Toll Roads and Free Roads/Part 1

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Section 13 of the Federal Aid Highway Act of 1938, approved June 8, 1938, provides that:

The Chief of the Bureau of Public Roads is hereby directed to investigate and make a report of his findings and recommend to the Congress not later than February 1, 1939, with respect to the feasibility of building, and cost of, superhighways not exceeding three in number, running in a general direction from the eastern to the western portion of the United States, and not exceeding three in number, running in a general direction from the northern to the southern portion of the United States, including the feasibility of a toll system on such roads.

In accordance with this direction an investigation has been made, reconnaissance locations of six highways answering the general description contained in the act have been projected, and the following report is submitted with recommendations concerning the feasibility of building, and cost of, the six superhighways selected, and the feasibility of a toll system on them.

The building of the six superhighways on the selected locations, to the high standards consistent with the indicated character of the proposed facilities, is entirely feasible from a physical standpoint. The approximate total length of the six superhighways, as projected, is 14,336 miles; and the estimated cost of constructing them to desirable standards is $2,899,800,000, which is at the average rate of $202,270 per mile.

The estimated cost per mile varies from a maximum of $1,158,400 for the section from Jersey City, N. J., to New Haven, Conn., to a minimum of $63,450 for the section from Rupert, Idaho, to Brigham, Utah. The variation results principally from differences in the estimated cost of right-of-way, the quantity of grading required, the number of access points, the number and character of bridges required to carry the highway over streams and over or under intersecting highways and railways, and the number of pavement lanes required for the accommodation of the estimated traffic.

A most conservative average estimated annual expenditure for theperiod 1945-60, required ‘for financing the construction, maintaining the property, and operating the facility, for the six superhighways in their entirety is $184,054,000 per year, which is at the average rate of $12,840 per mile per year, varying from a maximum of $66,560 per mile per year for the section from Jersey City, N. J., to New Haven, Conn., to a minimum of $5,700 per mile per year for the section from Rupert, Idaho, to Brigham, Utah. These estimates of the required annual expenditure are based on reasonable assumptions with respect to the probable service life of the various elements of the construction, probable maintenance and operating costs, and financing costs based upon a 30-year loan with annual interest at 2.6 percent and an additional 2.24 percent for retirement. ​

The total utilization of the six superhighways in their entirety, by the most optimistic estimate, averages for the period 1945–60, 4,544,000,000 vehicle-miles of toll-paying traffic per year, of which 3,635,000 000 is accumulated by passenger automobiles and 909,000,000 by motortrucks and busses. This utilization averages per day over the entire mileage approximately 12,450,000 vehicle-miles, of which 9,960,000 is by passenger automobiles and 2,490,000 by motortrucks and busses, implying an equivalent average traffic volume on each mile of the six superhighways of 699 passenger automobiles and 175 motortrucks and busses per day.

The most optimistic estimated average daily toll-paying traffic for the period varies from a maximum of 5,998 passenger automobiles and 1,500 motortrucks and busses for the section from Jersey City, N.J., to New Haven, Conn., to a minimum of 96 passenger automobiles and 24 motortrucks and busses for the section from Spokane, Wash., to Fargo, N. Dak.

The test of the feasibility of a direct toll system on the roads is based upon assumed average rates of 3.5 cents per vehicle-mile for motortrucks and busses and 1 cent per vehicle-mile for passenger cars. Since, on the average, it is estimated that the ratio of motortrucks and busses to passenger automobiles in the traffic will be approximately as 1 is to 4, the assumed toll rates for each type of vehicle result in an average rate of 1.5 cents per vehicle-mile for vehicles of all descriptions. It is believed that the usage rates assumed are reasonable for the purpose of testing the feasibility of a direct toll system on these roads. If higher rates were assumed, it would be necessary to reduce the estimated potential toll-paying traffic, probably by an amount that would result in a net reduction of the total yield. If lower rates were assumed, it is doubtful that the increased traffic would be sufficient to produce a greater total yield. In addition to these tolls, based on miles traveled, additional tolls were assumed for certain bridges where no alternate free facilities exist.

On the basis of the assumed rates of toll, the estimated total toll collection from the maximum amount of traffic that can reasonably be expected to use the six superhighways would be $84,037,000 for the year 1960 and for the period 1945-60 would be $1,154,236,000, or an average of $72,140,000 per year for the 16-year period, which is considerably less than the $184,054,000, estimated as the probable average total annual cost of the six superhighways. It is, therefore, concluded that a direct toll system on these six superhighways, in their entirety, would not be feasible as a means of recovering the entire cost of the facilities.

However, there are two sections on which it is estimated that the annual toll collections for the year 1960 will slightly exceed the annual cost. These sections extend from a point near Philadelphia, Pa., to a point near New Haven, Conn., a distance of 172 miles. On these two sections the estimated revenue of the year 1960 represents 109 and 104 percent, respectively, of the estimated cost for that year, or a combined average of 106 percent.

Other sections most nearly approaching these sections in point offeasibility of operation as toll facilities are those from the junction of the most westerly and most southerly routes in California to Whitewater, Calif., a distance of 91 miles; from Washington, D. C., Baltimore, Md., 39 miles; from a point near Boston, Mass., to Port​￦land, Maine, 134 miles; from Miami to Jacksonville, Fla., 326 miles; and from Baltimore, Md., to a point near Philadelphia, Pa., 76 miles. On these sections the anticipated revenues in 1960 would produce from 91.8 to 83.2 percent of the estimated cost for that year. On no other sections of the six projected toll roads do the estimates made result in a ratio of collections to costs as large as 80 percent. On 19 other sections of the six toll roads as projected the estimates made result in ratios of maximum collections to costs varying from 50 percent to less than 80 percent. These 19 sections, described by their approximate termini and total lengths and the corresponding ratios of maximum collections to costs in 1960, are as follows:

Approximate termini		Approximate length	Ratio of estimated annual toll collection in 1960 to annual cost
From—	To—
		Miles	Percent
Richmond, Va.	Washington, D.C.	108.0	76.1
San Ysidro, Calif.	Los Angeles, Calif.	124.4	76.0
Whitewater, Calif.	Indio, Calif.	32.7	73.3
Chicago, Ill.	Angola, Ind.	156.9	72.9
Brigham, Utah	Salt Lake City, Utah	52.3	69.9
Odessa, Tex.	Dallas, Tex.	337.9	67.1
Los Angeles, Calif.	San Fernando, Calif.	44.8	62.1
Buffalo, N.Y.	Albany, N.Y.	287.6	61.9
Whitewater, Calif.	Ludlow, Calif.	69.1	61.8
San Fernando, Calif.	Tracy, Calif.	[1]291.7	61.1
Minneapolis, Minn.	Chicago, Ill.	392.6	57.6
Sacramento, Calif.	Redding, Calif.	153.7	57.3
San Antonio, Tex.	Dallas, Tex.	250.7	53.2
Portland, Maine	Bangor, Maine	121.3	52.5
St. Joseph, Mo.	Springfield, Ill.	275.7	51.7
Springfield, Ill.	Indianapolis, Ind.	203.7	51.4
Carlisle, Pa.	Philadelphia, Pa.	94.8	51.0
Angola, Ind.	Detroit, Mich.	102.2	50.9
Tracy, Calif.	Sacramento, Calif.	69.1	50.5

On all other sections of the six superhighways as projected, the estimates made result in ratios of maximum collections to costs less than 50 percent.

The foregoing statement regarding collections and costs is based upon maximum estimates of traffic for sections of a complete system. If the sections were to be constructed as isolated units, the maximum collections and the ratios given would undoubtedly be materially reduced.

The comparisons made have reference to sections of substantial length extending between major controlling points on the highways. Doubtless, there would be shorter sections of the routes, perhaps some short sections of highway and some of the tunnels, but especially some of the bridges, which, if they were built and operated as local conveniences would accumulate a sufficient toll collection to cover all or a substantial part of their annual costs.

Each one of these indicated possibilities requires a thorough study in much more detail to determine the extent to which it might qualify as a sound, direct toll project.

On the basis of the investigation made and its results as briefly summarized above, a sound Federal policy for the construction of a system of transcontinental superhighways, traversing the entire extent of the United States from east to west and from north to south, ​cannot rest upon the expectation that the costs of constructing and operating such a system as a whole would be recoverable, in their entirety or in any large part from direct tolls collected from the users.

If, as an actual test of the feasibility of a limited mileage of toll roads, it is the desire of the Congress to make provision for the construction of a section of highway of substantial length upon which there is a reasonable prospect of the recovery of the costs through tolls, it is recommended that such provision be made applicable to a section of highway, properly located, and extending from an appropriate point near Washington, D. C., to an appropriate point near Boston, Mass.

The factual evidence presented in this report clearly indicates that the construction of direct toll highways cannot be relied upon as a sound solution of the problem of providing adequate facilities for the vitally necessary highway transportation of the United States, or to solve any considerable part of this problem.

While these conclusions are reached with reference to the limited question of financial feasibility of transcontinental superhighways and the possibility of toll collections to meet their cost, it is recognized that the report should be constructive rather than negative in character. Further, the Secretary of Agriculture is directed by the basic Federal highway legislation to submit reports or recommendations to the Congress on important highway matters. Conforming with this direction there is included in this report a discussion of the most important problems confronting both the Federal and State Governments and their subdivisions with respect to highway facilities.

