AIA) is the source of these data. AIA
obtains quarterly data from Boeing Corp., now the sole U.S. manufacturer of transport
aircraft, and publicly available financial disclosure information filed with the
U.S. Securities and Exchange Commission (SEC) via Form 10-k. SEC requires a publicly
traded company to file an annual report 90 days after the end of the company’s
fiscal year to provide an overview of that business.
Helicopters
AIA surveyed and received data from all 10 major helicopter manufacturers on
their sales and deliveries.
General Aviation
The general aviation figures are taken from the General Aviation Statistical
Databook published by the GAMA. General aviation refers usually to the small aircraft
industry in the United States. GAMA collects quarterly data from the 10 to 14
manufacturers who nearly equal a census of the general aviation sector.
Passenger Car, Truck, Bus, and Recreational Vehicles
Ward’s Motor Vehicle Facts and Figures is the source of these data. Ward’s
obtains sales data directly from manufacturers. Readers should note that automobile
manufacturers have inflated sales figures in the past, but Ward’s does contact
companies to verify numbers that appear too high or low.
Motorcycle
The Motorcycle Industry Council, Inc. (MIC) publishes the Motorcycle Statistical
Annual, which is the source for these data. MIC derived the estimate for new retail
motorcycle sales for each state from the MIC Retail Sales Report, and adjusted
for total retail sales. Motorcycle company reports provided sales data. Prior
to 1985, all-terrain vehicles (ATVs) were included in the motorcycle total. In
1995, the Motorcycle Industry Council revised its data for the years 1985 to present
to exclude all terrain vehicles from its totals.
Bicycle
The National Bicycle Dealers Association (NBDA) reported these data, which
are based on Bicycle Manufacturers Association (BMA) information through 1996.
BMA stopped reporting members' shipments in 1996. Moreover, BMA represents the
largest bicycle manufacturers (Huffy, Roadmaster, and Murray), and thus the data
do not reflect specialty bike makers or other manufacturers. The Bike Council
estimated 1997 through 2000 figures in the table. According to a Bicycle Council
representative, the estimates are a combination of domestic forecasts produced
by a panel of industry experts and import data from monthly U.S. census databases.
Transit
The American Public Transit Association provided these figures, which are based
on information in the U.S. Department of Transportation, Federal Transit Administration
(FTA), National Transit Database. These data are generally considered accurate
because the FTA reviews and validates information submitted by individual transit
agencies. Reliability may vary because some transit agencies cannot obtain accurate
information or misinterpret data. APTA conservatively adjusts FTA data to include
transit operators that do not report to the database (private, very small, and
rural operators).
Class I Rail
The data are from Railroad Facts, published annually by the Association of
American Railroads (AAR). AAR data are based on 100-percent reporting by Class
I railroads to the Surface Transportation Board (STB) via Schedule 700 of the
R1 Annual Report. STB defines Class I railroads as having operating revenues at
or above a threshold indexed to a base of $250 million (1991) and adjusted annually
in concert with changes in the Railroad Freight Rate Index published by the Bureau
of Labor Statistics. In 2000, the threshold for Class I railroads was $261.9 million.
Although Class I railroads encompasses only 2 percent of the number of railroads
in the country, they account for over 71 percent of the industry's mileage operated.
Historical reliability may vary due to changes in the railroad industry, including
bankruptcies, mergers, and declassification by the STB. Small data errors may
also have occurred because of independent rounding in this series by the AAR.
Amtrak
Amtrak maintains a computer database with a record of every locomotive and
car it operates. For each vehicle, those records include the year built, its service
status (operating or not on a daily basis), and location. These data should be
considered very reliable.
Water Transportation
U.S. Department of Transportation, Maritime Administration (MARAD), which classifies
vessels as merchant based on size and type, reports these data in annual issues
of its Merchant Fleets of the World. MARAD compiles these figures from a data
service provided by Lloyd’s Maritime Information Service. The parent company,
Lloyd’s Register (LR), collects data from several sources: its 200 offices worldwide,
data transfers and agreements with other classification societies, questionnaires
to shipowners and shipbuilders, feedback from government agencies, and input from
port agents. According to an LR official, consistent data gathering methods have
been maintained for more than 30 years but cautioned that inconsistencies may
occur in groupings of ship types over time. For example, tank barges are now included
in the tanker ship-type grouping rather than the barge grouping.
TABLE 1-12. U.S. Automobile and Truck Fleets by Use
These statistics originate from two sources. The R.L. Polk Co. provides numbers
for commercial fleet vehicles from state registrations. Bobit Publishing Co. also
obtains fleet vehicle sales data from automobile manufacturers. These two sources
cover nearly 100 percent of fleet vehicles in the United States. Thus, the data
should be very accurate.
TABLE 1-13. Annual U.S. Motor Vehicle Production and Factory (Wholesale) Sales
TABLE 1-14. Retail New Passenger Car Sales
TABLE 1-15. New and Used Passenger Car Sales and Leases
TABLE 1-19. World Motor Vehicle Production, Selected Countries
Motor Vehicle Production, Factory Sales, and New Passenger Car Retail Sales
Ward’s Motor Vehicle Facts & Figures is the source of these data. Ward’s
obtains sales data directly from manufacturers. Readers should note that automobile
manufacturers have inflated sales figures in the past, but Ward’s does contact
companies to verify numbers that appear too high or low.
Used Passenger Car Sales and Leased Passenger Cars
ADT Automotive Used Car Market Report is the source of these data. The Wall
Street Journal (WSJ) is the original source of 1999 data. According to an ADT
representative, publishing deadlines require ADT to use WSJ numbers until they
can be replaced with National Automotive Dealers Association data. ADT Automotive’s
Market Analysis Department also gathers figures from CNW Marketing/Research and
the R.L. Polk Co. CNW estimates used car sales volumes by collecting state title
transfer data and determining if a transaction was made between private individuals
or between a consumer and a franchised or independent dealer. This estimate is
evaluated by comparing total transactions with state automobile sales revenues.
Polk, an additional source of data, maintains a state vehicle registration database.
For 1998, the ADT representative stated that Polk’s data were within 5 percentage
points of CNW estimates.
TABLE 1-16. Retail Sales of New Cars by Sector
The U.S. Department of Commerce, Bureau of Economic Analysis, uses data from
Ward’s Automotive Reports. The sectoral break down is derived from registration
data obtained from R.L. Polk. Ward’s obtains sales data directly from manufacturers.
Readers should note that automobile manufacturers have inflated sales figures
in the past, but Ward’s does contact companies to verify numbers that appear too
high or low.
