Transportation
The
movement of people and goods from place to place is known as transportation.
Together with communication--the movement of ideas--transportation has been
essential in bringing about the integration of regions and nations into a single
world community. Transportation movements, combined into various systems and
networks, are by way of land, water, and air and by such means as automobile,
airplane, railroad, ship, and pipeline.
The Need for Transportation
Transportation is needed because few economic resources--raw materials,
fuels, food, manufactured goods--are located where they are wanted. Each region
or place on Earth produces more than it consumes of some goods and services and
less than it consumes of others. Through transportation, goods are moved from
where there are surpluses to where there are shortages. Improved transportation
has extended the areas in which various goods can be profitably marketed and
thus has helped make the goods widely available.
The
moving of people to places of work, education, and recreation and for their
other needs and wants also requires transportation. Like goods, people are
moved to where they are needed. But as decision makers people also travel to
where they want to be. In recreational activities, such as pleasure driving,
transportation can be an end in itself.
The
demand for transportation is derived from the need for people and goods to be
at a particular place. In satisfying this need, transportation gives people and
goods greater value and place utility. Sometimes, as in the aging of wine or
the ripening of bananas while they are en route to their destinations, goods
may acquire greater form utility. The in-transit storage of goods provided by a
vehicle may reduce the need for warehouse space at the destination. This is an
example of time utility--getting goods to a destination at the time of their
greatest usefulness.
The
demand for transportation--and the rate of actual traffic flow--tends to be
proportional to the population of the destination area. Traffic flow between
two areas also depends on their proximity--flow generally tends to be greater
the closer the areas are to each other.
The
concentration of transportation services in heavily urbanized and industrialized
areas is a result of the great amount of traffic. However, political or
military considerations or prospects for future economic growth may lead to the
construction of transportation facilities even where they are not profitable.
Economic development in nonindustrialized countries, for example, commonly
requires extensive investment in roads, airfields, harbors, and other transport
facilities long before there is much traffic.
In
industrialized countries such as the United States, transportation routes
traditionally have been provided for in advance of other economic development.
The Cumberland Road, for example, was built early in the 1800s to open the Ohio
Valley to settlement. The Erie Canal, completed in 1825, helped settle the
Great Lakes region. Federal land grants to railroad companies in the 19th
century helped settle the West. In Canada roads and railroads were being
extended to the north in the 1960s and 1970s to facilitate settlement and the
exploitation of natural resources. In the long run, transporting goods from one
place to another is justified only if the goods can be produced cheaply enough
at the first place so as to offset the transportation cost to the second.
Transportation Modes
The
various means, or modes, of transportation consist of both the specific types
of vehicles used and the facilities needed for their movement. The modes
include people walking and carrying loads, human-powered machines such as
bicycles, draft animals pulling wagons and coaches, and pack animals; motor-powered
highway vehicles such as trucks, buses, automobiles, taxis, and motorcycles;
water carriers such as ships, barges, hydrofoils, and hovercraft; railroad
trains; aircraft; and devices such as chutes, conveyor belts, pipelines, and
electric lines.
Transportation modes can be classified by whether they are by land,
water, or air; by how they are powered; by whether they use continuous flow or
not; by whether they carry passengers or freight or both; and by whether or not
they use fixed routes. Such distinctions are blurred somewhat by the fact that
several modes are typically used for the entire movement of persons or goods
from initial origin to final destination.
For
example, a woman traveling from Chicago, Ill., to New York City may take a bus
and a subway train to get to Chicago-O'Hare International Airport, where she
can board an airplane for New York's La Guardia Airport. At La Guardia she may
reverse the process, riding buses and subway trains until she reaches her
destination. For the trips to and from the airports she might instead have used
an automobile or a taxicab. She might have traveled cross-country by
automobile, bus, or train instead of by airplane.
A
transport vehicle such as an automobile, an airplane, or an ordinary ship has
both its motive power and its facilities for carrying goods or people in the
same unit. In other cases, such as a train of railroad cars pulled by a
locomotive, the barges pushed or pulled by a towboat, or the highway trailer
pulled by a truck tractor, the motive power and the cargo or passengers are in
separate units. When power and payload units are separate the power vehicle can
be utilized elsewhere while the carrier vehicles are being loaded or unloaded
or are in storage. Separation of units also permits changes in the number of
carrier vehicles, as with a railroad train or a barge tow, as the volume of
traffic varies.
The
power for moving a vehicle may be furnished by a natural process such as wind
or gravity. The power may be generated in an engine by the burning of fuel such
as wood, charcoal, coal, gasoline, kerosine, or fuel oil. Power may also be
furnished by an electric motor operated from batteries, an overhead wire or
third rail, or a diesel engine such as in a diesel-electric locomotive. Diesel
engines have increasingly replaced steam engines in maritime and railroad
transportation and are also used in buses and trucks. Gasoline engines are used
in automobiles and also in many buses and trucks. Turbines--both jet and
propjet--have replaced engines using reciprocating pistons in most airline
transportation.
Freight Transportation
Heavy or
bulky goods and those of low value in proportion to their weight or bulk
generally tend to be moved by transportation modes that use large vehicles such
as ships and barges, which travel at slow speeds. Compact, perishable, and
high-value goods tend to be moved by transportation modes that use small
vehicles such as trucks and especially aircraft, which travel at high speeds.
Goods
being transported can be classified into general cargo, or package freight, on
the one hand and bulk cargo on the other. General cargo usually consists of
merchandise, including manufactured items such as machinery, that has a high
value in proportion to its weight or to the space it occupies in a vehicle.