From the discussion there emerges the general outline of what is in effect a master highway plan for the entire Nation. The carrying out of the plan in all its parts calls for appropriate action by the Federal and State Governments and all county and municipal subdivisions. As desirable joint contributions of the Federal and State Governments, the report lists several undertakings as follows:

1. The construction of a special, tentatively defined system of direct interregional highways, with all necessary connections through and around cities, designed to meet the requirements of the national defense in time of war and the needs of a growing peacetime traffic of longer range.
2. The modernization of the Federal-aid highway system.
3. The elimination of hazards at railroad grade crossings.
4. An improvement of secondary and feeder roads, properly inteerated with land-use programs.
5. The creation of a Federal Land Authority empowered to acquire, hold, sell, and lease lands needed for public purposes and to acquire and sell excess lands for the purpose of recoupment.

The report emphasizes the difficulties encountered in the acquisition of adequate rights-of-way; and, in view of the fundamental necessity of such rights-of-way, proposes definite measures by which the United States could aid in the acquisition of suitable rights-of-way and simultaneously contribute helpfully to the solution of other urgent problems, especially certain problems confronting the larger cities.

For the wealth of basic data, available in great detail for the purposes of the required investigation, especially data concerning the volume, character, and range of traffic, the condition of existing ​highways, and the need for new facilities, we are indebted to the State-wide highway planning surveys of 46 States. These surveys have been made possible by the availability of joint Federal and State funds under the authority of the provision contained in the Federal highway legislation authorizing expenditure from several Federal highway appropriations and matching State funds for physical and economic investigations required for the planning of future highway projects and programs.

The information furnished by these surveys made it possible within the limited time available to select the six superhighways described in this report with reasonable assurance that the selection made is probably the best that can be made, and to obtain the substantial concurrence, in the particular selection, of the responsible State highway authorities of all States. In fullness and in accuracy the facts supplied for consideration in the investigation are unmatched by the information elsewhere or to any person available. In the absence of these facts this report would necessarily be far less definite in its conclusions, and less dependable in its authority.

The facts derived from the highway planning surveys were especiallyuseful in disclosing the general characteristics of highway traffic, which have an important bearing upon the estimation of the amount of traffic that would probably use the proposed superhighways if they were constructed. Certain of these general characteristics that affect important decisions basic to the conclusions of this investigation will be described and illustrated by facts supplied mainly by the highway planning surveys of a number of States.

Some of the proposals for the construction of so-called transcontinental highways appear to be motivated by a belief that there exists an important volume of transcontinental travel; i. e., a through travel in motor vehicles between points in the Atlantic coast or far Eastern States and points in the Pacific coast or far Western States. No other explanation adequately accounts for the usual insistence upon a virtually absolute straightness of line between the continental termini.

Facts developed by the highway planning surveys definitely and conclusively show that there is no fully transcontinental travel, none even of semicontinental range, that could be accumulated in sufficient amount on any one or several highways traversing the breadth of the country, either to justify the construction, or to any considerable extent determine the character or location of such a highway or highways.

This conclusion is borne out by the planning survey facts presented graphically in plate 1. The greatest width of the tentacled central band shown in this graph represents to scale the average daily number of passenger cars traveling between points in the three Pacific-coast States and points in all States east of Idaho, Nevada, and Arizona, as actually counted at stations on all main-traveled east-west roads located approximately where such roads are crossed by the dashed line ​ curving through the States of Idaho, Nevada, and Arizona. The average daily number of all such vehicles is 2,532, all of which are bound to or from the three Pacific-coast States in the proportions indicated by the numbers appearing at the end of the scaled tentacles running to the three States.

Similarly the numbers of passenger cars bound to or from points in all States eastward of the three in which the counts were made are ​shown by the figures appearing at the end of the tentacles running to the respective States. The sum of the numbers of cars bound to or from points in States bordering on or near the Atlantic coast is 300. This figure represents substantially the total volume of average daily passenger-car traffic moving over all main-traveled highways between the east and west coasts. By a similar reckoning the average daily passenger-car traffic between the west-coast States and all points east of the Mississippi River over all main east-west highways will be found to be less than 800 vehicles. These vehicles could not be attracted to a single east-west route under any circumstances.

Plate 2 shows by a similar diagram the origins and destinations of motortrucks and busses observed at the same Idaho, Nevada, and Arizona points and indicates that the range of travel by such vehicles is much shorter than the passenger-car range represented in plate 1.

Similarly plates 3 and 4 show the origins and destinations of all passenger automobiles and motortrucks, respectively (other than vehicles of Florida registration), passing on an average day over the Florida State line. The traffic data represented are the results of counts made throughout the year 1937 on all main highways crossing the State line. Plate 3 shows that there is a well-developed movement between Florida and the Middle Atlantic and New England States that might conceivably be accumulated on one properly located free highway between the Potomac River and the Florida line. It shows also that there is another well-developed movement that might be accumulated on a single properly located free highway between Chicago and Florida.

It may be observed that the number of passenger cars of other than Florida registration shown, in plate 3, as bound to or from the three Pacific Coast States is 23. Cars of Florida registration, not included in the graphed totals, similarly bound to or from the three West Coast States add an average of 3 daily to this number, making a total of 26, as counted at the Florida line. It is interesting to compare this total with the 20 cars shown in plate 1 as having been found in Idaho, Nevada, and Arizona to be bound to or from Florida points. The close agreement of these figures, resulting from counts made independently at points separated by almost the width of the continent, is indicative of the high accuracy of the highway planning surveys.

Plate 5, based upon planning survey data from 11 representative States, shows the range in frequency distribution of the lengths of all one-way trips of passenger cars extending beyond the limits of cities. The States represented are Florida, Kansas, Louisiana, Minnesota, New Hampshire, Pennsylvania, South Dakota, Utah, Vermont, Washington, and Wisconsin. For each range of trip length, represented horizontally in miles, the graph shows by the height of the vertical bar to the bottom of the shaded areas the lowest percentage in which trips of that length are found in any of the 11 States. To the top of the shaded area the height of the bar for each range of trip length represents the highest percentage in which trips of that length were found in any of the 11 States. The vertical length of the shaded bands, represents to the percentage scale at the left the range between the maximum and minimum percentage in which trips of each range of length were found in the 11 States. ​

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It will be observed that trips less than 5 miles in length constitute the largest group in all States, ranging between 25.7 percent of all trips in one State and 43.8 percent in another, the percentages in the other nine States lying between these limits. Trips from 5 to 10 miles in length constitute the next largest group, and those from 10 to 20 miles long the third largest group.

The same data that are represented in plate 5 were used to compute the mean and median lengths of trip shown in table 1 for each of the 11 States. The table shows the mean and median trip lengths in miles, in each of the States, separately for cars owned in rural and urban places, in each of four population classes of urban places, and in the State as a whole. The mean of all trip lengths is shown to range from 11.7 miles to 18.7 miles; the median from 6.3 miles to 8.9 miles. The data contained in the table also indicate that trips of passenger cars owned in rural areas are generally shorter than trips of cars owned in cities; and also that the length of trip by city-owned cars increases generally with the population of the city in which they are owned. ​

State	Length of trips traveled by passenger cars registered in—
	Rural areas		Incorporated places having a population of—								Urban areas		All places
			2,501 to 10,000		10,001 to 25,000		25,001 to 100,000		More than 100,000
	Mean	Median	Mean	Median	Mean	Median	Mean	Median	Mean	Median	Mean	Median	Mean	Median
	Miles	Miles	Miles	Miles	Miles	Miles	Miles	Miles	Miles	Miles	Miles	Miles	Miles	Miles
Florida	11.4	6.3	20.2	9.9	29.7	14.6	30.5	14.9	22.8	10.0	23.5	11.3	16.1	8.1
Kansas	9.6	5.0	23.2	11.6	29.7	15.6	30.5	14.9	41.0	18.5	29.6	14.6	13.3	6.3
Louisiana	9.9	5.6	23.2	11.6	22.1	11.2	26.6	13.5	74.2	57.5	28.3	12.6	16.4	6.5
Minnesota	11.4	6.1	24.9	11.6	27.4	12.3			54.3	19.7	34.7	15.1	16.4	7.3
New Hampshire	13.0	8.3	13.7	8.6	20.1	11.1	27.2	16.7			18.5	9.9	15.5	8.9
Pennsylvania	9.8	5.9	13.3	7.1	15.1	8.4	19.7	9.4	30.8	13.6	17.5	8.5	13.5	7.1
South Dakota	15.9	8.6	25.2	8.3	34.2	10.0	60.9	26.9			30.9	9.9	18.7	8.7
Utah	10.8	4.8	18.0	8.2	38.3	15.4	38.8	18.9	52.9	24.0	34.2	14.3	17.4	6.6
Vermont	9.3	5.7	20.2	9.5	24.5	11.4					21.6	9.8	11.7	6.5
Washington	11.5	5.8	20.0	8.1	30.6	13.8	26.2	14.7	40.8	20.0	30.6	14.1	14.6	6.7
Wisconsin	10.9	6.4	24.5	12.6	27.9	13.9	33.2	8.4	48.2	25.8	31.2	15.9	15.9	7.9

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The data represented in plate 5 and table 1 have a double significance in relation to the estimation of potential traffic for the proposed highways with limited access.

1. They indicate that a considerable proportion of an existing traffic moving directly along the line of the proposed facility cannot be counted upon to use the facility unless the distances between access points are very short. Any given distance between access points must be considered as excluding from potential use of the facility all or practically all of the traffic found to be desirous of moving directly along the line of the facility for distances shorter than the access spacing.