TABLES 1-17 and 1-18. Period Sales, Market Shares, and Sales-Weighted Fuel
Economies of New Domestic and Imported Automobiles and Light Trucks, Selected
Sales Periods
These data originate from Oak Ridge National Laboratory’s (ORNL) Light-Duty
MPG and Market Shares System database, which relies on information from monthly
Ward’s Automotive Reports. Comparisons and observations are made on sales and
fuel economy trends from one model year to the next. ORNL has adopted several
conventions to facilitate these comparisons, such as the use of sales-weighted
average to estimate fuel economy and vehicle characteristics. For example, "sales-weighted"
miles per gallon refers to a composite or average fuel economy based on the distribution
of vehicle sales. ORNL’s methodology for sales-weighting can be found in the Appendix
of the Highway Vehicle MPG and Market Shares Report: Model Year 1990 (the latest
published report). The method was changed dramatically in 1983, and data reliability
prior to that year is questionable. This information is now published annually
in ORNL’s Transportation Energy Data Book.
TABLE 1-20. Number and Size of the U.S. Flag Merchant Fleet and Its Share of
the World Fleet
The U.S. Department of Transportation, Maritime Administration, which classifies
vessels as merchant based on size and type, compiles these figures from a data
service provided by Lloyd’s Maritime Information Service. The parent company,
Lloyd’s Register (LR), collects data from several sources: its 200 offices worldwide,
data transfers and agreements with other classification societies, questionnaires
to shipowners and shipbuilders, feedback from government agencies, and input from
port agents. According to an LR official, consistent data gathering methods have
been maintained for more than 30 years, but cautioned that inconsistencies may
occur in groupings of ship types over time. For example, tank barges are now included
in the tanker ship-type grouping rather than the barge grouping.
TABLE 1-21. U.S. Airport Runway Pavement Conditions
These data originate from the U.S. Department of Transportation, Federal Aviation
Administration (FAA), National Plan of Integrated Airport Systems (NPIAS). The
NPIAS includes all commercial service airports, all reliever airports, and selected
general aviation airports. It does not include more than 1,000 publicly owned
public use landing areas, privately owned public use airports, and other civil
landing areas not open to the general public. NPIAS airports serve 92 percent
of general aviation aircraft (based on an estimated fleet of 200,000 aircraft).
In 1998, the NPIAS encompassed 3,344 of the 5,357 airports with public access.
Runway pavement condition is classified as follows:
Good: All cracks and joints are sealed.
Fair: Mild surface cracking, unsealed joints, and slab edge spalling.
Poor: Large open cracks, surface and edge spalling, vegetation growing
through cracks and joints.
On a rotating basis, the FAA arranges annual inspections for about 2,000 of
the approximately 4,700 public-use airports. The inspections are based on funding
availability and not on statistical criteria, and nearly all runways are inspected
every two years. Inspections are primarily made to collect information for pilots
on airport conditions. The FAA relies on state and local agencies to perform inspections,
so some inaccuracy may arise from variation in their adherence to federal guidelines
regarding pavement condition reporting. In 1998, the U.S. General Accounting Office
found that Pavement Condition Index information was available for about 35 percent
of NPIAS airports (GAO/RCED-98-226).
TABLE 1-22. Median Age of Automobiles and Trucks in Operation in the United
States
The R.L. Polk Co. is a private enterprise that purchases state registration
data to maintain a database of operational vehicles. Its data represent a near
census of registered vehicles in the United States, and the age estimate should
be considered very reliable.
TABLE 1-23. Condition of U.S. Roadways by Functional System
U.S. Department of Transportation, Federal Highway Administration (FHWA) collects
pavement condition data from each state through the Highway Performance Monitoring
System. The FHWA uses two rating schemes—the Present Serviceability Rating (PSR)
and the International Roughness Indicator (IRI).IRI is used to measure the condition
of Interstates, other principal arterials, rural minor arterials, and other National
Highway System roadways. PSR is used to measure the condition of rural major collectors
and urban minor arterials and collectors. Rural minor collectors are not measured.
Where IRI data are not reported for sampled sections, the PSR data are collected.
Using the PSR, values range from 0.1 to 5.0, where 5.0 denotes new pavement in
excellent condition and 0.1 denotes pavement in extremely poor condition. On the
IRI scale however, lower values indicate smoother roads (e.g., <60 for interstate
pavement in very good condition to >170 for interstate pavement in poor condition).
The IRI is an objective measure of pavement roughness developed by the World
Bank. The PSR is a more subjective measure of a broader range of pavement characteristics
and therefore less comparable. Prior to 1993, all pavement conditions were evaluated
using PSR values. Beginning with data published in Highway Statistics 1993, the
FHWA began a transition to the IRI, which should eventually replace the PSR. The
change from PSR to IRI makes comparisons between pre-1993 pavement condition data
and 1993 and later pavement condition data difficult. Thus, trend comparisons
should be made with care.
FHWA indicates that the protocol of measuring pavement roughness is not followed
by all states, and some did not report for all required mileage. Totals only reflect
those states reporting usable or partially usable data. Column percentages may
not sum to 100 and may differ slightly from percentages in source tables, which
were adjusted so that they would add to 100.FHWA believes that the IRI data are
of "reasonably good quality."
TABLE 1-24. Condition of U.S. Bridges
These figures are from the U. S. Department of Transportation, Federal Highway
Administration (FHWA), National Bridge Inventory Database. State highway agencies
are required to maintain a bridge inspection program and inspect most bridges
on public roadways at a minimum of every two years. With FHWA approval, certain
bridges may be inspected less frequently. A complete file of all bridges is collected
and maintained, representing a very reliable assessment of bridge conditions.
However, some inaccuracy may be attributable to variations in state inspector’s
adherence to the National Bridge Inspection Standards.
TABLE 1-25. Average Age of Urban Transit Vehicles
These figures are based on information in the U.S. Department of Transportation,
Federal Transit Administration (FTA), National Transit Database. Section 15 of
the Federal Transit Act requires federally funded transit agencies to provide
detailed financial and operating data, including vehicle inventories. Transit
operators that do not report to FTA are those that do not receive federal funding,
typically private, small, and rural operators. The data are generally considered
accurate because FTA reviews and validates information submitted by individual
transit agencies. Reliability may vary because some transit agencies cannot obtain
accurate information or may misinterpret certain data definitions.