Bulk cargo generally consists of goods that are of low value in proportion to
their weight or bulk. They include ores, grains, coal, oil, petroleum products,
and other raw materials and fuels.
General
cargo may be transported in boxes, crates, bales, barrels, and other
containers. Because of the great variety of shapes, sizes, and weights of
general cargo, its handling is less easily mechanized and requires a larger
labor force than the handling of bulk cargo. Bulk goods can be conveniently
taken on and off ships, railroad cars, trucks, barges, and other carriers by
means of gravity, suction, conveyor belts, pipes, or other continuous-flow
devices. When being loaded, bulk goods also are able to flow around obstructions
in a vehicle and thus fully occupy the available cargo space. Most of the
world's shipping is designed primarily for the movement of bulk goods.
Bulk
cargoes can be classified into dry bulk and liquid bulk. Dry bulk goods can be
packaged, such as in bags or bales, but more commonly they are not. Sugar, for
example, formerly handled only in bags, is increasingly being transported in
bulk. Dry bulk goods often are moved in specially designed vessels. They
frequently are handled in ships as "bottoming cargo," to fill any
last-minute unused capacity. In some cases dry bulk goods are moved by overland
pipeline. Even some solids, such as coal and ores, can be moved through pipes
in a liquid suspension, or slurry. Electricity is transported by power lines, a
continuous-flow device.
Liquid
bulk goods are transported either by continuous flow in pipelines or by
tankers, barges, trucks, or railroad cars. Tankers account for about half the
tonnage capacity of all oceangoing merchant ships. Their average size is much
larger than that of any other type of ship. Some supertankers have capacities
of more than 300,000 tons. The principal cargo carried by tankers is crude oil,
the leading commodity in international trade (see Petroleum,
"Transportation and Distribution of Oil").
Many
small tankers, uncompetitive with supertankers for moving oil on the longer
voyages, are used for moving grain. Some vessels, known as oilbulk-ore vessels
(OBOs), carry oil in one direction and ore on the return voyages. There also
are specialized tanker ships that carry such chemicals as heated liquid sulfur
or extremely cold liquefied natural gas. Specialized railroad tank cars and
highway trucks also are designed to carry chemicals and other products under
controlled temperatures and pressures.
Freight
transportation in the United States is dominated by railroads. They carry about
40 percent of the total volume, measured in ton-miles. Railroad freight
traffic, while chiefly bulk, is the most diversified of any transportation
mode. Motor truck traffic between cities in the United States has been
increasing rapidly since the 1920s when it first became a significant mode of
transportation. Trucking accounts for about 20 percent of total freight volume.
But because trucks carry general merchandise with a high average value per ton,
they account for more than half the revenues from all domestic freight. Even
when cargo is moved between major terminals by rail, air, or water carriers, it
is usually picked up and delivered by truck.
Inland
waterways in the United States, including the Great Lakes, account for about 15
percent of the total freight volume. Traffic is almost entirely of bulk goods,
chiefly iron ore, coal, petroleum, lumber, steel, grain, and chemicals. Powerful
diesel towboats and barge tows on the rivers can carry about 40,000 tons of
cargo each. Oil pipelines in the United States account for more than 20 percent
of the total freight traffic. Pipeline transportation of crude oil and
petroleum products has largely replaced coastal tanker and railroad tankcar
transportation. Air cargo traffic, although increasing rapidly, accounts for
less than one percent of the total. The goods carried tend to be perishable,
compact, and valuable.
One of
the most common methods of handling freight cargoes is stacking individual
crates, boxes, and bales on wood or metal platforms known as pallets. Pallets
are moved onto or off vehicles by forklift trucks, cranes, or various kinds of
conveyors specially designed to transport pallets.
Cargo
can also be stuffed into large, uniform-size metal containers. Such containers
are placed in general-cargo ships, in specially designed container ships, and
on barges. They can be carried "piggyback" by railroad trains as
trailer-on-flatcar (TOFC) or as container-on-flatcar (COFC) cargo. In TOFC,
truck semitrailers (with their wheel assemblies) are loaded; in COFC,
containers (without wheels) are loaded. Truck semitrailers and containers are
also placed on flatbed trailers hauled by highway truck tractors. The
semitrailers and containers can easily be loaded aboard a ship or barge, either
by large cranes or, in the case of vessels known as Ro-Ro (Roll-on Roll-off),
by means of ramps. Some containers are carried on wide-bodied jet aircraft.
A large
container ship, because of its greater size and speed and less time spent
loading and unloading in port, can often replace four to six conventional
general-cargo vessels and can move the cargo at much lower cost. Container
ships were first built in large numbers in the late 1960s. As a result, many
conventional ocean freighters were made obsolete, as were the port facilities
that had been designed and located to handle their cargoes.
Containerization is not new. Ordinary trucks and railroad boxcars are
forms of containers. But unlike modern containers, each may be loaded with a
variety of merchandise that must be divided at a freight station and sent to
several destinations. Such less-than-carload (LCL) traffic can be handled more
efficiently by truck than by railroad because a truck can be driven directly to
a destination area and provide door-to-door service.
Passenger Transportation
In
metropolitan areas of the United States, movements of people between home and
work account for about 40 percent of the total number of passenger journeys.
Recreational trips account for about 15 percent of all trips in the typical
urban area. Automobile riding, for example, is not only a means of reaching a
destination but is a popular form of outdoor recreation. Recreational boating
also is popular. Cruise ships have made up the major proportion of ocean-going
passenger vessels since jet aircraft became the favored mode of transoceanic
travel. (See also Travel and Tourism.)