2. The data also indicate that, as a rule, the amount of traffic that would be attracted by any of the proposed limited-access highways from other generally parallel routes will vary inversely with the distance separating the new highway from the parallel routes. Generally it must be assumed that for most of the traffic moving on a parallel route, diversion to the proposed highway would involve some indirection. The amount of such indirection that would overbalance other attractions of the new highway would vary with the length of the trip possible along the new highway before diverging to destination. As long trips are shown by plate 5 and table 1 to be a small percentage of all trips, and as only a traveler embarked upon a fairly long trip would accept any considerable lateral diversion from his direct course in order to enjoy superior highway facilities, it follows that the amount of traffic that can be counted as transferable to a limited-access highway from a generally parallel normal highway at a considerable distance must be quite small.

As indicated by table 1, residents of large cities, on the average, make longer trips than residents of small cities. Evidence that will be submitted hereafter (see pl. 8) shows that as a city is approached, the volume of traffic begins to increase at a greater distance from large cities than from small ones, which corroborates the stated rule. As New York is our largest city, the traffic diagram presented in plate 6 may be considered to represent the extreme condition in respect to average length of trip and ratio of numbers of long to short trips. Yet, even at New York, as plate 6 shows, an average daily traffic of 82,166 crossing the Hudson River by all facilities between the Battery and Tarrytown dwindles to less than a fifth of that amount within 20 miles. This dwindling occurs despite the existence of a ring of satellite cities which, by their local influence tend to keep the volume up.

It is of particular interest to note in plate 6 that only 3,100 of the 82,166 vehicles crossing the Hudson River are bound from or to points in States west and south more distant than New York, Pennsylvania, and New Jersey.

A survey recently made by the Bureau of Foreign and Domestic Commerce, United States Department of Commerce, shows that the majority of family passenger cars are owned by families of very moderate income. As indicated in the table below more than half of all family cars are owned by families that have an annual income of $1,500 or less. Less than 5 percent of all family cars are owned by families that have an annual income of more than $5,000. Less ​than a third are owned by families that have annual incomes in excess of $2,000.

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Ownership of family passenger cars by annual income groups
Annual income bracket	Percentage of family passenger cars owned by families in each income bracket	Percentage of family passenger cards owned by families with income less than the maximum of each income bracket
	Percent	Percent
Under $500	6.54	6.54
$500 to $1,000	20.55	27.09
$1,000 to $1,500	24.77	51,86
$1,500 to $2,000	18.08	69.93
$2,000 to $3,000	17.73	87.66
$3,000 to $5,000	8.02	95.68
Over $5,000	4.32	100.00

In estimating the probable volume of toll-paying traffic on the selected superhighways, it is necessary to give due consideration to these facts. Persons of low income who own and operate passenger automobiles are influenced in the uses they make of their cars to a greater extent by the immediate operating expense, such as gasoline and oil, than by the actual total costs, including tires, depreciation, and so forth. The cost of the gasoline consumed on a trip may amount to little more than a cent a mile. To the motorcar owner with an income of less than $1,500 a year, a toll of 1 cent per mile is likely to appear as a 100-percent increase in his cost of operation; and so viewed it is an additional cost that he is not likely to pay.

Several considerations influenced the location of the routes chosen for the superhighways to be investigated. The first requirement was that the routes selected should conform substantially to the description specified in the act, i. e., that there should be not more than three running in a general direction from the eastern to the western portion of the United States, and not more than three running in a general direction from the northern to the southern portion of the United States.

The major routes selected conform exactly to this description. Two of the north-south roads run from the Canadian line to the Mexican border, the third runs from Maine to Florida; and all three of the east–west routes run substantially from the Atlantic to the Pacific coasts.

In addition to the three major routes in each general direction, the investigation has also covered three diagonal branches from the central east-west route. One of these was included to give direct connection with the National Capital at Washington; the other two, branching northwest and southwest from points near Salt Lake City, were included because they permit the central route to give reasonably direct connection to the northern and southern Pacific coast sections during seasons when, for climatic reasons, the central route may be preferred by travelers to the northern or southern route. ​

The second consideration was that the routes chosen should be reasonably distributed geographically and in relation to the distribution of the population of the country; that, consistent with other requirements, they should pass through as many States as possible. Accordingly the northern east–west route clings to the northern tier of States from New England to Washington. The southern east–west route traverses the southern tier. The central east–west route passes almost exactly through the center of the country. The eastern and western north–south routes approximately parallel the coasts, and the central north-south route, though for valid reasons it departs somewhat from a central position geographically, intersects the central east-west route close to the center of population. The 6 major routes and 3 diagonal branches traverse for some distance 41 of the 48 States.

A third consideration in the selection of the routes was that they should accord reasonably with recognized popular routes of travel. For their movements across the country, whether the distances were long or short, motorists have previously had a considerable choice of routes, between which, in the beginning at least, there was little advantage of improvement. By their choice, as reflected in the relative density of present traffic on various highways, they have established certain preferred routes, which stand out quite clearly as the widest bands on a traffic map of the country. (See pl. 8.) In the selection of routes for the superhighways close conformity to these preferred lines of travel was an important objective. This consideration weighed heavily in the decision to include the two western branches of the central route among those to be investigated. These branches, one coinciding closely with the historic Dee Trail and the other with the pioneer movement of the Mormons into southern Utah, both bear the stamp of approval of the early pathfinders and a long succession of their followers.

This consideration also strongly influenced the southwestward slant of the central north-south route, which follows closely a line selected by many travelers for winter use in driving from the populous Northeast to the Pacific coast.

A further consideration was that the several routes should have important continental termini and should run as directly between these ultimate objectives as might prove to be consistent with the connection of important intermediate points and the development of traffic. It is believed that the routes selected fulfill these requirements.

The eastern north-south route joins the New England and Florida playgrounds, and passes within a reasonable distance of all the coastal cities. The central north-south route has its termini at the international bridges at Port Huron, Mich., and Laredo, Tex. At the south it is the logical connection with the Inter-American Highway. For 157 miles in the north it joins with the northern east-west route, ​and so doing saves $42,000,000 in the construction cost at the expense of 4 or 5 miles of extra distance for traffic moving between Chicago and Detroit. The western north–south route takes a protected valley course for the most part from border to border, within easy reach of all the coastal cities.

The northern east–west route joins the hub of New England with Seattle, northernmost of west coast cities, and in its intermediate course first serves Cleveland, Chicago, and the other Great Lakes cities and the Twin Cities of Minnesota and then follows almost an air line through North Dakota and Montana.

The central east–west route begins at a junction with the Atlantic coast route, which can be reached conveniently from New York and Philadelphia, and thence follows a very direct line to San Francisco. The line first chosen for this route diverged from the final line southwestward at a point near Indianapolis, to pass close to St. Louis and Kansas City, and then followed the Missouri River northward to a point between Lincoln and Omaha, Nebr., where it entered the valley of the Platte River and thence followed the line of the historic Oregon Trail and Overland Route into Wyoming. The change to the present direct route between points near Indianapolis and Denver follows the consensus of advice received from the responsible State highway officials of all the States affected.

The southern east–west route begins near Charleston, S. C., and runs very directly through the southern tier of States to Los Angeles. It crosses the eastern north–south route at a point that nicely compromises the claims of the southern coastal cities, which there have convenient access to it. It passes near Atlanta, Birmingham, Montgomery, and Jackson, and heads directly toward Dallas and Fort Worth in Texas, whence, avoiding the Big Bend of the Rio Grande River, it passes just north of El Paso and on to its western terminus.

Finally, and subject to a proper balance of all previous considerations, it was the intention so to locate the several routes, as to achieve an optimum condition in respect to toll collections. The results in this respect are set forth in great detail in subsequent pages. It is sufficient at this point to state that it is believed that no substantial change in the chosen lines, reasonably consistent with the several considerations previously discussed, would improve upon the potential earning power of the lines selected.

In January 1938 the first traffic map of the United States was compiled by the Bureau of Public Roads from the latest data then obtainable from State traffic flow charts and available tabulations, most of which had been prepared in connection with the highway planning surveys. In January 1939 this map was revised to conform with more complete and detailed information, and the revised map is reproduced in plate 7.

The traffic flow represented is that of the year 1937 on routes of the United States highway system and other main-traveled highways. Bands of varying width, centered upon the approximate lines of the various highways, indicate by their scaled width at all points the vol​ume of passenger-car traffic using the highways at such points. The over-all width of the open bands represents the total passenger-car traffic, and the width of the narrower black bands the volume of that part of the traffic, described as “foreign,” consisting of passenger cars registered in all States other than the State in which they were observed.

As it was the purpose of the map to show only the passenger-car movements of longer range, local increases of total traffic caused by short trips in and out of cities and local increases of “foreign” traffic caused by short trips over State lines are not shown. Shorn of these increases, the band widths, as shown, represent approximately the volume of all passenger-car traffic flowing, exclusive of the numerous extremely local movements mentioned. Thus, even the open bands represent traffic of relatively long range, and the black bands represent generally movements that are still longer and at least of interstate extent.

Examining the map, some of these existing routes are seen to stand out above others as relatively important in respect to both their total traffic and the volume of “foreign” traffic they serve; and it was by such a visual comparison, qualified by the various general considerations previously described, that certain routes were tentatively chosen as representing the approximate lines of the six superhighways to be investigated.

The routes thus chosen are indicated by the darker traffic bands on plate 8. On this map the width of the shaded bands represents the same total traffic that is indicated on plate 7 by the width of the open bands; and the generally superior importance of the selected routes is borne out by the generally greater width of the darker bands.