TABLE 1-26. Class I Railroad Locomotive Fleet by Year Built
The data are from Railroad Facts, published annually by the Association of
American Railroads (AAR). Figures reported by AAR are based on 100-percent reporting
by Class I railroads to the Surface Transportation Board (STB) via Schedule 700
of the R1 Annual Report. STB defines Class I railroads as having operating revenues
at or above a threshold indexed to a base of $250 million (1991) and adjusted
annually in concert with changes in the Railroad Freight Rate Index published
by the Bureau of Labor Statistics. In 2000, the threshold for Class I railroads
was $261.9 million. Declassification from Class I status occurs when a railroad
falls below the applicable threshold for three consecutive years. Although Class
I railroads encompasses only 2 percent of the number of railroads in the country,
they account for over 71 percent of the industry's mileage operated.
TABLE 1-27. Age and Availability of Amtrak Locomotive and Car Fleets
Amtrak maintains a computer database with a record of every locomotive and
car it operates. For each vehicle those records include the year built, its service
status (operating or not on a daily basis), and location. These data should be
considered very reliable.
TABLE 1-28. U.S. Flag Vessels by Type and Age
The data are from the U.S. Army Corps of Engineers (USACE), Waterborne Transportation
Lines of the United States (WTLUS), annual issues. The WTLUS database contains
information on vessel operators and characteristics and descriptions for all domestic
vessel operations. Data are collected by the USACE’s Navigation Data Center, primarily
through a survey of vessel operating companies. More than 3,000 surveys are sent
to these companies and response rates are typically above 90 percent. However,
a USACE official did report that less than 10 percent of the total number of companies
operating inland vessel fleets either did not receive and/or did not respond to
the annual survey.
TABLE 1-29. U.S. Vehicle-Miles
TABLE 1-30. Roadway Vehicle-Miles Traveled (VMT) and VMT per Lane-Mile by
Functional Class
TABLE 1-31. U.S. Passenger-Miles
Air Carrier, Certificated, Domestic, All Services
The U.S. Department of Transportation (USDOT), the Bureau of Transportation
Statistics, Office of Airline Information, reports aircraft revenue-miles and
passenger-miles in its publication Air Traffic Statistics. These numbers are based
on 100-percent reporting of passengers and trip length by large certificated air
carriers. Minor errors arise from nonreporting but amount to less than 1 percent
of all air carrier passenger-miles. The figures do not include data for all airlines,
such as most scheduled commuter airlines and all nonscheduled commuter airlines.
These, if added, may raise total air passenger-miles by about 5 percent.
General Aviation
Passenger-mile numbers for 1975 to present are calculated by adjusting the
Interstate Commerce Commission’s 1974 figure for air passenger-miles by the percentage
change in annual hours flown by general aviation aircraft as published in the
USDOT, Federal Aviation Administration (FAA), FAA Statistical Handbook of Aviation.
Numbers in the handbook are based on the General Aviation and Air Taxi Survey
(GAATA). In 1993, the GAATA stopped including commuter aircraft. Commuter-miles
collected before 1993 by the GAATA were, according to one FAA official, woefully
underreported. Therefore, problems with the estimate of general aviation aircraft
include: a break in the series between 1992 and 1993, a possible outdated factor
used to calculate passenger-miles, and the classification of commuter operations.
Highway
Highway vehicle-miles of travel (vmt) are estimated using data from the Highway
Performance Monitoring System (HPMS), a database maintained by FHWA that contains
information on highway characteristics supplied by individual states. Annual vmt
by highway functional system is calculated as the product of the annual average
daily traffic (AADT) along each highway section, the centerline length of each
highway section, and the number of days in the year. Also, expansion factors are
used for roadways that are sampled rather than continuously monitored. Vmt by
vehicle type is estimated using vehicle share estimates supplied by states.
FHWA has established methods for collecting, coding, and reporting HPMS data
in two manuals: Traffic Monitoring Guide (TMG) and Highway Performance Monitoring
System Field Manual. The prescribed sampling process for collecting highway volume
data, which is used to estimate AADT, is based on statistical methods. However,
in practice, several factors affect the ultimate quality of the data. FHWA discusses
many of these issues in their annual Highway Statistics report and other publications.
However, BTS is not aware of any study or report that has statistically quantified
the accuracy of vmt estimates. Some of the primary issues related to data quality
are noted here.
- The sampling procedures suggested in the TMG and HPMS Field Manual are designed
to produce traffic volume estimates with an average precision level of 80-percent
confidence with a 10-percent allowable error at the state level. FHWA provides
additional guidance to states through annual workshops and other avenues to help
them follow these procedures as closely as possible. However, the actual data
quality and consistency of HPMS information are dependent on the programs, actions,
and maintenance of sound databases by numerous data collectors, suppliers, and
analysts at the state, metropolitan, and other local area levels. Not all states
follow the recommended sampling, counting, and estimating procedures contained
in the Traffic Monitoring Guide, and the exact degree to which the states follow
these guidelines overall is unknown. However, FHWA believes that most states generally
follow the guidelines.
- Estimates for higher-level roadway systems are more accurate than those for
lower level ones, since traffic volumes on higher-level roadways are sampled at
a higher rate. The TMG recommends that traffic counts be collected for all Interstate
and principal arterial sections on a three-year cycle. Under this scheme, about
one-third of the traffic counts for these roadway sections in a given year are
actually measured, while volumes on the remainder are factored to represent present
growth. Although some States collect data at all traffic count locations every
year, most use some variation of the TMG data collection guidelines. Volumes on
urban and rural minor arterials, rural major collectors, and urban collectors
are collected using a sampling procedure. States are not required to report volumes
for rural/urban local systems and rural minor collectors, though most do so. However,
the methods used to estimate travel on these roadways vary from state to state
since there are no standard guidelines for calculating travel on these roadways.
- Vmt estimates by vehicle type are less accurate than are estimates for total
motor vehicle vmt for several reasons:
1) vehicle classification equipment can frequently misclassify vehicles (see B.A.
Harvey et al, Accuracy of Traffic Monitoring Equipment, GDOT 9210, (Georgia Tech
Research Institute:1995);
2) vehicle shares are often determined by methods or by special studies that are
not directly compatible with HPMS data definitions and/or purposes, and observed
local-level vehicle classification counts are difficult to apply on a statewide
basis; and
3) vehicle type definitions can vary among states.
- Vmt estimates for combination trucks in HPMS differ from survey-based estimates
from the Truck Inventory and Use Survey (TIUS), as much as 50 percent for some
categories of combination trucks. Much of this discrepancy appears to be due to
differences in truck classification definitions and biases introduced by data
collection practices. See R.D. Mingo et al.1995.Transportation Research Record,
No. 1511 (Washington, DC: National Academy Press), pp. 42-46.