The
automobile dominates intercity passenger transportation in the United States.
It accounts for more than 80 percent of the total passenger miles. No other
mode of transportation approaches the flexibility and convenience of the
automobile, which provides door-to-door service independent of schedules.
The
railroad is no longer a major means of intercity passenger transportation in
the United States, though railroad passenger service thrives in much of the
rest of the world. As recently as the early 1940s there were more than 20,000
daily intercity passenger trains in the United States. By the early 1970s there
were only about 200. Whereas railroads accounted for almost 70 percent of the
total passenger-miles by public carrier in 1930, by 1970 they accounted for
less than one percent. In 1971 the National Railroad Passenger Corporation, a
federal agency that is also known as Amtrak, took over most of the intercity
railroad passenger service. Most Amtrak trains operate in the Northeast
corridor between Boston, Mass.; New York City; Philadelphia, Pa.; Baltimore,
Md.; and Washington, D.C. A large proportion of the New York-Washington service
is by high-speed electric trains called Metroliners. There is suburban railroad
passenger service in the metropolitan areas of such large cities as New York,
Chicago, Philadelphia, Boston, and San Francisco. Electric interurban railroads
and street railways in cities have almost disappeared.
Intercity scheduled buses in the United States serve many more
communities than do railroads. Using modern expressways, they provide swift
service between major cities, though many communities not on expressways now
have much less bus service than they formerly had. Air carriers dominate public
intercity passenger transportation in the United States. The growth of air
passenger traffic has been rapid, increasing from only 14 percent of the total
in 1950 to more than 85 percent in the 1980s. Passenger travel by water
carriers in the United States is insignificant except for some ferry services.
Carrier Organizations
There
are several types of transportation carrier organizations. Common carriers
offer their services to the general public at standard terms and rates. They
usually operate over fixed routes and on regular schedules. In the United States
all interstate common carriers are regulated by the federal government. Almost
all railroads and intercity bus services are common carriers, as is much of
intercity trucking, inland waterway barge traffic, and petroleum pipelines. All
are regulated by the Interstate Commerce Commission (ICC) or by individual
states. Almost all scheduled airlines in the United States are regulated by the
Federal Aviation Administration (FAA).
Shipping
lines participate in international conferences, or cartels, which set the
schedules and usually the rates charged for common carriers on most major ocean
routes. They compete with nonconference lines, however, and face the
possibility that large-scale users of ships might operate their own vessels if
conference rates are too high. International scheduled airline services are
operated by agreement with the affected countries. They are largely regulated
by the International Air Transport Association (IATA).
Contract
carriers carry people or goods by agreement with a limited number of shippers.
They do not operate over fixed routes or on regular schedules. They include
tramp ships, which operate under charter and mainly carry shiploads of bulk
cargo rather than general cargo. Nonscheduled, or supplementary, airlines and
the charter services of scheduled airlines also are examples of contract
carriers, as are urban taxicabs and charter buses. Contract carriers carry a
large share of the world's ocean cargo.
Private
carriers serve individual or corporate owners. They are not for hire to the
public. Most automobiles in the United States are private carriers. Many
companies operate their own truck fleets, and some of the largest shippers,
especially petroleum companies, operate their own ships and barges.
Transportation Terminals
A
transportation terminal is the place where goods and people are transferred
from one carrier or mode to another. It is the place where vehicles are loaded
and unloaded or where several vehicles are assembled into or separated from
trains. Terminals are located where transportation routes intersect and where
journeys or shipments begin or end. They include seaports, airports, railroad
yards and depots, truck terminals, bus stations, and automobile parking lots.
Transportation terminals tend to be located within or close to a city's
downtown area. But the need for large tracts of land at relatively low cost
often requires locations in outlying areas. For example, a 700-foot-
(200-meter-) long berth for a container ship requires as much as 25 acres (10
hectares) of adjoining land for assembling and distributing cargoes by truck
and rail. As a result, many port terminals, often located along congested
downtown waterfronts, have been abandoned. Larger terminals have been
established most commonly on the seaward edges of such large port cities as
Rotterdam, The Netherlands.
Modern
commercial airports require even more space. Chicago-O'Hare International
Airport, for example, covers ten square miles (25 square kilometers). Even
larger are airports such as those for Dallas-Fort Worth, Tex.; Kansas City,
Mo.; and Los Angeles, Calif. Airports also need unobstructed space for long
distances past the ends of their runways. A modern railroad classification
yard, in which trains are assembled and disassembled, may be as much as 1/2 by 5 miles (1 by 8 kilometers).
In many
cases, the relocation of freight terminals has been due to the increased
decentralization of the industrial and commercial establishments that are the
sources and destinations of freight traffic. Decentralization is also a result
of the improved access that modern highways have given to outlying areas. The
traffic congestion, noise, and air and water pollution associated with
transportation activities also make it desirable to locate terminals away from
residential areas. As a side effect of decentralization, much of the land
formerly needed by railroads and ports for central-city terminals has become
available for nontransportation uses.
Passengers wait for the arrivals and departures of common and charter
carriers at airport, railroad, and bus terminals. Amenities include ticket
offices, waiting rooms, toilet facilities, and a variety of business
establishments. In terminals handling international traffic, there are customs,
immigration, public health, and quarantine facilities. In and near major
railroad stations and airports there often are hotels.
Transportation Routes
A
transportation route is the regular path that is followed by a movement of
people or goods. Ideally it follows the shortest possible distance--a straight
line, or what is known on the curving surface of the Earth as a great circle.