Tentative locations for three east-west and three north-south superhighways approximately paralleling the existing routes indicated in plate 8 were defined by the Bureau and submitted for consideration and criticism to the highway departments of each of the 48 States. In accordance with the comments received, several adjustments were made, and a final decision was reached, with the concurrence of all States except South Dakota, upon the routes as shown and numbered on plate 9.^[1]

For purposes of designation, the three north–south routes were numbered from the easternmost to the westernmost 1, 3, and 5; and the three east–west routes were numbered from the northernmost to the southernmost 2, 4, and 6. The diagonal route running northwestward from Salt Lake City was designated 4N (north) and the diagonal running southwestward from the same city, 4S (south). The branch of route 4 added to connect with Washington, D. C., was designated 4A; and because route 3 is broken where its location coincides with that of route 2, east of Chicago, the section extending northeastward from route 2 was designated as route 3 Mich.

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In estimating the traffic that would probably use the selected routes all available information was carefully considered. The 1937 volumes of total and “foreign” passenger-car traffic on existing highways approximately parallel to the routes chosen, were known, as indicated by plate 7. General information concerning the relative ​percentages of passenger-car trips of various lengths in a normal highway movement, and concerning the percentages of all car owners having annual incomes of various orders, was also available as previously set forth in this report. And finally, the Bureau was also in possession of information concerning the volume of motortruck and bus traffic on various main highways and in various sections, which, though not so complete as the available passenger-car traffic data, was still sufficient for the purpose.

As a first step in estimating their probable traffic, the selected highways were assumed to be free highways of limited access, but with access points located as they probably would be in a toll system. Guided by this assumption, an estimate was made, for each section of the proposed routes, of the amount of traffic the new facility would probably attract from existing free highways located at various distances from it and approximately parallel to it.

The first consequence of the assumed condition was to exclude as potential traffic for the limited-access route that part of the movement on any parallel free highway composed of trips shorter than the assumed distance between access points. Since vehicles making such shorter trips would be forced by the limitation of access to travel further than necessary between their origins and destinations they would not use the new facility even if it were immediately adjacent to the existing free route.

In estimating the percentage of the known volumes of traffic on parallel free routes that, for this reason, would be excluded from the limited access routes, the facts concerning the distribution of trip lengths developed by the highway planning surveys of 11 States, provided helpful guidance. These facts are presented in plate 5 and corresponding vehicle-mile data are generalized in the single curve on plate 10. Referring to this curve it will be seen that if the interval ​

al between any two access points were 10 miles, at least 20 percent of the vehicle-mileage of traffic moving on an immediately adjacent free highway would have to be counted as unavailable for the limited-access route. If the distance between access points were 20 miles the excluded portion of the free highway vehicle-mileage would be increased to 40 percent.

That part of the traffic on parallel free highways not excluded from the limited-access route by the distance between accesses, might be attracted by the superior facility of the new route. Whether it would be or not would depend upon the distance it would be necessary to travel and the character of service available over existing roads from the point of origin to the new route and from the route to the point of destination, and also upon the whole extra distance entailed by use of the new facility. While the superior design of the new route, if operated as a free facility, would doubtless be considered by potential users as outweighing some extra distance, there would obviously be no advantage in its use if to reach it at one end of a trip and continue from it at the other it were necessary to travel as far over existing cross roads as the distance via a comparable parallel road directly from origin to destination. This consideration would impose a definite limit upon the lateral distance over which the superior facility of the new route would attract traffic from existing parallel roads. Of the traffic moving over a closely parallel existing road it would definitely exclude only the traffic of comparatively short trip length; of the traffic moving over more distant parallel roads it would definitely exclude larger parts as the separating distance increased.

Beyond these definite limits use of the new facility would involve greater travel over existing roads than would be necessary for direct travel by a comparable existing road from origin to destination. Under this condition use of the new facility would be inspired only by a quickly satisfied curiosity. Within the limits mentioned, use of the new facility would not require greater travel over existing roads than would be necessary to travel entirely over such roads from origin to destination but would increase the total travel distance. Under this condition, the decision whether or not to use the new road would depend upon an individual appraisal, by potential users, of the competing attractions of short distance on the one hand and a better facility for part of a longer distance on the other. The number of potential users who, under this condition, would actually choose to use the new facility would increase with reduction in the amount of extra distance involved in such use in relation to the total length of the possible trip over the new facility. Traffic of long range moving in the general direction of the new facility would obviously be attracted to it from a greater lateral distance than any short-ranging traffic. For this reason, the greatest potential usage of the new facilities would naturally be expected to be generated by the existing-road traffic indicated on plate 7 as “foreign.”

In estimating the traffic that would probably use the proposed new facilities if they were operated as free limited-access roads, these several considerations were kept in mind in a section-by-section appraisal of the probabilities with respect to the entire mileage in ​volved. The relation of each section of the routes with respect to all possibly competing highways was carefully studied and a judgment was formed as to the part of the known traffic using such competing roads that could be attracted to the new facility. Mathematical exactness in such judgments was an impossibility; and to avoid underestimation there was studied effort to maintain a liberal bias. The resulting estimates, therefore, are believed to represent the maximum traffic that could reasonably be expected to make use of the proposed facilities if operated as free limited-access routes.

Having considered every section of the proposed routes from this point of view, the next step was to convert the estimates made upon the assumption of free use into estimates of the probable toll-paying traffic.

A consideration of the ability of people to pay tolls, as indicated by the distribution of automobile owners by income groups, and further consideration of actual fees which would be charged for specific trips over various sections of the routes, led to the conclusion that not more than about one-third of the vehicles that might use a typical free road of limited access could be regarded as potential traffic for the same road operated as a toll facility.^[1]

The general estimate of one-third as the proportion of users of a free limited-access facility who would use a similar toll facility and estimates of toll-road traffic based thereon were submitted to responsible highway authorities of all the States with a request that they comment upon the reasonableness of the assumptions and the resultant traffic estimates. In arriving at the final estimates of traffic likely to use the proposed routes, if operated as toll facilities, comments received from the State officials were considered together with a firsthand review of the particular attractiveness of each section of the routes and of the ability of the potential users in each section of the country to pay a toll of 1 cent per mile for passenger cars.

On the basis of this further study various factors, ranging from 0.167 to 0.40, were decided upon for application to the estimated free-facility traffic to convert it to an estimate of traffic on the toll facility. In densely populated areas, where highway congestion in considerable degree has already been experienced and where there are relatively large numbers of potential users who are able to pay tolls, factors as high as 0.40 were used. This value was used, for example, on the section of route 1 between New York City and central Connecticut. In sparsely populated areas, where thus far little or no congestion has been experienced and existing modern highways afford excellent service, factors in the lower range were used. For example, a factor of 0.20 was used for the section of route 4 between Evanston, Wyo., and Rock Springs, Wyo.

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The estimates thus made of the traffic that would have used the various sections of the selected routes, if operated as toll facilities in ​1937, total, for the entire system, 5,823,745 vehicle-miles per day. In table 2, this figure is shown as the sum of the average daily vehicle-mileage on each of 75 sections into which the entire system is divided. The table shows the length of each section and the estimated average number of vehicles that would have used it, in addition to the utilization expressed in vehicle-miles. The sections are arranged in the descending order of estimated average daily traffic and the sectional lengths and estimated vehicle-mileages are progressively accumulated in that order. For each accumulation of length and vehicle-mileage a corresponding average daily volume of traffic is shown in the last column of the table. ​