- FHWA adjusts questionable data using a variety of standard techniques and
professional judgement. For example, national average temporal adjustment factors
developed from HPMS and other national highway monitoring programs are applied
to State data, when necessary, to compensate for temporal deficiencies in sampling
practices. Also, in estimating vmt by vehicle type, FHWA employs an iterative
process to reconcile vmt, fuel economy (miles per gallon), fuel consumption, and
vehicle registration estimates. Fuel consumption, total vmt by highway functional
class, and registrations by vehicle group are used as control totals. This process
limits the size of errors and ensures data consistency.
- Passenger-miles of travel (pmt) are calculated by multiplying vmt estimates
by vehicle loading (or occupancy) factors from various sources, such as the Nationwide
Personal Transportation Survey conducted by FHWA and TIUS. Thus, pmt data are
subject to the same accuracy issues as vmt, along with uncertainties associated
with estimating vehicle-loading factors.
Transit
The American Public Transit Association (APTA) figures are based on information
in USDOT, Federal Transit Administration (FTA), National Transit Database. Transit
data are generally considered accurate because FTA reviews and validates information
submitted by individual transit agencies. However, reliability may vary because
some transit agencies cannot obtain accurate information or may misinterpret data.
APTA adjusts the FTA data to include transit operators that do not report to the
FTA database (private, very small, and rural operators).
Class I Rail (vehicle-miles)
Data are from Railroad Facts, published annually by the Association of American
Railroads (AAR). AAR data are based on 100-percent reporting by Class I railroads
to the Surface Transportation Board (STB) via Schedule 700 of the R1 Annual Report
required of Class I railroads. STB defines Class I railroads as having operating
revenues at or above a threshold indexed to a base of $250 million (1991) and
adjusted annually in concert with changes in the Railroad Freight Rate Index published
by the Bureau of Labor Statistics. In 1999, the adjusted threshold for Class I
railroads was $258.5 million. Declassification from Class I status occurs when
a railroad falls below the applicable threshold for three consecutive years. Although
Class I railroads encompasses only 2 percent of the number of railroads in the
country, they account for over 71 percent of the industry's mileage operated.
Intercity Train
The AAR passenger-miles number is based on an almost 100-percent count of tickets
and, therefore, is considered accurate.
TABLE 1-33. Long-Distance Travel in the United States by Selected Trip Characteristics:
1995
TABLE 1-34. Long-Distance Travel in the United States by Selected Traveler
Characteristics: 1995
The data presented in these tables are estimates derived from the 1995 American
Travel Survey (ATS) conducted for the U.S. Department of Transportation, Bureau
of Transportation Statistics. The survey’s estimation procedure inflates unweighted
sample results to independent estimates of the total population of the United
States. Values for missing data are estimated through imputation procedures.
Since ATS estimates come from a sample, they are subject to two possible types
of error: nonsampling and sampling. Sources of nonsampling errors include inability
to obtain information about all sample cases, errors made in data collection and
processing, errors made in estimating values for missing data, and undercoverage.
The accuracy of an estimate depends on both types of error, but the full extent
of the nonsampling error is unknown. Consequently, the user should be particularly
careful when interpreting results based on a relatively small number of cases
or on small differences between estimates.
Standard errors for ATS estimates that indicate the magnitude of sampling error
as well as complete documentation of the source and reliability of the data may
be obtained from detailed ATS reports. Because of methodological differences,
users should use caution when comparing these data with data from other sources.
TABLE 1-35. U.S. Air Carrier Departures, Enplaned Revenue Passengers, and Enplaned
Revenue Tons
The Airport Activity Statistics of Certificated Air Carriers (AAS) is the source
of these data. Published annually by the U.S. Department of Transportation, Bureau
of Transportation Statistics, Office of Airline Information (OAI), the AAS presents
traffic statistics for all scheduled and nonscheduled service by large certificated
U.S. air carriers for each airport served within the 50 states, the District of
Columbia, and other U.S. areas designated by the Federal Aviation Administration.
The publication draws its data from the T-100 and T-3 databases maintained by
OAI. These data are based on a 100-percent reporting of enplanements, departures,
and tonnage information by large certificated U.S. air carriers via BTS Form 41.
Prior to 1993, the AAS included all scheduled and some nonscheduled enplanements
for certificated air carriers but did not include enplanements for air carriers
offering charter service only. Prior to 1990, the freight category was divided
into both freight and express shipments and the mail category was divided into
U.S. mail (priority and nonpriority) and foreign mail. Beginning in 1990, only
aggregate numbers were reported for freight and mail.
Air traffic hubs are designated as geographical areas based on the percentage
of total passengers enplaned in the area. A hub may have more than one airport.
This definition of hub should not be confused with the definition used by airlines
in describing their "hub-and-spoke" route structures.
TABLE 1-36. Passengers Boarded at the Top 50 U.S. Airports
The Airport Activity Statistics of Certificated Air Carriers (AAS), is the
source of these data. Data for 1999 are from the U.S. Department of Transportation
(USDOT), Federal Aviation Administration’s Statistical Handbook of Aviation. Published
by USDOT, Bureau of Transportation Statistics, Office of Airline Information (OAI),
the AAS presents traffic statistics for all scheduled and nonscheduled service
by large certificated U.S. air carriers for each airport served within the 50
states, the District of Columbia, and other U.S. areas designated by the Federal
Aviation Administration. The publication draws its data from the T-100 and T-3
databases maintained by OAI. These data are based on a 100-percent reporting of
enplanements, departures, and tonnage information by large certificated U.S. air
carriers via BTS Form 41.
Prior to 1993, the AAS included all scheduled and some nonscheduled enplanements
for certificated air carriers but did not include enplanements for air carriers
offering charter service only. Prior to 1990, the freight category was divided
into both freight and express shipments and the mail category was divided into
U.S. mail (priority and nonpriority) and foreign mail. Beginning in 1990, only
aggregate numbers were reported for freight and mail.
TABLE 1-37. Air Passenger Travel Arrivals in the United States from Selected
Foreign Countries
TABLE 1-38. Air Passenger Travel Departures from the United States to Selected
Foreign Countries
The International Trade Administration in the U.S. Department of Commerce publishes
the U.S. International Air Travel Statistics Report annually. The passenger data
is based on information collected by the U.S. Immigration and Naturalization Service
using the INS Form I-92. All passengers on international flights must complete
the I-92 form with the exception of those passengers on flights arriving or departing
from Canada.