But natural barriers, such as intervening landmasses on ocean routes, often
block such direct paths. Inland waterways usually follow the winding courses of
river valleys. Land routes bend to avoid steep slopes or to go around bodies of
water. Air routes deviate from straight lines to avoid bad weather or to make
use of tail winds. Transportation routes may also deviate from straight lines
to tap intermediate sources of traffic or to avoid crossing specific political
boundaries.
The
world's largest volume of ocean traffic is across the North Atlantic between
the highly urbanized, industrialized, and densely populated regions of eastern
North America and Western Europe. Branches of the North Atlantic sea route on
the North American side lead to ports up the St. Lawrence River and on the
Great Lakes and to ports on the East and Gulf coasts. On the European side one
branch leads to and from ports in northern Europe; another passes through the
Mediterranean Sea, leading to and from ports in southern and eastern Europe,
the Middle East, and northern Africa. Mediterranean ports compete with those on
the Atlantic and on the North and Baltic seas for the trade of the European
interior, much as the Great Lakes, Gulf coast, and Atlantic ports compete for
the trade of the North American interior. Through the Suez Canal the
Mediterranean route connects with Indian Ocean routes to India, Japan, and
other countries in southern and eastern Asia.
Another
major sea route, through the Panama Canal, links the seaboards of Western
Europe and eastern North America with the western coasts of North America and
South America. Major routes also extend from the Panama Canal across the
Pacific Ocean to Australia and New Zealand and to Japan and the eastern and
southeastern coasts of Asia. Other transpacific routes directly link western
North America and eastern Asia.
Another
major world shipping route across the Atlantic links Western Europe with Brazil
and eastern South America. A branch of this route that curves around southern
Africa links Western Europe with ports in Africa and on the Indian Ocean,
replacing the Suez Canal route. Another major route is that between the Persian
Gulf and Japan.
The
world pattern of air routes is similar to that of ocean routes, though an
airplane can follow a more direct route than a ship can. The heaviest volume of
international air traffic, like sea traffic, is across the North Atlantic
between North America and Europe. There is also a great volume of air traffic
between the various countries of Europe as well as on domestic flights within
such major countries as Russia and the United States. The most heavily used
airways in the United States are between Boston, New York City, and Washington,
D.C.; New York City and Chicago; and Los Angeles and San Francisco.
Inland
waterways are concentrated in the world's heavily populated river basins and
lowland plains. Among the busiest are the Great Lakes-St. Lawrence Seaway and
the Mississippi and Ohio rivers in North America, the Rhine River and other
rivers and canals in northwestern Europe, and the system centering on the Volga
and Don rivers in Eastern Europe. The United States has about 25,000 miles
(40,200 kilometers) of inland waterway routes, including the Atlantic and Gulf
intracoastal waterways. Land transportation routes are densest where urban
commercial and industrial activities are the most extensively developed. Such
core regions are in the central and eastern United States and southeastern
Canada, in northwestern Europe, and in Japan. Other major transportation
concentrations include the Pacific coast of North America, the Rio de
Janeiro-Sao Paulo area of southern Brazil, the Ganges plain of northern India,
the eastern areas of China, and south-eastern Australia.
The
nets, or webs, of transportation routes are less densely developed in regions
such as the interior western United States, the southern part of western
Canada, Spain and Portugal, and southern Sweden and Norway. Some regions are
served by railroads and highways that connect with transportation nets only at
one end. Such transportation tentacles extend to otherwise isolated localities
such as mining areas, logging camps, and other resource-extracting settlements.
Examples are the rail lines and highways extending into northern Canada and
into Siberia. Because of geography some sparsely settled regions such as the
Amazon Basin of South America have few or no railroads and are served by inland
waterways, air routes, and a few roads.
In the
United States and Canada the transportation web is densest in the general area
bounded by the Ohio and Potomac rivers on the south, the Missouri River on the
west, and the St. Lawrence Valley. Several corridors within this densely
populated, highly industrialized core region of North America generate
extremely heavy movements of both goods and passengers. The most noted corridor
is through the megalopolis stretching between Boston, New York City,
Philadelphia, Baltimore, and Washington, D.C. Others are the axis between
Detroit, Mich.; Cleveland, Ohio; and Pittsburgh, Pa.; the corridor from Chicago
to Milwaukee, Wis.; and the corridor connecting Detroit; Toronto, Ont.;
Montreal; and Quebec, Que.
In the
southeastern United States, goods traffic very often moves to and from ocean
and river ports. There also are major centers of passenger and freight traffic
in the interior, such as at Atlanta, Ga.
In the
interior of the western United States, transportation routes are spaced much
farther apart, a reflection of the low population density. But on the heavily
populated Pacific coast, a north-south corridor of closely spaced rail,
highway, and air routes links San Diego, Calif.; Los Angeles; the San Francisco
Bay area; and the Willamette Valley-Puget Sound-Strait of Georgia cities of
Portland, Ore.; Tacoma and Seattle, Wash., in the United States and Vancouver,
B.C., in Canada.
There
were only about 172,900 miles (278,250 kilometers) of railroad routes in the
United States in the late 1980s, as compared with about 254,000 miles (408,760
kilometers) in the peak year of 1916. Railroad mileage has steadily fallen as
little-used branch lines have been abandoned in favor of highways. The United
States has about 3.5 million miles (5.6 million kilometers) of surfaced roads.
A network of pipelines links the Gulf coast and interior oil fields to the
northeastern urban areas. Other major pipelines serve the Pacific coast.