Section					Accumulated length	Average daily number of vehicles	Average daily number of vehicle- miles	Accumulated vehicle- miles	Average daily number of vehicles for accumulated length
Number	Route	From–	To—	Length
				Miles	Miles
1	1	Jersey City, N.J.	New Haven, Conn.	65.6	65.6	3,508	230,125	230,125	3,508
2	1	Junction Route 4, Pa.	Jersey City, N.J.	106.86	172.4	2,651	283,127	513,252	2,977
3	5	Junction Route 6, Calif.	San Fernando, Calif.	44.8	217.2	1,734	77,683	590.935	2,721
4	1	Washington, D.C.	Baltimore, Md.	39.3	256.5	1,602	62,959	653,894	2,549
5	1	Junction Route 2, Mass.	Portland, Maine	133.9	390.4	1,348	180,497	834,391	2,137
6	6	Junction Route 5, Calif.	Whitewater, Calif.	91.0	481.4	1,310	119,210	953,601	1,981
7	1	Baltimore, Md.	Junction Route 4, Pa.	76.2	557.6	1,272	96,926	1,050,527	1,884
8	5	San Ysidro, Calif.	Junction Route 6, Calif.	124.4	682.0	1,140	141,816	1,192,543	1,748
9	2	Junction Route 3, Ill.	Junction Route 3, Mich., Ind.	156.9	838.9	1,119	175,571	1,367,914	1,631
10	1	New Haven, Conn.	Junction Route 2, Mass.	99.8	938.7	1,048	104,590	1,472,504	1,569
11	2	Buffalo, N.Y.	Albany, N.Y.	287.6	1,226.3	1,020	293,352	1,765,856	1,440
12	1	Richmond, Va.	Washington, D.C.	108.3	1,334.6	946	102,452	1,868,308	1,400
13	4	Carlisle, Pa.	Junction Route 1, Pa.	94.8	1,429.4	852	80,770	1,949,850	1,364
14	1	Salem, Oreg.	Portland, Oreg.	56.9	1,486.3	822	46,772	1,995,850	1,343
15	3 Michigan	Junction Route 2, Ind.	Detroit, Mich.	102.2	1,588.5	805	82,271	2,078,121	1,308
16	4	Oakland, Calif.	Auburn, Calif.	110.0	1,698.5	750	82,500	2,160,621	1,272
17	2	Albany, N.Y.	Junction Route 1, Mass.	147.2	1,845.7	748	110,106	2,270,727	1,230
18	2	Cleveland, Ohio	Buffalo, N.Y.	220.7	2,066.4	744	164,201	2,434,928	1,178
19	4	Pittsburgh, Pa.	Carlisle, Pa.	166.6	2,233.0	715	119,199	2,554,047	1,144
20	2	Perrysburg, Ohio	Cleveland, Ohio	79.3	2,312.3	676	53,607	2,607,654	1,128
21	5	San Fernando, Calif.	Tracy, Calif.	[1]291.7	2,604.0	658	164,106	2,771,759	1,082
22	5	Portland, Oreg.	Junction Route 2, Wash.	146.7	2,750.7	654	95,942	2,867,701	1,059
23	5	Tracy, Calif.	Junction Route 4, Calif.	69.1	2,819.8	625	43,188	2,910,889	1,048
24	6	Whitewater, Calif.	Indio, Calif.	32.7	2,852.5	800	19,620	2,930,509	1,043
25	5	Junction Route 2, Wash.	Canadian Boundary	124.7	2,977.2	567	70,705	3,001,214	1,022
26	2	Minneapolis, Minn.	Junction Route 3, Ill.	392.6	3,369.8	550	215,930	3,217,144	967
27	6	Junction Route 3, Tex.	Shreveport, La.	190.4	3,560.2	548	104,339	3,321,483	944
28	4	Indianapolis, Ind.	Columbus, Ohio	156.6	3,716.8	511	80,023	3,401,506	926
29	3 Michigan	Detroit, Mich.	Port Huron, Mich.	72.5	3,789.3	510	36,975	3,438,481	918
30	1	Portland, Maine	Bangor, Maine	121.3	3,910.6	491	59,558	3,498,039	904
31	6	Odessa, Tex.	Junction Route 3, Tex.	337.9	4,248.5	484	163,544	3,661,583	870
32	4	Columbus, Ohio	Pittsburgh, Pa.	195.6	4,443.5	475	92,625	3,754,208	853
33	3	Junction Route 4, Ill.	Junction Route 2, Ill.	155.5	4,599.0	468	72,774	3,826,982	840
34	1	Miami, Fla.	Jacksonville, Fla.	326.5	4,925.5	446	146,619	3,972,601	814
35	4 North	Brigham, Utah	Salt Lake City, Utah	52.3	4,977.8	412	21,548	3,994,149	809
36	3	San Antonio, Tex.	Junction Route 6, Tex.	250.7	5,228.5	398	99,779	4,093,928	789 ​
37	4	Junction Route 3, Ill.	Indianapolis, Ind.	203.7	5,432.2	396	80,665	4,174,593	771
38	3	St. Louis, Mo.	Junction Route 4, Ill.	88.8	5,521.1	360	31,968	4,206,561	768
39	5	Roseburg, Oreg.	Salem, Oreg.	133.3	5,654.3	354	47,188	4,253,749	758
40	2	Junction Route 3—Mich., Ind.	Perrysburg, Ohio	69.9	5,724.2	352	24,605	4,278,354	753
41	4	St. Joseph, Mo.	Junction Route 3, Ill.	275.7	5,999.9	331	91,257	4,369,611	733
42	4 South	Junction Route 6, Calif.	Ludlow, Calif.	69.1	6,069.0	320	22,112	4,391,723	729
43	3	Springfield, Mo.	St. Louis, Mo.	165.2	6,387.9	316	52,203	4,443,926	718
44	5	Junction Route 4, Calif.	Redding, Calif.	153.7	6,387.9	313	48,108	4,492,034	708
45	2	Fargo, N. Dak.	Minneapolis, Minn.	219.1	6,607.0	301	65,949	4,557,983	694
46	4	Auburn, Calif.	Reno, Nev.	106.5	6,713.5	300	31,950	4,589,933	688
47	5	Ashland, Oreg.	Roseburg, Oreg.	122.9	6,836.4	298	36,624	4,626,557	681
48	3	Tulsa, Okla.	Springfield, Mo.	171.3	7,007.7	296	50,705	4,677,262	671
49	1	Jacksonville, Fla.	Junction Route 6, S.C.	219.3	7,227.0	288	63,158	4,740,420	660
50	1	Junction Route 6, S.C.	Richmond, Va.	362.6	7,589.6	279	101,165	4,841,585	641
51	4-A	Junction Route 4, Pa.	Junction Route 1, Md.	88.5	7,678.1	271	24,249	4,865,831	637
52	4 North	Portland, Oreg.	Boardman, Oreg.	[2]163.4	7,841.5	272	30,328	4,896,162	632
53	2	Seattle, Wash.	Ellensburg, Wash.	90.0	7,931.5	270	24,300	4,920,462	628
54	4	Greeley, Colo.	St. Joseph, Mo.	529.7	8,461.2	258	136,663	5,057,125	604
55	3	Junction Route 6, Tex.	Tulsa, Okla.	270.5	8,731.7	252	68,166	5,125,291	593
56	6	El Paso, Tex.	Odessa, Tex.	245.2	8,976.9	248	60,810	5,186,101	584
57	4 North	Boise, Idaho	Rupert, Idaho	182.2	9,159.1	235	42,817	5,228,918	577
58	4 South	Ludlow, Calif.	Las Vegas, Nev.	117.0	9,276.1	210	24,570	5,253,488	572
59	5	Redding, Calif.	Ashland, Oreg.	138.2	9,414.3	204	28,193	5,281,681	567
60	6	Shreveport, La.	Vicksburg, Miss.	168.8	9,583.1	195	32,916	5,314,597	560
61	6	Phoenix, Ariz.	El Paso, Tex.	391.1	9,974.2	192	75,091	5,380,688	546
62	6	Indio, Calif.	Phoenix, Ariz.	254.0	10,228.2	165	41,910	5,431,598	536
63	4 North	Boardman, Oreg.	Boise, Idaho	253.1	10,481.3	158	39,990	5,471,588	527
64	6	Birmingham, Ala.	Atlanta, Ga.	141.2	10,622.5	155	21,886	5,493,474	522
65	4 South	Las Vegas, Nev.	Salt Lake City, Utah	407.5	11,030.0	140	57,050	5,550,524	508
66	4	Salt Lake City, Utah	Greeley, Colo.	463.3	11,493.3	136	63,009	5,613,533	492
67	6	Vicksburg, Miss.	Birmingham, Ala.	270.5	11,763.8	121	32,730	5,646,263	484
68	1	Bangor, Maine	Canadian Boundary	196.6	11,960.4	119	23,395	5,669,658	478
69	3	Mexican Boundary	San Antonio, Tex.	156.2	12,116.6	96	14,995	5,684,653	473
70	6	Augusta, Ga.	Charleston, S.C.	116.3	12,232.9	91	10,583	5,695,236	469
71	4 North	Rupert, Idaho	Brigham, Utah	119.7	12,352.6	80	9,576	5,704,812	465
72	6	Atlanta, Ga.	Augusta, Ga.	153.2	12,505.8	78	11,950	5,716,762	406
73	4	Reno, Nev.	Salt Lake City, Utah	514.9	13,020.7	63	32,439	5,749,201	445
74	2	Ellensburg, Wash.	Spokane, Wash.	145.9	13,166.6	62	9,046	5,758,247	440
75	2	Spokane, Wash.	Fargo, N. Dak.	1,169.6	14,336.2	56	65,498	5,823,745	409
		Total		[3]14,336.2			5,823,745

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The section of the routes selected on which it is estimated there would have been the largest volume of toll-paying traffic in 1937 is the 65.6 miles from Jersey City, N. J., to New Haven, Conn. It is estimated that 3,508 vehicles would have used that section daily, resulting in a total utilization of 230,125 vehicle-miles.

The lightest 1937 traffic estimated for any section is the 56 daily vehicles corresponding to the 1,169.6-mile section from Spokane, Wash., to Fargo, N. Dak. Although 18 times as long as the Jersey City–New Haven section the vehicle-mileage generated is barely more than one-fourth of the utilization of the most heavily traveled section.

The estimated 1937 tfaffic on all sections of the selected routes, operated as a toll system, is shown on the flow chart, plate 11. Estimates for the section between Richmond, Va. and Boston, Mass. are shown in greater detail in plate 12.

The 10 most heavily traveled sections of the selected routes, as listed in table 2, have an aggregate length of 938.7 miles. The location of these sections is shown in the map, plate 13. It will be noted that these most heavily traveled sections form a continuous route from Washington, D. C., to Portland, Maine, and shorter stretches east of Chicago, Ill., and in the vicinity of Los Angeles, Calif.

Adding eight more sections, as listed in table 2, raises the aggregate mileage to 2,066.4 miles; and, with the exception of a section between Cleveland, Ohio, and the Ohio–Indiana line, completes a route from Boston, Mass., to Chicago, Ill., with a spur to Detroit, Mich. In the West, sections are added near Oakland, Calif., and between Portland and Salem, Oreg., as shown in plate 14.

If, in a similar manner, sections are added successively in groups, in the order of their estimated traffic volume, the locations of the ​accumulating sections are shown on plates 15 to 21, inclusive. Comparison of this entire series of plates gives a good idea of the relative traffic importance of the selected routes in various sections of the country. If the roads were built in the order of their traffic importance as toll facilities they would be built in the order of progression indicated by this series of maps.