The international passenger arrivals and departures data for Canada is obtained
from Air Carrier Traffic at Canadian Airports, which is published by Statistics
Canada. Three surveys are conducted by Statistics Canada in order to collect the
necessary passenger data. Since all data is not received by the time of publication
and data is occasionally updated or resubmitted by the participating carriers,
data should be considered preliminary for the years referenced in the source publication.
TABLE 1-41. U.S. Ton-Miles of Freight
Air Carrier
Air Carrier Traffic Statistics, published by the U.S. Department of Transportation,
Bureau of Transportation Statistics (BTS), Office of Airline Information (OAI),
is the source of these data. Large certificated U.S. air carriers report domestic
freight activities to OAI via BTS Form 41.The information reported in the table
represents transportation of freight (excluding passenger baggage), U.S. and foreign
mail, and express mail within the 50 states, the District of Columbia, Puerto
Rico, and the Virgin Islands. It also covers transborder traffic to Canada and
Mexico by U.S. carriers. The data does not include information on small certificated
air carriers, which represent less than 5 percent of freight ton-miles.
Intercity Truck
The data are estimates from Transportation in America, published by the Eno
Transportation Foundation, Inc. (Eno). Eno’s estimates of intercity truck ton-miles
are based on historic data from the former Interstate Commerce Commission (ICC),
estimates from the American Trucking Association, and other sources. Eno supplements
its estimates by using additional information on vehicle-miles of truck travel
published in Highway Statistics by the Federal Highway Administration. Users should
note that truck estimates in the tables do not include local truck movements.
Class I Rail
The data are from Railroad Facts, published annually by the Association of
American Railroads (AAR). AAR data are based on 100-percent reporting by Class
I railroads to the Surface Transportation Board (STB). The data represent all
revenue freight activities of the Class I railroads and are not based on information
from the Rail Waybill Sample. The STB defines Class I railroads as having operating
revenues at or above a threshold indexed to a base of $250 million (1991) and
adjusted annually in concert with changes in the Railroad Freight Rate Index published
by the Bureau of Labor Statistics. In 1999, the adjusted threshold for Class I
railroads was $258.5 million. Declassification from Class I status occurs when
a railroad falls below the applicable threshold for three consecutive years. Although
Class I railroads encompasses only 2 percent of the number of railroads in the
country, they account for over 71 percent of the industry's mileage operated.
Domestic Water Transport
The data are from Waterborne Commerce of the United States, published by the
U.S. Army Corps of Engineers (USACE). All vessel operators of record report their
domestic waterborne traffic movements to USACE via ENG Forms 3925 and 3925b.Cargo
movements are reported according to points of loading and unloading. Certain cargo
movements are excluded: 1) cargo carried on general ferries, 2) coal and petroleum
products loaded from shore facilities directly into vessels for fuel use, 3) military
cargo moved in U.S. Department of Defense vessels, and 4) cargo weighing less
than 100 tons moved on government equipment. USACE calculates ton-miles by multiplying
the cargo’s tonnage by the distance between the points of loading and unloading.
Oil Pipeline
The data for 1960, 1965, and 1970 are from Transportation in America, published
by the Eno Transportation Foundation, Inc., and the data for 1975 to 1998 are
from Shifts in Petroleum Transportation, by the Association of Oil Pipe Lines
(AOPL). Eno’s data are based on information from the former Interstate Commerce
Commission’s Transport Economics. Common carrier oil pipelines reported all freight
activities to the ICC.
AOPL obtains barrel-miles from the Federal Energy Regulatory Commission (FERC),
which requires petroleum shippers to report annual shipments. AOPL then coverts
barrel-miles to ton-miles using conversion figures in the American Petroleum Institute’s
(API’s) Basic Petroleum Data Book. Since 16 percent of pipeline shipments are
intrastate and not subject to FERC reporting requirements, AOPL makes adjustments
to FERC data.
TABLE 1-42. Average Length of Haul: Domestic Freight and Passenger Modes
Freight
Air Carrier and Truck
The Eno Transportation Foundation, Inc. estimated these figures.
Class I Rail
The data are from Railroad Facts, published annually by the Association of
American Railroads (AAR). AAR data are based on 100-percent reporting by Class
I railroads to the Surface Transportation Board (STB) via Schedule 700 of the
R1 Annual Report required of Class I railroads. The STB defined Class I railroads
as having operating revenues at or above a threshold indexed to a base of $250
million (1991) and adjusted annually in concert with changes in the Railroad Freight
Rate Index published by the Bureau of Labor Statistics. In 1999, the adjusted
threshold for Class I railroads was $258.5 million. Declassification from Class
I status occurs when a railroad falls below the applicable threshold for three
consecutive years. Although Class I railroads encompasses only 2 percent of the
number of railroads in the country, they account for over 71 percent of the industry's
mileage operated.
Water
The data are from Waterborne Commerce of the United States, published by the
U.S. Army Corps of Engineers (USACE). All vessel operators of record report their
domestic waterborne traffic movements to USACE via ENG Forms 3925 and 3925b.Cargo
movements are reported according to points of loading and unloading. Certain cargo
movements are excluded: 1) cargo carried on general ferries, 2) coal and petroleum
products loaded from shore facilities directly into vessels for fuel use, 3) military
cargo moved in U.S. Department of Defense vessels, and 4) cargo weighing less
than 100 tons moved on government equipment. USACE calculates ton-miles by multiplying
the cargo’s tonnage by the distance between points of loading and unloading.
Oil Pipeline
The Eno Transportation Foundation, Inc., provided these figures, which are
estimates based on U.S. Department of Energy and Association of Oil Pipe Lines
reports. Figures are derived by dividing estimated pipeline ton-miles by estimated
crude and petroleum products tonnage.
Passenger
Air Carrier
The U.S. Department of Transportation (USDOT), the Bureau of Transportation
Statistics, Office of Airline Information, reports average trip length in its
publication Air Traffic Statistics. These numbers are based on 100-percent reporting
of passengers and trip length by large certificated air carriers via BTS Form
41.The figures do not include data for all airlines, such as most scheduled commuter
airlines and all nonscheduled commuter airlines.
Bus
The Eno Transportation Foundation, Inc. estimated these figures based on Class
I carrier passenger data and vehicle-miles data from Highway Statistics, an annually
published report of the USDOT, Federal Highway Administration.
Commuter Rail
The American Public Transit Association (APTA) provided these data, which are
based on the USDOT, Federal Transit Administration’s (FTA’s), National Transit
Database. Transit data are generally accurate because the FTA reviews and validates
information submitted by individual transit agencies. Reliability may vary because
some transit agencies cannot obtain accurate information or may misinterpret data.