All-water transportation routes via southern Africa, the Panama Canal,
and the Suez Canal (before 1967) have faced increasing competition from
land-sea combination routes that cross North America or Eurasia. Traffic from
Japan to Europe, for example, may be routed first by ship across the Sea of
Japan to Russia and then on the Trans-Siberian Railroad across Eurasia. Traffic
from Japan to the eastern United States may be routed first by ship across the
Pacific and then by rail or highway across the United States. Traffic from
North America's West coast to Europe may be routed first by rail or highway
across to the East coast and then by ship across the Atlantic. Speedier
transfer of cargoes between ships and overland carriers at the ports has
greatly facilitated this choice of routings.
The
world pattern of transportation routes changes slowly. The most important
recent changes are a result of the growth of air transportation; the
development of routes from new sources of fuels and metals in formerly isolated
regions such as Labrador, northwestern Australia, and central Africa; the
closing of the Suez Canal in 1956 and 1967; the opening of the enlarged St.
Lawrence Seaway in 1959; and the opening of the Arkansas River to large-scale
barge navigation in 1971. Transportation routes also have changed as
supertankers, OBO vessels, container ships, and railroad piggyback service have
been introduced.
Transportation Costs
Transportation costs depend primarily on distance and on the amount of
goods or the number of people being carried. Reduced costs are generally
achieved through the use of transportation modes that permit larger volumes or
numbers to be moved. Savings are also realized by using as much as possible of
the capacity of a particular mode or vehicle. For many movements of passengers
and goods, however, the primary aim is not low cost but greater speed,
convenience, or comfort. Such convenient modes as the private automobile or the
taxicab, for example, are much costlier to use than a bus or train.
The cost
of transportation includes both terminal costs and line-haul costs. Terminal
costs are those incurred in assembling and distributing passengers and goods
and loading them onto and unloading them from the vehicle. In the case of
railroads they include the costs of making and breaking trains. The transfer
from one mode to another, as between land and water carriers at a port, also is
a terminal cost. Linehaul costs are those incurred in the actual movement of
goods or people between terminals. They are generally proportional to distance,
or length of haul (and fuel costs), and to time (and labor costs).
Another
distinction is between fixed costs and variable costs. Fixed costs--also known
as overhead, or constant, costs--include administration, sales, financing,
insurance, rents, depreciation, and taxes. They are largely independent of
particular transportation movements. Variable costs--also known as marginal, or
out-of-pocket, costs--such as for fuel, are those attributed to a particular
transportation movement and depend on actual traffic volume.
Costs
are partly related to the load factor, the proportion of the capacity of the
vehicle that actually carries the payload of cargo or passengers. If, for
example, a 100-seat airplane carries 60 passengers, its load factor is 60
percent. Transportation operators try to achieve as high a load factor as
possible by offering less frequent service during off-peak periods than during
peak periods. In this way they can meet the increased demands of peak periods
but not be saddled with unused capacity at other times.
Most
rates and fares charged shippers and travelers fall between what are known as
the value of service and the cost of service. The value of service is the
maximum rate or fare that can be charged. If the charge is higher, transfer or
substitution will take place--the traveler or shipper will find another
transportation mode, another carrier of the same mode, another destination,
another source of supply, another market, or cancel altogether.
If the
carrier is a private enterprise, as are most transportation services in the
United States, the total rates and fares charged must be sufficiently above the
cost of service so as to give the carrier a profit. If traffic is carried at
below cost, the loss must be made up by some form of public subsidy--that is,
the government and the taxpayers share the transportation costs with the
operators and the users. The desirability of a public subsidy is based on estimating
whether the public benefit is great enough.
Early History of Transportation
Throughout most of human history, people's movements on land were
restricted to those speeds and distances that could be attained by walking. The
use of sledges, pack animals, and then draft animals pulling wheeled vehicles
increased the distance that early men could traverse and the amount of goods
that they could transport (see Wheel).
Long-distance transportation was mainly by water--on rivers and lakes,
along seacoasts, and from island to island, usually in sight of land. Early
vessels, propelled by currents and by paddles or poles, included rafts made of
reeds or branches, boats made of skins, and dugout canoes. Later vessels used
sails, which harnessed the wind. Extensive water commerce was carried on by the
civilizations in ancient Phoenicia, around the Aegean Sea, and along the
valleys of the Nile River in Egypt, the Tigris and Euphrates rivers in
Mesopotamia, the Indus River (now in Pakistan), and the Yellow River in
China.
Some of
the earliest long-distance overland trade routes date from around 2000 BC. These were the trails along which amber was carried from near the
Baltic Sea to the Mediterranean and Aegean seas. Starting in the 6th century BC, the Persian rulers Cyrus and Darius built a road system in their
empire. Around the end of the 4th century BC a road system was built in the Maurya Empire of India. Camel caravans
carried silk from China to Europe on trails that perhaps predate the 4th
century BC. By the 3rd century AD the road network of the Roman Empire had reached Britain, Gaul (modern
France), and the eastern Mediterranean region.
During
the Middle Ages, improved sailing vessels and the magnetic compass made
open-sea voyages out of sight of land much safer (see Navigation).
Voyages of discovery in the 15th and 16th centuries greatly enlarged the world
known to Europeans. An extensive sea trade developed, with merchant vessels
carrying gold and silver from Latin America, tea and spices from the Orient,
and slaves from Africa.
Meanwhile, advances were being made in bridge and road construction, and
the lock gate for canals was developed. Between the 16th and 18th centuries an
extensive canal system was built in France. Transportation improvements in
18th-century Great Britain included the establishment of a turnpike (toll road)
system and the use of iron for bridge construction. In 1815, John Loudon
MacAdam first built a macadamized road, surfaced with compacted broken stone.