​

In table 3 the traffic that would probably have used the selected routes in 1937, operated both as free and toll facilities of limited access, is compared with the actual traffic moving in that year over existing highways closely paralleling the selected routes, and with the traffic on these highways with and without their urban connections. In one-half of the table the comparison is made in terms of ​average daily vehicle-mileage, in the other half it is made in terms of average daily traffic volume.

It will be noted that the total vehicle-mileage estimated for the toll facility on all routes is about one-seventh of the vehicle-mileage ​served by all sections of the parallel existing highways, about a fifth of the vehicle-mileage on rural sections of the existing highways, and one-fourth or a little more of the vehicle-mileage estimated for a limited access route operated as a free facility.

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Route	Length of sections of—			Average daily vehicle-miles in 1937				Average daily traffic density in 1937
				On parallel existing highway		On selected limited- access route		On parallel existing highway		On selected limited- access route
	Existing highways, urban and rural	Existing highways, rural only	Limited- access highways	Urban and rural sections[1]	Rural sections only	Operated as free facility	Operated as toll facility	Urban and rural sections[1]	Rural sections only	Operated as free facility	Operated as toll facility
	Miles	Miles	Miles
1	2,066.0	1,624.7	1,856.2	9,342,414	5,683,349	5,208,578	1,453,578	4,522	3,498	2,806	783
2	3,153.5	2,717.3	2,978.8	6,335,003	4,725,059	4,536,926	1,199,604	2,009	1,739	1,523	403
3	1,493.1	1,300.3	1,258.2	3,772,750	3,156,505	1,428,139	390,590	2,527	2,428	1,135	310
3 Michigan	226.6	166.8	174.7	989,940	608,267	427,772	119,220	4,369	3,647	2,449	682
4	3,150.7	2,800.6	2,816.8	6,490,525	5,107,920	3,387,126	891,455	2,030	1,824	1,202	316
4-A	100.3	85.6	88.5	457,565	321,614	87,261	24,283	4,562	3,757	986	274
4 South	675.9	616.8	593.6	776,033	631,113	408,172	103,626	1,148	1,023	688	175
4 North	863.7	771.4	[2]770.7	1,143,524	894,599	608,314	147,336	1,324	1,160	789	191
5	1,453.9	1,223.2	[3]1,406.4	5,771,231	4,377,166	3,079,054	799,614	3,696	3,578	2,189	569
6	2,623.2	2,327.1	2,392.3	5,392,157	4,060,813	2,912,549	694,600	2,056	1,745	1,217	290
Total	15,806.9	13,633.8	[4]14,336.2	40,471,142	29,566,405	22,083,891	5,823,745	2,560	2,169	1,540	406

​

The traffic shown for the existing highways is that which actually used them in 1937. Had these roads been thoroughly modernized throughout, it is conservatively estimated that their traffic would have been from 15 to 30 percent greater than it actually was.

Based upon estimates of probable future changes in population, in the number of motor vehicles per capita, in motor fuel consumed per vehicle, and upon an estimate of the increase in miles traveled per gallon of fuel by the average vehicle as a result of improvements in motor vehicles and changes in driving habits, plate 22 shows a predicted trend in the vehicle-mileage of travel on all rural roads.

It is assumed that the rate of increase in vehicle-miles of travel onmain highways will exceed the average rate of increase on all rural roads because: (1) A faster rate of development of abutting properties is anticipated for main roads than for local roads; and (2) the average length and number of long trips (50 miles or more) is expected to increase at a faster rate than the average length and number of shorter trips. The allowance for each of these factors depends, of course, upon the specific section of highway considered.

In considering an allowance for the first of these factors for the selected system composed of three east-west and three north-south routes, it must be remembered that access is assumed to be denied to all abutting property owners except at designated poimts where approach facilities are provided. This condition restricts development of abutting property to areas close to access points. Where the selected route is located in such manner that it provides an attractive connection between such areas and nearby marketing or metropolitan areas, a very fast rate of development may be anticipated. However, ​to keep pace with the average rate of development of abutting property on all roads having unrestricted access, the fast rate of development in favorably located areas close to access points on the selected routes must be great enough to compensate for the lack of traffic contributing development along the balance of the system. It seems doubtful that it would be great enough even were the selected routes operated as free facilities, but in the absence of a definite means of determining the extent to which these items balance, it is assumed that the average rate of development on such a system operated as a free facility would keep pace with the average rate of development on all routes. For a system of toll highways, a slower rate of development must be assumed.

In considering the probable faster rate of increase in the average length and number of long trips, it becomes apparent again that the allowance made for the selected routes operated as toll facilities should be different from that which would be made if they were operated as free facilities. This difference is caused by the fact that the more money people spend for tolls, the less they have left to spend for operation of their vehicles. However, this rate of increase should be greater for the selected routes, operated on either a free or toll basis, than the rate of increase for main highways, because the long trips, which tend to increase in number faster than short ones, form a larger percentage of the traffic on limited-access roads than on normal main highways.

A thorough consideration of all of these points indicates that it would be reasonable to assume that the trend of travel on the selected routes, operated as toll facilities, would increase approximately one-third faster than travel on all roads.

Before expanding the maximum estimates of 1937 traffic by application of these trends, one further factor must be considered. That factor is generated traffic which, for this purpose, may be defined as the traffic which results from a new desire for travel on the part of certain people who would not care to perform the same travel in the absence of the improved facilities. This traffic would appear during the first years of operation of the new facilities, after which time its entire effect upon the rate of increase may be assumed to be eliminated. It is estimated that 3 years after completion of a route this traffic would increase the total diverted traffic by 20 percent, if it were operated as a toll facility.

Using these relationships, the multiplying factors derived for converting the maximum estimates of 1937 traffic on the selected routes, operated as toll facilities, were 2.5 for 1960 traffic and 34.2 for the traffic of the entire period from 1944 to 1960, assuming that one-half of the system could be placed in operation January 1, 1944, and the remaining half could be placed in operation January 1, 1946.

One of the elements of highway design most affected by the volume of traffic to be served is the width of the pavement or the number of lanes provided.

In determining the number of traffic lanes required for toll roads, it is necessary to base the determination upon factors that are not ​present in the same degree in dealing with free public highways. Highway departments have built the existing roads with definitely limited funds and it has been their problem to distribute these funds over the roads under their control so as to meet the most urgent traffic requirements. Provision of facilities has always lagged behind the evident needs. Often a needed widening of surface has been deferred in order to meet more pressing demands for surfacing earth roads or to replace low-type surfaces with more durable construction. Any system of highways constructed with public funds for the free use of the public must be designed on the basis of compromise, and all highway users have been inconvenienced at times by the lack of both wide and smooth surfaces.

It is understood, however, that these conditions must either be accepted or that funds must be provided more rapidly for their correction. The prospective user of a toll highway will regard lack of adequate width in an entirely different light. He will be in a position to choose between the free and the toll route. To attract the motorist the toll roads must offer advantages that loom larger than the tolls charged. There must he no retarding of traffic flow because of lack of width. Therefore the traffic volume at which a toll facility should be widened is inevitably much lower than that at which free highways have been widened. To provide unrestricted movement of the traffic anticipated 20 years hence requires wide pavements at relatively low present volumes.

In considering the possibilities of self-liquidation of any toll highway, the measure of use must be the total volume for a year or some average volume that takes into account seasonal fluctuations. Estimates of probable use are prepared on such a basis for use in financial studies. But such figures do not indicate the necessary widths of pavements because width must be based on the maximum estimated traffic that will use the road at peak periods throughout the year. Not only does the average daily traffic for any month vary considerably from the average on a yearly basis, but also the traffic on the different days of the week varies to a similar or an even greater degree.

To provide means of determining the probable maximum daily and hourly traffic volumes from the estimated average daily volume on the selected routes, records from a number of automatic traffic recorders were analyzed. Selection was made of records from highways on which the fluctuation of traffic was thought to be comparable with that which may be expected on the routes of the selected system.

The results of this analysis are shown in plates 23 and 24. Plate 23 shows that with an average daily volume of 1,500 vehicles, for example, the average daily volume in the month of maximum traffic may be expected to be 2,000 vehicles. Plate 24 shows that 2,000 vehicles per day correspond to a maximum hourly traffic of 520 vehicles.

The next step was to establish a relation between traffic volume and needed width on a toll road. Recently, the Bureau of Public Roads has conducted studies of highway capacity in which exhaustive analysis has been made of the movements of all vehicles using highways of ​

​various widths, carrying a wide range of traffic volumes. Over 300,000 vehicles have been observed in these studies. A number of interesting facts are revealed by analysis of the data collected on a four-lane divided highway representing the highest standards of design, and on a two-lane road, of reasonably good design, both carrying traffic of the same character. The graphical presentation in plate 25 shows that the speed of vehicles begins to decrease with increase in traffic volume, even at very low volumes.

With a zero traffic volume there are no vehicles and consequently there can be no value for vehicle speed, but vehicle speed at zero traffic is approximated when a vehicle moves by itself, so separated from other traffic that the driver is not influenced by the presence of other vehicles on the road. His speed is then uninfluenced by that of other vehicles, and represents a free choice at the particular time on the particular road. The average speed for all vehicles using the road under that condition was, in the case of the two-lane width, 44 miles per hour, and on the divided highway 48 miles per hour. Increase of the total traffic volume to 500 vehicles per hour resulted in a decrease of the average vehicle speeds to 40 and 47.5 miles per hour respectively, and at a volume of 1,000 vehicles per hour in both directions, the speeds become 35.5 and 47 miles per hour. It is significant that there was no serious reduction in speed with increasing volumes on the four-lane road and also that at low traffic volume the traffic moved faster over the divided highway, with its invitation to faster and safer travel, than over the two-lane road.