APTA conservatively adjusts FTA data to include transit operators that do not
report to the database (private, very small, and rural operators).
Intercity/Amtrak
The Statistical Appendix to the Amtrak Annual Report is the source of these
data. Amtrak data are based on 100 percent of issued tickets, and thus should
be accurate.
TABLE 1-43. Top U.S. Foreign Trade Freight Gateways by Value of Shipments:
2000
The value of U.S. air, maritime, and land imports and exports are captured
from administrative documents required by the U.S. Departments of Commerce and
Treasury. In 1990, the United States entered into a Memorandum of Understanding
with Canada concerning the exchange of import data. As a consequence, each country
is using the other’s import data to replace its own export data. U.S. international
merchandise trade statistics, therefore, are no longer derived exclusively from
the administrative records of the Departments of Commerce and Treasury, but from
Revenue Canada. Import value is for U.S. general imports, customs value basis.
Export value is FAS (free along ship) and represents the value of exports at the
U.S. port of export, including the transaction price and inland freight, insurance,
and other charges. Trade levels reflect the mode of transportation as a shipment
entered or exited a U.S. Customs port.
Truck, rail pipeline, mail, and miscellaneous modes are included in the total
for land modes. Data present trade activity between the United States, Puerto
Rico, and the U.S. Virgin Islands and Canada and Mexico. These statistics do not
include traffic between Guam, Wake Island, and America Samoa and Canada and Mexico.
These statistics also exclude imports that are valued at less than $1,250 and
for exports that are valued at less than $2,500.
TABLE 1-46. U.S. Waterborne Freight
The data are from Waterborne Commerce of the United States, published by the
U.S. Army Corps of Engineers (USACE). All vessel operators of record report their
domestic waterborne traffic movements to USACE via ENG Forms 3925 and 3925b. Cargo
movements are reported according to points of loading and unloading. Certain cargo
movements are excluded: 1) cargo carried on general ferries, 2) coal and petroleum
products loaded from shore facilities directly into vessels for fuel use, 3) military
cargo moved in U.S. Department of Defense vessels, and 4) cargo weighing less
than 100 tons moved on government equipment. USACE calculates ton-miles by multiplying
the cargo’s tonnage by the distance between points of loading and unloading.
Foreign waterborne statistics are derived from Census Bureau and U.S. Customs
data, which excludes traffic between Guam, Wake Island, and American Samoa and
any other foreign country, and imports and exports used by U.S. Armed Forces abroad.
Individual vessel movements with origins and destinations at U.S. ports, traveling
via the Panama Canal are considered domestic traffic.
TABLE 1-47. Tonnage of Top 50 U.S. Water Ports, Ranked by Total Tons
Data on the weight of U.S. maritime imports and exports are captured from administrative
documents required by the U.S. Departments of Commerce and Treasury. In 1990,
the United States entered into a Memorandum of Understanding with Canada concerning
the exchange of import data. As a consequence, each country is using the other’s
import data to replace its own export data. The United States’ merchandise trade
statistics, therefore, are no longer derived exclusively from U.S. government
administrative records, but from Revenue Canada. Maritime weight data are initially
processed and edited by the Foreign Trade Division, U.S. Census Bureau (Census)
as part of the overall edits and quality checks performed on all U.S. international
merchandise trade data. After Census processing, the U.S. Army Corps of Engineers
(USACE) and the Maritime Administration (MARAD) perform additional maritime-specific
processing and quality edits on maritime-related data elements, including the
weight of maritime imports and exports. The USACE and MARAD began performing this
function in October 1998 after the Foreign Waterborne Trade data program was transferred
from the Census Bureau. Prior to October 1998, the USACE historically performed
additional specialized edits at the port level, including reassignment of some
tonnage data to the actual waterborne port rather than the reported U.S. Customs
port.
TABLE 1-43. Modal Shares of Freight Shipments within the United States by
Domestic Establishments: 1993 and 1997
TABLE 1-49. Value, Tons, and Ton- Miles of Freight Shipments within the United
States by Domestic Establishment, 1997
TABLE 1-52. U.S. Hazardous Materials Shipments by Mode of Transportation,
1997
TABLE 1-53. U.S. Hazardous Materials Shipments by Hazard Class, 1997
These data are collected via the 1997 Commodity Flow Survey (CFS) undertaken
through a partnership between the U.S. Department of Commerce, Census Bureau (Census),
and the U.S. Department of Transportation, Bureau of Transportation Statistics.
For the 1997 CFS, Census conducted a sample of 100,000 domestic establishments
randomly selected from a universe of about 800,000 multiestablishment companies
in the mining, manufacturing, wholesale trade, and selected retail industries.
It excluded establishments classified as farms, forestry, fisheries, governments,
construction, transportation, foreign, services, and most retail.
Reliability of the Estimates
An estimate based on a sample survey potentially contains two types of errors—sampling
and nonsampling. Sampling errors occur because the estimate is based on a sample,
not on the entire universe. Nonsampling errors can be attributed to many sources
in the collection and processing of the data and occur in all data, not just those
from a sample survey. The accuracy of a survey result is affected jointly by sampling
and nonsampling errors.
Sampling Variability
Because the estimates are derived from a sample of the survey population, results
are not expected to agree with those that might be obtained from a 100-percent
census using the same enumeration procedure. However, because each establishment
in the Standard Statistical Establishment List had a known probability of being
selected for sampling, estimating the sampling variability of the estimates is
possible. The standard error of the estimate is a measure of the variability among
the values of the estimate computed from all possible samples of the same size
and design. Thus, it is a measure of the precision with which an estimate from
a particular sample approximates the results of a complete enumeration. The coefficient
of variation is the standard error of the estimate divided by the value being
estimated. It is expressed as a percent. Note that measures of sampling variability,
such as the standard error or coefficient of variation, are estimated from the
sample and are also subject to sampling variability. Standard errors and coefficients
of variation for CFS data presented in this report are given in Appendix B of
the 1997 Economic Census report, and are available online www.census.gov/econ/wwwse0700.html.
Nonsampling Errors
In the CFS, as in other surveys, nonsampling errors can be attributed to many
sources, including 1) nonresponse; 2) response errors; 3) differences in the interpretation
of questions; 4) mistakes in coding or recoding the data; and 5) other errors
of collection, response, coverage, and estimation.
A potentially large source of nonsampling error is due to nonresponse, which
is defined as the inability to obtain all intended measurements or responses from
selected establishments. Nonresponse is corrected by imputation.