The American
Indians did not have wheeled vehicles. Some tribes carried goods on an A-shaped
drag called a travois. Indian trails often followed animal trails. For inland
water transportation the Indians and later the European colonists used dugout,
bark, or skin canoes (see Indians, American).
Late in
the 18th century gravel roads were introduced in the United States. One of the
first was a toll road, the Lancaster Turnpike in Pennsylvania. Plank roads and
corduroy roads, made of lumber or logs laid side by side on the roadbed to
overcome dust and mud, were built in the 1830s and 1840s. By the early 1800s
transportation was being provided by animal-drawn Conestoga wagons and
stagecoaches.
Flatboats were common on inland waterways. The opening of the Erie Canal
in 1825 heralded a great era of canal building that linked the Atlantic
seaboard with the lands west of the Appalachians. After 1818, packet ships
regularly sailed across the Atlantic to Europe. In the mid-1800s, fast,
efficient clipper ships were built to sail from Atlantic ports around South
America to California and the Orient.
Steam Power
The use
of steam power to drive vehicles was applied as early as 1769 when a Frenchman,
Nicolas Cugnot, demonstrated a steam carriage intended for use on common roads.
It was in water transportation, however, that the early use of steam power was
the most successful and enduring.
A
short-lived steamboat service was begun by John Fitch on the Delaware River in
1790. In 1807 Robert Fulton established a successful steamboat line on the
Hudson River (see Fitch; Fulton). By the 1820s, steamboats plied the
Great Lakes and the rivers of the Mississippi and Ohio valleys. Along with the
development of canals, their use greatly reduced shipping costs to and from the
interior and helped open vast areas of North America to settlement. During that
same time, steamships were introduced onto European sea routes. The first
oceangoing steamship, the Savannah, crossed the Atlantic from Savannah, Ga., to
Liverpool, England, in 1819, although it used sails for most of the voyage. By
the 1840s, vessels were crossing the Atlantic entirely by steam power. In 1840
Samuel Cunard established the first regularly scheduled steamship line between
England and North America. These early steamships were wooden and were
propelled by side paddle wheels. They were primarily passenger and mail ships,
since their cargo capacity was limited by the large space needed to carry coal
for fuel on long ocean voyages.
With the
adoption of the speedier screw propeller, the building of stronger iron-hulled
vessels, and the establishment of coaling stations along their routes, ocean
steamships by the 1890s had exceeded sailing ships in tonnage carried. Sailing
ships soon were eliminated from long-distance ocean trade.
New,
shorter ocean routes were established. The Suez Canal, opened in 1869, enabled
vessels to bypass the long voyage around Africa on routes between Europe and
Asia. The Panama Canal, opened in 1914, bypassed the voyage around South
America on routes between Atlantic and Pacific ports.
Growth of Railroads
Railroads were used in European mines as early as the mid-1500s. Men or
animals pushed wagons loaded with ore along wooden tracks. Later, iron tracks
were used and, with the advent of steam power, wagons were hauled by ropes
connected to stationary engines. In Wales in 1804, Richard Trevithick
demonstrated the first successful railroad steam locomotive. In 1825 the
Stockton and Darlington railway near Newcastle, England, became the first
common carrier to use steam locomotives.
In the
United States the Baltimore and Ohio Railroad and the South Carolina Railroad
began operation in 1830. Like the early roads, they were inland feeders to
ports. Railroads spread rapidly in the eastern and southern United States, with
short lines being merged to form through routes. By the mid-1850s, railways
linked the Atlantic seaboard and the Midwest. In 1869 the first
transcontinental route was completed to the Pacific coast.
Railroads
became the dominent mode of overland transportation in the last half of the
19th century. Faster and more powerful locomotives and larger freight and
passenger cars were built. Standardization of track gauges and the adoption of
standard time zones aided efficiency. The invention of air brakes, automatic
signaling, and the automatic coupler increased safety. Sleeping cars and dining
cars increased passenger comfort and convenience (see Brake;
Locomotive).
In 1832
the horse-drawn tramcar on rails was adopted in New York City and in the
following decades became widely accepted as an inexpensive form of public urban
transportation. In the 1870s, steam-powered cable-drawn trams became popular.
Beginning in 1863 in London, England, steam-powered underground railways
(subways) were built (see Subway).
Electric
power was introduced to land transportation in the mid-1880s when electric
street railways began operating in the United States, Canada, and Europe. By
1900 they had replaced horsecars and cable cars as the chief form of urban
transportation. Electrified elevated or subway lines were built in several
European cities and in Boston, Chicago, and New York City (see Street
Railway) Electrification spread early in the 20th century to intercity railroad
lines but later the diesel-electric locomotive became dominant in the United
States (see Diesel Engine). By the 1950s, the automobile, bus, and
airplane had replaced the railroad train as the principal passenger carriers in
the United States. Trucks, waterways, and pipelines also competed increasingly
with railroads in freight hauling.
The Automobile and the Air Age
Some of
the first successful gasoline automobiles were developed in Germany by Karl
Benz and Gottlieb Daimler in the 1880s and in the United States by Charles E.
and J. Frank Duryea in 1893. Although some early automobiles were powered by
steam and electricity, the internal-combustion gasoline engine soon became the
favored form of motive power.
The
early farm-to-market roads in the countryside were rarely paved. By the 1890s,
however, some roads near the cities were being paved in response to the growing
popularity of bicycle riding. As the automobile came into common use in the
1900s, 1916 the Federal Aid Road Act provided for massive federal aid in
highway construction. Limited-access express highways originated in Europe in
the 1920s and 1930s with the building of the first Italian autostrada and
German autobahn. One of the first expressways in the United States was the
Pennsylvania Turnpike, opened in 1940. The Federal-Aid Highway Act of 1956 and
later amendments provided for a network of 42,500 miles of interstate
expressways to be completed by the mid-1970s.