It has been found that the average speed of all vehicles does not. represent a final criterion of the freedom of movement or congestion. Results of various analyses show that the average difference in speed ​between successive vehicles is a much more positive index of congestion. In periods of light traffic when passing is generally unrestricted, any desired difference in speed between successive vehicles may be maintained. As the traffic volume increases the opportunity for passing diminishes, lines of vehicles form and, accordingly, the difference in speed between successive vehicles becomes less, even though the average speed of all vehicles may not be affected greatly. Plate 26 shows that such difference in speeds is a much more sensitive index of congestion than is the average speed of all vehicles. This graph shows, for roads of the different widths, the mean difference in speed between Here again, a successive vehicles under various traffic volumes. straight-line relation exists between the traffic volume and the speed differences, again indicating that there is an effect on the freedom of movement even with relatively light traffic volumes, and that there is no point at which congestion suddenly occurs.

Beginning with a speed difference of 6.4 miles per hour at zero volume, this figure on the two-lane road drops to 3.5 at 1,000 vehicles per hour in the two directions, while the initial speed difference on the divided highway of 8.3 miles per hour drops only to 7.1 at 1,000 vehicles per hour. To restrict the freedom of movement on the divided highway to a speed difference of 3.5 miles per hour requires a total of over 4,000 vehicles per hour, or over 2,000 vehicles per hour in each direction.

Investigation of the distribution of vehicle speeds, on the two-lane road studied, shows that no vehicles traveled over 60 miles per hour even in traffic as low as 200 vehicles per hour in both directions, and only 7 percent exceeded 50 miles per hour. On the divided highway, ​however, at similar volumes 5.1 percent of the vehicle speeds exceeded 60 miles per hour and 36.6 percent exceeded 50 miles per hour. The width of the two-lane road studied was narrower than the 24-foot width recommended for the toll roads, and similar studies on wider two-lane pavements might show a somewhat greater percentage of fast driving, but it is certainly indicated that on any two-lane road speed of operation would be limited to a greater extent than on four-lane divided highways. These figures add to the evidence that even under conditions of light traffic, four-lane divided highways induce higher speed and therefore will prove more attractive to drivers wishing to save time with safety.

The faster travel speeds in themselves indicate a willingness of the driver to pay for saving in time, since increasing speed increases gasoline consumption. Composite figures obtained by averaging the results of tests on several makes of modern passenger cars show that with steady driving on concrete pavements at a speed of 40 miles per hour, gasoline consumption is 0.0575 gallon per mile. At 60 miles per hour the consumption becomes 0.082 gallon per mile. With gasoline at 18 cents per gallon the cost per mile would increase from 1.03 to 1.47 cents per mile, representing a cost for the higher speed of over 0.4 cent per mile for gasoline alone. Should the availability of a large mileage of high-speed highway induce the more general usage of over-drive transmissions, or the introduction of engines performing more efficiently in the higher speed ranges, the final cost of fast driving on toll highways might be no higher than present costs of traveling at similar speeds, desired but seldom possible, on existing highways.

Since the studies of highway capacity are still incomplete, the figures presented are based on data obtained on the best alinement; that is, a level straight highway. Introduction of grades and curves, even of the low magnitude recommended for the selected routes will tend to reduce somewhat the freedom of movement possible. Therefore, in any section of the country where curves and grades must be incorporated frequently in the design of the highway, there will be on two-lane roads a further restriction to the freedom of movement.

It may be thought that differences in speeds will not be significant on such roads since only persons desiring to travel at the highest reasonable speed will be willing to pay the required fees. This might be true with reference to passenger vehicles, even though the data of plates 25 and 26 tend to dispute that thought, but it must be remembered that the value of time and distance saved over such roads will be largest for commercial vehicles. It may be expected that commercial vehicles, particularly the heavier units, would be attracted to these roads in greater proportion than that in which they are found on the existing roads.

Results of studies of the movement of many thousands of vehicles in many sections of the country show that the spacing of vehicles traveling normally over a highway follows rather definite laws. Analysis of observations shows that with a traffic volume of 200 vehicles per hour in one direction, spaces between these vehicles long enough to permit vehicles moving in the opposite direction to pass ​each other are available only 50 percent of the time, if the time required for the completion of the passing maneuver is 10 seconds. While it is believed that 10 seconds is entirely reasonable, reduction of the time required to 8 seconds would still leave only 55 percent of the time available for passing. It is believed, therefore, that a volume of 400 vehicles per hour with traffic approximately evenly divided in the two directions is a maximum which it is safe to assume may be carried over a two-lane road without inconvenience at some time during the year. Plate 24 shows that this maximum volume of 400 vehicles per hour corresponds to an average daily volume of 1,500 vehicles. Sections of the selected system on which the average daily traffic volume is expected to exceed 1,500 in 1960 are, therefore, planned to be more than two lanes in width.

Neither in theory not in practice is there complete agreement as to the width of road to build when more than two lanes are required. Were adequate accident records available, the proper width for highways wider than two lanes could be based entirely on the factor of safety. In no State, however, are accident data sufficiently complete to permit a reliable analysis of the accident rate on roads of various widths. In theory, a three-lane road has a definite place where the traffic in one direction is much heavier than that in the other direction and where the direction of heavy traffic flow reverses as, for example, between morning and evening. In the case of toll highways, however, it is not anticipated that there will be any such marked difference in the volume of traffic in the two directions and therefore this theoretical advantage of the three-lane highway is not present. Furthermore, many studies of vehicular movement on three-lane highways definitely show a reluctance of drivers to utilize the center lane to the maximum advantage.

From the point of view of driver behavior, the three-lane highway suffers a psychological disadvantage which might well result in an abnormally high accident rate. On a two-lane road, a driver engaged in a passing Maneuver must encroach upon the left lane, the lane which is definitely reserved for traffic in the opposite direction, and he does it with full realization that his passing is accomplished only in the face of the superior rights of drivers in the opposing lane. In the case of the three-lane road, particularly with traffic evenly divided in the two directions, there is no clear-cut right-of-way distinction. A vehicle moving in one direction has as much right in the center lane as one moving in the other direction, and passings may involve much greater traffic hazards.

Furthermore, for the selected routes the three-lane pavement could be regarded only as an expedient. Its traffic capacity is somewhat higher than that of a two-lane pavement, but four lanes will permit, without inconvenience, traffic volumes several times as high as those which may be accommodated on a two-lane road. Inasmuch as the three-lane road does not lend itself readily to remodeling as a four-lane divided highway, which is believed to be the ultimately desirable type of construction, the three-lane road has no place on the selected routes. Although the available accident figures are not sufficiently reliable or voluminous to be employed as a criterion, it is interesting that in one ​State the reported accidents on undivided roadways of two-, three- and four-lane width show but a small difference in the accident expectancy on the basis of accidents per million vehicle-miles. Very limited data from another State in which a modern four-lane highway has recently been opened to traffic show a remarkable reduction in accidents on the four-lane divided section as compared with those of an adjacent fourlane highway. There was 0.31 accident per million vehicle-miles on the undivided highway as compared to 0.13 accident per million vehicle-miles on the four-lane divided section. Although both figures are low, they are fairly comparable, and the advantage of the divided highway is striking.

It is recommended that when the traffic volume becomes too greatto be reasonably accomodated by a two-lane highway, a four-lane divided highway should be provided. All the cost estimates have been based upon this recommendation. The dividing line between two- and four-lane pavements has been taken at an average traffic of 1,500 vehicles per day in 1960. It is unwise to recommend for general use a capacity limit for four-lane highways in terms of total traffic since it is felt that local conditions producing traffic volumes sufficient to justify more than four lanes will be so individual in their characteristics that each case will require special study. Serious congestion on four-lane pavements would occur only in proximity to large cities, where in the periods of heavy volume, the traffic is not evenly divided between the two directions. Accordingly, the volume justifying an increase in width beyond four lanes is based on the traffic in one direction only, rather than on the total in both directions.

Figures show that the same freedom of movement possible on a two-lane road with a total hourly volume of 400 vehicles will be found on a four-lane divided highway with an hourly volume of 2,600 vehicles, or 1,300 vehicles in each direction. Using the ratio between the maximum hourly volume and the average daily volume throughout the year found on two-lane roads, 1,300 vehicles per hour represent a daily average of 5,000 vehicles in each direction. Typical heavily traveled roads show that in periods of heavy volume, the volume in one direction is seldom more than double that in the other. Therefore, an average of 7,500 vehicles per day in both directions is considered a conservative figure for the capacity of a four-lane divided highway without inconvenience at any time. This figure is offered only as a rough indication, and should not be used where it is possible to study and analyze traffic characteristics. Traffic volumes far higher than 7,500 vehicles per day may be accomodated on four-lane surfaces with slight inconvenience at certain times, but still at relatively high average speeds. The 1,300 vehicles per hour in each direction could travel at an average speed of 45 miles per hour, but the traffic may be increased to 3,400 vehicles per hour in each direction with an average speed of 40 miles per hour. Each of these figures represents an average speed, and with the distribution of speeds normally encountered, some vehicles must travel at 60 miles per hour or faster to offset those which travel under 40 miles per hour even in light volumes. ​

In accordance with criteria and standards previously established the selected routes were approximately fixed by detailed location on large-scale maps, chiefly county maps, prepared in connection with the State highway planning surveys. A typical section of one of these maps is shown in plate 27. The lines were located either by Bureau of Public Roads engineers resident in the several States or by engineers of the State highway departments, or both, working together. In all cases the locating engineers were intimately familiar with the areas in which they worked.