TABLE 1-50. Value of U.S. Land Exports to and Imports from Canada and Mexico
by Mode
The Transborder Surface Freight Data (TSFD) is derived from official U.S. international
merchandise import and export data. (For a description of U.S. merchandise trade
statistics, see www.census.gov/foreign-trade/www/index.html.)
As of December 1995, about 96 percent of the value of all U.S. imports has been
collected electronically by the Automated Broker Interface System. About 55 percent
of the value of all U.S. exports is collected electronically through the U.S./Canada
Data Exchange and the Automated Export Reporting Program. The balance is collected
from administrative records required by the U.S. Departments of Commerce and Treasury.
The TSFD incorporates all data, by surface mode, on shipments entering or exiting
the United States from or to Canada or Mexico. Prior to January 1997, this dataset
also included transshipments—shipments entering or exiting the United States by
way of U.S. Customs ports on the northern or southern borders even when the actual
origin or final destination of the goods was other than Canada or Mexico. (In
other U.S. Bureau of the Census trade statistics, transshipments through Canada
and Mexico are credited to the true country of origin or final destination.) To
make this dataset more comparable to other U.S. Census Bureau trade statistics,
detailed information on transshipments has been removed. The TSFD presents a summary
of transshipments by country, direction of trade, and mode of transportation.
Shipments that neither originate nor terminate in the United States (i.e., intransits)
are beyond the scope of this dataset because they are not considered U.S. international
trade shipments.
In general, the reliability of U.S. foreign trade statistics is very good.
Users should be aware that trade data fields (e.g., value and commodity classification)
are typically more rigorously reviewed than transportation data fields (e.g.,
the mode of transportation and port of entry/exit). Users should also be aware
that the use of foreign trade data to describe physical transportation flows may
not be accurate. For example, this dataset provides surface transportation information
for individual U.S. Customs districts and ports on the northern and southern borders.
However, because of filing procedures for trade documents, these ports may or
may not record where goods physically cross the border. This is because the information
filer may choose to file trade documents at one port while shipments actually
enter or exit at another port. The TSFD, however, is the best publicly available
approximation for analyzing transborder transportation flows. Since the dataset
was introduced in April 1993, it has gone through several refinements and improvements.
When improbabilities and inconsistencies were found in the dataset, extensive
analytical reviews were conducted and improvements made. However, accuracy varies
by direction of trade and individual field. For example, import data are generally
more accurate than export data. This is primarily because the U.S. Customs Bureau
uses import documents for enforcement purposes while it performs no similar function
for exports. For additional information on TSFD, the reader is referred to the
U.S. Department of Transportation, Bureau of Transportation Statistics Internet
site at www.bts.gov/transborder.
TABLE 1-51. Crude Oil and Petroleum Products Transported in the United States
by Mode
Pipelines
The Association of Oil Pipelines (AOPL) obtains barrel-miles from the Federal
Energy Regulatory Commission (FERC), which requires petroleum shippers to report
annual shipments. AOPL then coverts barrel-miles to ton-miles using conversion
figures in the American Petroleum Institute’s (API’s) Basic Petroleum Data Book.
Since 16 percent of pipeline shipments are intrastate and not subject to FERC
reporting requirements, AOPL makes adjustments to FERC data to include intrastate
shipments. AOPL also conducts periodic studies to estimate intrastate shipments.
Water Carriers
Data are from Waterborne Commerce of the United States, published by the U.S.
Army Corps of Engineers (USACE). All vessel operators of record report domestic
freight and tonnage information to USACE via ENG Forms 3925 and 3925b.Cargo movements
are reported according to points of loading and unloading. Certain cargo movements
are excluded: 1) cargo carried on general ferries, 2) coal and petroleum products
loaded from shore facilities directly into vessels for fuel use, 3) military cargo
moved in U.S. Department of Defense vessels, and 4) cargo weighing less than 100
tons moved on government equipment. USACE calculates ton-miles by multiplying
the cargo’s tonnage by the distance between the points of loading and unloading.
Motor Carriers
AOPL estimates ton-miles by multiplying tons by the average length of haul.
For crude, the tonnage of the prior year is projected by using a growth rate established
by data from the U.S. Department of Energy, Energy Information Administration’s
Petroleum Supply Annual, vol. 1, table 37. For products, the same calculation
is made but with a growth rate estimated by the American Trucking Association
in Financial and Operating Statistics, Class I and II, Motor Carriers, Summary
table VI-B. Average length of haul is determined from the prior six years of data
for ton-miles and tonnage of crude and petroleum products moved by motor carriers.
Railroad
AOPL calculates ton-miles by multiplying tonnage by average length of haul.
Tonnage data for crude and products comes from the Association of American Railroad’s
Freight Commodity Statistics, U.S. Class I Railroads. The U.S. Department of Transportation,
Federal Railroad Commission provides the average length of haul for crude and
products in its Carload Way Bill Statistics.
TABLE 1-54. Worldwide Commercial Space Launches
The U.S. Department of Transportation, Federal Aviation Administration, Associate
Administrator for Commercial Space Transportation (AST) licenses and regulates
U.S. commercial space launches as authorized by the Commercial Space Launch Act
of 1984 and Executive Order 12465.Every commercial space launch must be approved
and monitored by AST. Thus, data reliability is high.
TABLE 1-55. Passengers Denied Boarding by the Largest U.S. Air Carriers
TABLE 1-56. Mishandled-Baggage Reports Filed by Passengers with the Largest
U.S. Air Carriers
TABLE 1-57. Flight Operations Arriving On Time for the Largest U.S. Air Carriers
These numbers are based on data filed with the U.S. Department of Transportation
on a monthly basis by the largest U.S. air carriers – those that have at least
one percent of total domestic scheduled-service passenger revenues. Data cover
nonstop scheduled service flights between points within the United States (including
territories). The largest U.S. carriers account for more than 90 percent of domestic
operating revenues. They include Alaska Airlines, America West Airlines, American
Airlines, Continental Airlines, Delta Air Lines, Northwest Airlines, Trans World
Airlines, Southwest Airlines, United Airlines, and US Airways. However, there
are other carriers offering domestic scheduled passenger service that are not
required to report. In some cases, major airlines sell tickets for flights that
are actually operated by a smaller airline that is not subject to the reporting
requirement.