The
first successful manned, engine-powered flight in a heavier-than-air craft was
achieved in 1903 at Kitty Hawk, N.C., by Orville and Wilbur Wright (see
Wright, Wilbur and Orville). Airplanes were used in combat during World War I.
Regular airmail routes began in the United States in 1918. During the 1920s and
1930s, mail planes commonly carried passengers. In the 1930s, scheduled flights
were begun over the Atlantic and Pacific oceans.
The
development during World War II of multiengine long-distance planes, aided by
reliable electronic navigation and weather forecasting, led to the rapid
advance of commercial air transportation. As a result, shipping lines rapidly
declined as major passenger carriers.
With the
introduction of jet power to commercial air service in the 1950s, speeds were
doubled and costs were greatly reduced. Propeller planes were largely replaced
on major transcontinental and trans-oceanic routes. The testing of supersonic
jet transports began in Europe and the United States in the late 1960s. During
that same time, jumbo jet aircraft, with capacities of nearly 500 passengers
each, were brought into service.
Transportation Problems
The
world's transportation facilities are elaborate but unevenly developed. Many
underindustrialized countries cannot afford the transportation services they need.
At the same time, some highly industrialized countries are oversupplied. In the
United States, for example, there are many miles of underused railroads, inland
waterways, and rural roads.
Transportation movements are hampered by economic barriers such as
tariffs and import and export quotas. Different railroad gauges on opposite
sides of an international boundary often require a costly transfer of freight
and passengers from one national railroad to another.
"Cargo preference" laws of some countries, restricting those
vessels eligible to take particular cargoes, may impede the most economic
operation of the world's shipping fleets. The desire of many countries to have
their own fleets of ships or to promote their own airlines may also divert traffic
from the most efficient carriers.
Many
countries regulate their transportation services so that the various modes are
complementary rather than competitive. In the United States, however,
government regulations vary widely from mode to mode and between those
transportation movements that cross state boundaries and those that do not. A
major step toward developing a unified national transportation policy was taken
in 1966 with the creation of the Cabinet-level Department of Transportation.
Laws,
customs, and labor agreements often require the employment of more persons than
are needed for efficient transportation service, especially as technological
advances such as container ships are introduced. But layoffs of unneeded
workers may result in large-scale unemployment and create severe social
problems. Similarly, the building of modern terminal facilities in certain
ports and cities may so concentrate traffic that other, bypassed ports and
cities face economic depression.
There
often are costly and inconvenient delays when people and goods are transferred
from one transportation mode to another. These delays include time spent by a
traveler at a corner bus stop, at an airplane loading gate or baggage counter,
or in the air while an airplane is waiting for clearance to land. They include
the time spent by general cargo ships while in port being loaded or
unloaded.
The
building of expressways and tollways, with their wide rights-of-way and complex
intersections, is very costly and has forced the relocation of hundreds of
thousands of homes and businesses, particularly in cities. Entire neighborhoods
have been destroyed. Many of the people displaced are from low-income areas in
the inner cities and are those least able to find new homes.
Traffic congestion in the United States has
been relieved somewhat as cities have decentralized and population and business
densities have decreased. But rush-hour traffic jams and lack of parking space,
especially in downtown areas, are still acute problems. Greater use of mass
transit services is a likely solution. Unless mass transit is heavily
subsidized, however, it can neither meet its costs from a fare structure that
would be low enough nor provide service that would be frequent enough to induce
people to leave their cars at home. Meanwhile, the decline of public
transportation services has hit hardest at the poor, the elderly, the young,
and the handicapped, who are least likely to have access to private
automobiles.
Transportation facilities and operation also affect the quality of the
environment. In an effort to reduce air pollution, laws in the United States
set limits on automobile emissions. Such antipollution measures, however, may
add to the expense of building and operating motor vehicles. Similarly, design
changes required by laws limiting the noise levels and air pollution of
aircraft may decrease the operating efficiency of the aircraft. The development
of supersonic aircraft, in particular, has been opposed because of the loud sonic
boom they create while in flight. Fear of pollution from massive oil leaks has
affected plans for new pipelines and the building and operation of
supertankers. Natural scenery may be marred and historical landmarks destroyed
by construction for highways, railroads, and airports.
Transportation facilities also present a safety hazard. The private
automobile, in particular, is one of the most dangerous modes of
transportation, though accident rates are slowly being reduced. Major accidents
on other transportation modes are relatively rare, though when they do occur,
as in the crash of an airliner or in the collision of passenger trains, the
loss of life may be great.
Advances in Transportation
Technological advances in transportation have included the development
of superspeed trains, such as Japan's "bullet train" of the 1960s and
France's TGV (Train de Grand Vitesse) of the 1970s and 1980s. These advances
gave engineers the inspiration to design such experimental railroad systems as
the magnetic levitation, or maglev, train, which by the early 1990s had only
short test systems set up in Germany and Japan. Improvements in power
generation and transmission and concern for the air and noise pollution caused
by diesel engines have prompted automobile makers to develop cars that will run
on alternative types of fuel. One result has been the prototype of an electric
car. (See also Automobile; Railroad.)
A
greater variety of ships, including submarine tankers and fast, multiple-hulled
surface ships, have been developed. Other new types of vessels that are
available include the hydrofoil, which travels on sea wings with its hull above
water, and the surface-effect ship, or hovercraft, which rides above the water
on a cushion of air.
The
widespread use of atomic power for ship propulsion is a major research goal.
STOL (short takeoff and landing), VTOL (vertical takeoff and landing), and
supersonic aircraft have been adopted. These new technologies have made
vehicles quieter. Passenger travel has improved in speed and comfort. Freight
transport costs less because larger vehicles are used and operating efficiency
has increased. The computer is used for record keeping, traffic control,
navigation, and other routine operations.
In the
more distant future, rocket transportation may become feasible, perhaps in
combination with orbiting satellites, enabling all points on Earth to be
connected in less than an hour's travel time. Underground gravity vacuum tubes
may permit freight and passengers to travel between stations thousands of miles
apart also in less than an hour.
Improvements may be expected in transportation management techniques.
Some forms of transportation now under private ownership, management, and
operation will increasingly depend on public financing or control, just as
urban mass transit now does. Some forms of transportation will be integrated
into multimodal organizations, both public and private, in order to move people
and goods with a minimum of cost, inconvenience, and delay.
The need
for modes of transportation will endure. Innovative communications systems,
however, have already made much travel unnecessary. Teleconferencing enables
people to hold meetings and see each other without having to travel. Computer
networking makes cooperative work possible, without the workers leaving home or
office (see Telecommunication).
Notable Events in Transportation History
By 7000 BC. Sledges used
for hauling. By 3000 BC. Domesticated
animals made beasts of burden; sails and wheeled vehicles developed. About AD 800-1100. Modern horse harness and
traces and nailed iron horseshoes developed. About
1200. Magnetic compass, probably invented in China,
adopted by European mariners. 1497-8. Vasco da Gama sails around Africa and establishes ocean trade route to
the Orient. 1519-22. First voyage
around the world, achieved by Ferdinand Magellan expedition. 1769. First steam road vehicle demonstrated by Nicolas
Cugnot in Paris. 1786. First successful steamboat demonstrated by John Fitch on Delaware River.
1804. First
successful railroad steam locomotive demonstrated by Richard Trevithick in
Wales. 1815. John Loudon
MacAdam builds macadam hard-surfaced roads in England. 1825. Stockton and Darlington Railway in England
becomes first common carrier to use locomotive power; Erie Canal opens in the
United States. 1850s. Age of clipper sailing ships. 1863. First subway line opens in London. 1869. Suez Canal opens; transcontinental railroad completed in the United
States. 1882-83. First
electrified railroads open in England and Ireland. 1880s. Benz and Daimler in Germany build first
successful automobiles with gasoline engines. 1903. Wright brothers make first airplane flight. 1914. Panama Canal opens. 1934. Diesel-powered passenger trains go into service
in the United States. 1952. First commercial jet air service, using British De Havilland Comet. 1970. First jumbo jet (Boeing 747) air service. (See
also Inventions table "Famous Inventions and Inventors" under
"Outstanding American Patents.")
This article was contributed by Harold M. Mayer,
Professor, Department of Geography, University of Wisconsin, Milwaukee, Wis.
FURTHER RESOURCES FOR TRANSPORTATION
Books for Children
Ancona, George.
Freighters: Cargo Ships and the People Who Work Them (Crowell Junior Books,
1985). Ardley, Neil. Air and
Flight (Watts, 1984). Barner, Bob. Elevator Escalator Book: A Transportation Fact Book (Doubleday, 1990). Brandt, Keith. Transportation (Troll,
1985). Brown, Richard. One
Hundred Words About Transportation (Harcourt, 1989). Gakken Company Limited Editors. Wheels and
Wings (Time-Life, 1988). Kerrod, Robin and others. Land (Silver Burdett, 1984). Kerrod, Robin
and others. Water (Silver Burdett, 1985). Little, Karen. Wings, Wheels and Water (EDC
Publishers, 1988). Williams, Brenda and
Williams, Brian. Wings, Wheels and Sails
(Random, 1991).
Books for Young Adults
Arnold, James. All
Drawn by Horses (David & Charles, 1985). Bulliet,
Richard. The Camel and the Wheel (Columbia Univ. Press,
1990). Bushell, C.J. Jane's
Urban Transport Systems (Jane's Information Corporation, 1990). Cain, Wilma. Story of Transportation
(Gateway Press, Inc., 1988). Evans, A.N. The Automobile (Lerner, 1985). Fargo, O.J. Western Transportation (Green Valley World, 1990). Graham, Ian. Transportation (Watts, 1990).
Lowe, Marcia. Alternatives
to the Automobile (Worldwatch Institute, 1990). Nentl, J.A. Big Rigs (Crestwood, 1983). Norris, Ann. On the Go (Lothrop, 1990). Papageorgiou, M.N. Concise Encyclopedia of
Traffic and Transportation Systems (Pergamon, 1991). Pollard, Michael. From Cycle to Spaceship: The
Story of Transportation (FOF, 1987). Radford, Don. Looking at Flight (David & Charles, 1984). Schulz, Marjorie. Transport: Careers for Today
(Watts, 1990). Stein, Barbara. Kids' World Almanac of Transportation: Rockets, Planes, Trains, Cars,
Boats, and Other Ways to Travel (Pharos Books, 1991). Wilkins, Frances. Transport and Travel from
Nineteen Thirty to the Nineteen Eighty's (David & Charles, 1985). (See
also bibliographies for Airplane; Automobile.) [1]
Hashim Ibrahim Filali
1. Comdata Observe (1-2), 1987H, 1988G - 1408H, 1409H
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[1]Excerpted
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1996, 1997 The Learning Company, Inc. All Rights Reserved.