TABLE 1-58. U.S. Air Carrier Delays Greater than 15 Minutes by Cause
The source of these data, the U.S. Department of Transportation (USDOT), Federal
Aviation Administration (FAA), counts a flight as delayed if it departed or arrived
more than 15 minutes after its scheduled gate departure and arrival times. FAA
calculates delayed departures based on the difference between the time a pilot
requests FAA clearance to taxi and the time an aircraft’s wheels lift off the
runway, minus the airport’s standard unimpeded taxi-out time. Users should note
that taxi-out time varies by airport due to differences in configurations. The
cause of delay is also recorded, e.g., weather, terminal volume, closed runways,
etc.
USDOT guidance defines departure as the time the aircraft parking brake is
released and gate arrival as the time the brake is set. According to the USDOT’s
Office of the Inspector General (OIG), FAA’s omission of part of a plane’s ground
movement compromises the data’s validity. A recent OIG report noted that the FAA
tracks ground time only after a pilot requests clearance and fails to track a
plane’s time in the ramp area. OIG found that ramp time comprised 28.7 percent
to 40.5 percent of the average taxi-out time at the three major New York area
airports (OIG Audit Report CR-2000-112), and would not be counted as an FAA delay.
Reliability
Several data collection changes complicate comparisons over time. For example,
FAA modified its method for calculating volume-related delays that resulted in
a 17 percent drop in such delays. Decreases in volume-related delays from 1998
to 1999 totaled less than one percent. Moreover, prior to 1999, USDOT did not
provide a clear definition of what a departure was. An OIG Audit (CE-1999-054)
report noted that air carriers used four different departure events: 1) rolling
of aircraft wheels; 2) release of parking brake; 3) closure of passenger and/or
cargo doors; and 4) a combination of door closures and release of the parking
break. The same report also noted errors in the reporting of departure times by
the air carriers.
Data are now manually entered in FAA’s Operations Network (OSPNET) database,
and reporting errors may arise and decrease reliability. The FAA monitors data
quality assurance by spot checking the reported delay data and requesting that
discrepancies be reviewed by the responsible facility. According to an OIG Audit
(CR-2000-112), however, mistakes are not reliably corrected and many air traffic
controllers suggested that delays are underreported sometimes by as much as 30
percent.
TABLE 1-59. Major U.S. Air Carrier Delays, Cancellations, and Diversions
A second data source for air-carrier delay is the USDOT, Bureau of Transportation
Statistics, Office of Airline Information (OAI). This information originates from
the Airline Service Quality Performance data. These figures are collected from
the largest airlines—those that have at least one percent or more of total domestic
scheduled service passenger revenues. Delays are categorized by phase of flight
(i.e., gate-hold, taxi-out, airborne, or taxi-in delays). These data differ from
FAA’s OSPNET information due to differences in definition of delay.
While the FAA tracks delays on the taxiway, runway, and in the air, BTS tracks
delays at the departure and arrival gates. OAI calculates delays as the difference
between scheduled and actual gate departure. If a flight leaves the gate within
15 minutes of its scheduled time, then OAI would record it as departed on-time
even if it sat for several hours on the ramp or runway, in which case the delay
would be accounted for as a late arrival.
TABLE 1-60. Annual Person-Hours of Delay Per Eligible Drive
TABLE 1-61. Roadway Congestion Index
TABLE 1-62. Congestion Index and Cost Values
The Texas Transportation Institute’s (TTI) Urban Roadway Congestion Annual
Report provided figures for tables 1-54 through 56.TTI relies on data from the
U.S. Department of Transportation, Federal Highway Administration, Highway Performance
Monitoring System database (HPMS). TTI utilizes these data as inputs to its congestion
estimation model. Detailed documentation for the TTI model and estimations can
be found at this website http://mobility.tamu.edu/study/index.stm.
Structure, Assumptions, and Parameters
Urban roadway congestion levels are estimated using a formula measuring traffic
density. Average travel volume per lane on freeways and principal arterial streets
are estimated using area wide estimates of vehicle-miles of travel (vmt) and lane
miles of roadway. The resulting ratios are combined using the amount of travel
on each portion of the system so that the combined index measures conditions on
the freeway and principal arterial street systems. Values greater than one are
indicative of undesirable congestion levels. Readers seeking the algorithm for
the congestion index should examine this website http://mobility.tamu.edu/study/numbers.stm.
Annual person-hours of delay results from the multiplication of daily vehicle-hours
of incident and recurring delay times 250 working days per year times 1.25 persons
per vehicle. Two types of costs are incurred due to congestion: time delay and
fuel consumption. Delay costs are the product of passenger vehicle hours of delay
times $12.00 per hour person time value times 1.25 occupants per vehicle. Fuel
costs are calculated for passenger and commercial vehicles from the multiplication
of peak period congestion speeds, the average fuel economy, fuel costs, and vehicle-hours
of delay.
In previous reports, the TTI methodology assumed that 45 percent of all traffic,
regardless of the urban location, occurred in congested conditions. TTI indicated
that this assumption overestimated travel in congested periods. Thus, their 1999
estimates now vary by urban area anywhere from 21 percent to 50 percent of travel
that occurs in congestion. TTI’s model structure applies to two types of roads:
freeways and principal arterial streets. The model derives estimates of vehicle
traffic per lane and traffic speed for an entire urban area. Based on variation
in these amounts, travel is then classified under 5 categories: uncongested, moderately
congested, heavily congested, severely congested, and extremely congested (a new
category in 1999). The threshold between uncongested and congested was changed
in 1999. Previous editions classified congested travel when areawide traffic levels
reached 13,000 vehicles per lane per day on highways and 5,000 vehicles per lane
per day on principal arterial streets. These thresholds were raised in the latest
report to 14,000 and 5,500 vehicles per lane per day respectively. Comparisons
across time will be questionable due to these changes. For instance, TTI applied
the new methodology to 1996 data that resulted in lower congestion levels. Readers
should refer to the TTI Internet site for more detailed algorithms and estimation
procedures at http://mobility.tamu.edu/estimating_mobility.
TTI reviews and adjusts the data used in their models. State and local officials
also review the TTI data and estimations. Some of the limitations acknowledged
in the TTI report include the macroscopic character of the index. Thus, it does
not account for local variations in travel patterns that may affect travel times.
The index also does not account for local improvements, such as ramp metering
or travel speed advantages obtained with transit or carpool lanes.
TABLE 1-63. Amtrak On-Time Performance Trends and Hours of Delay by Cause
Amtrak determines on-time performance through its computer system maintained
at the National Operations Center (NOPS) in Wilmington, Delaware. If a train is
delayed, a call is made to the NOPS for recordkeeping. These data can be supplemented
with computer entries made for locomotive or car malfunctions that cause delays.
These data should be considered reliable.
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