Wherever necessary a field reconnaissance was made. It is thus reasonably assured that the approximate locations chosen are practicable of development and conform closely to the criteria adopted. The field inspections also permitted a better judgment to be formed of the quantities of the various construction items that should be accounted for in the estimates of cost.

The alinements chosen extend as directly as possible from one major source of traffic to another, deviating from such direct lines to serve minor sources of traffic only where it has been estimated that the resulting increase of traffic would be substantial. Sources of traffic, in general, consist of cities and towns, intersecting highways, and points of travel interest, such as national parks, resorts, etc.

In all but two sections, totaling 94.2 miles, the detailed locations have been made entirely on new lines apart from existing roads. One of the excepted sections, 51.9 miles in length, lies along the Columbia River in Oregon; the other, 42.3 miles long, crosses the Sierra Madre Range north of Los Angeles, Calif. In these sections the alinement chosen coincides with that of existing highways because no other topographically feasible line could be found.

The chosen approximate locations bypass cities and towns, but pass sufficiently close to them, wherever possible, to attract their traffic. In detail, the locations are such that (1) control of access may be readily obtained wherever possible; (2) obstruction to the outward development of cities and interference with communication across the selected route are avoided to the greatest extent possible; (3) the cost of grade separation structures is reduced to the feasible minimum; and (4) a maximum feasible benefit of low land values is gained.

It was considered necessary that the design standards of the selected routes be sufficiently superior to the standards of existing roads to attract traffic, insure a maximum of safety and utility in their present use, and conform so far as possible to the probable requirements of future traffic. At the same time the standards were not set so far in advance of the requirements of existing traffic as to incur excessive initial costs which present users should not be asked to pay. For example, over three-fourths of the mileage of the routes, as designed, consists of two-lane roads, but to meet the possibility of future expansion to four lanes the initial pavement would be placed at one side of the right-of-way. ​

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In general, the design provides a right-of-way width of 300 feet in rural areas and 160 feet in suburban areas. These are in the nature of minimum widths. In rural areas it is expected that they may be exceeded where (1) land values are very low; (2) it may be less expensive to acquire extra land to avoid the cost of constructing grade-separation structures for roads to connect private property divided by the road; or (3) where additional land is needed for some special construction or border control. In suburban areas the minimum width may be exceeded where (1) the additional land is required to allow for expected future growth or to insure effective control of the road; (2) it may be economically feasible to purchase parcels of real estate in their entirety instead of paying damages for areas left isolated by the construction of the road; or (3) it may be less expensive to acquire additional land and so to avoid costly construction, such as retaining walls. In rare instances it may be advisable to restrict the right-of-way to less than the minimum widths mentioned to avoid the purchase of very expensive or important land or buildings, even though the result may be an apparently excessive construction cost; but in no case should this be done at a sacrifice of the minimum standards of design.

It was the purpose to design the selected routes for use at a normal maximum speed of 70 miles per hour. Consistent with this purpose, the normal standards of curvature and gradient were set at maxima of 3° for curves and 3 percent for grades. Jn applying these standards, however, it was necessary to make some concession to topography to avoid costs clearly exceeding the benefits to be gained by adherence. In rugged mountainous terrain an effort was made to keep within maxima of 4° curvature and 4-percent gradient, and this was found possible at reasonable cost except on four sections having and aggregate length of 153.8 miles. For these four sections alternate locations were made, one conforming to the 4° curvature and 4-percent grade requirement, and one permitting curves of 6° and grades of 6 percent.

The estimated cost of constructing the 153.8 miles to the lower standard is $26,107,000. Built to the higher standard these lines would aggregate 172.4 miles in length and their cost would be $42,124,600. It is concluded that the advantage to be gained by building to the higher standard would not justify the additional 18.6 miles of travel and the increased construction cost of $16,017,600.

The sections involved and the estimated lengths and costs of each are as follows:

Section	6°—6-percent standard		4°—4-percent standard
	Length	Estimated cost	Length	Estimated cost
	Miles		Miles
Castaic Junction, Calif., to Wheeler Ridge, Calif. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .	50.6	$12,798,564	55.9	$26,409,860
Wells, Nev., to Nevada–Utah State line . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .	58.3	4,819,140	64.4	5,285,090
In Sierra County, Calif. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .	14.7	3,098,980	16.0	3,577,380
In Nevada County, Calif. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .	30.2	5,390,310	36.1	6,852,270
Total . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .	153.8	26,106,994	172.4	42,124,600

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Considerations of safety require that the length of road ahead visible to drivers of vehicles be at all points at least as great as the distance required to stop a vehicle moving at the assumed design speed, allowing 2 seconds for perception and brake reaction and a braking distance based upon a uniform coefficient of friction of 0.4. The distance thus required is 614 feet. Three-degree curvature in unwidened cuts allows a minimum sight distance of 690 feet; 4° curvature under similar circumstances provides a minimum sight distance of 590 feet. The higher of these standards, therefore, would conform to the requirements of safety corresponding to the assumed design speed of 70 miles per hour, the lower would be only slightly deficient; but 6° curvature under similar conditions would provide seriously insufficient sight distance for safety of operation. On the 153.8 miles located to the latter standard it might be necessary in places either to widen cuts where they occur on the sharper curves or indicate the necessity for caution by warning signs.

Modern passenger cars in good condition are capable of maintaining relatively high speeds on 3- and 4-percent grades and even on grades of 6 percent. Motortrucks, as at present designed, are incapable of such performance. Tests by the Bureau of Public Roads indicate that the larger vehicles now in general use, when loaded in accordance with the manufacturer’s gross-weight rating, cannot be expected to climb 4-percent grades at a speed greater than 25 miles per hour. On 3-percent grades a speed of 30 miles per hour is the maximum that may be expected under the same conditions. With vehicles loaded 50 percent over the manufacturer’s rating—a practice that is not uncommon—the corresponding maximum speeds for 4- and 3-percent grades are 16 and 22 miles per hour respectively. Under either condition of loading a 6-percent grade slows the larger modern trucks to a crawling speed.

On grades of steepness approaching either the 3- or 4-percent standards and, of course, on the exceptional 6-percent grades, ample provision is required to permit the passing of trucks by passenger cars.

On 2-lane roads the sight distance, wherever possible, should be sufficient to permit passing of the slower vehicles when the visible length of road is clear of opposing traffic, even if opposing traffic appears after the operation of passing is begun. Where such a sight distance cannot feasibly be obtained signs must be placed to prohibit passing. Such limited sections should be permitted only as exceptions, and in no case should their continuous length exceed about 2 miles.

For roads of the character of those proposed only high-type pavements are appropriate. The pavement thickness should be designed in each section to be consistent with the wheel loads to be expected. A smooth-riding surface, as nonskid and glareproof as possible, should result. Subbases should be used wherever required; and, both for pavements and subbases, good local materials should preferably be used, if available.

Material encountered in foundations should be analyzed, and, if found to be unstable, should be replaced or improved by stabilization, ​using cementing admixtures as required. To the extent possible measures should be taken to insure a uniform moisture content of the subgrade.

Typical cross sections are shown in plate 28. As indicated, all traffic lanes of the proposed roads would be 12 feet wide. On two-lane roads these lanes are shown as separated by a traversable dividing strip 2 feet wide. This is believed to be a desirable feature; in fact a more positive division between the lanes of opposing traffic would be desirable, but on two-lane roads is impossible because of the necessity of using the opposing traffic lane as a passing lane. For this reason the narrow dividing strip provided should be built as a traversable surface, flush with the surface of the traffic lanes, but contrasting with them in color and texture, so that drivers will be warned both visually and physically when they cross it or encroach upon it.^[1]

Where the expected traffic volume justifies the construction of more than two traffic lanes, four lanes built in pairs, the pairs separated by a parkway strip at least 20 feet wide in suburban areas and 40 feet wide in rural areas, would be provided. These widths of medial parkway strips are ample and may, in exceptional cases, be reduced, since the separation of grades at intersections obviates need of the parkway for protection of crossing vehicles. Sections of the selected routes on which two- and four-lane pavements would be required are shown on plate 29.

Each two-lane pavement would be designed to drain to both sides and drainage would be provided in the medial parkway strip. This design is particularly advantageous in sections subject to snow. The parkway is a convenient area on which to store the snow which, when melted, runs off into the central drain instead of flowing across the pavements to create a serious hazard in case of sudden freezing.

Shoulders would be invariably 10 feet wide to provide adequate space for stopping off the pavement. In construction they would be sufficiently strong to support the weight of vehicles in all weather.

Slopes of cuts and fills would be designed to prevent erosion. Where feasible, fills would be made to a slope of 1 on 4 or flatter to avoid the use of guardrails and in no case, except perhaps in some mountain locations, would their slope be steeper than 1 on 2. Cut slopes would be varied according to the character of the materials encountered and the depth of cut. All cut slopes would be liberally rounded for both stability and appearance; and no hazardous breaks, such as deep ditches, would be permitted. At ends of cuts and fills, slopes would be made progressively flatter so that they would gradually merge with the ground and with each other.

Low curbs, with flat slopes readily mounted in emergencies, would be used in park areas and on the inside of curves where necessary to control drainage and reduce the maintenance of shoulders or medial parkway strips. Curbs of this character would be contiguous with the pavement proper. Curbs intended to prevent vehicles from leaving the pavement, as at walls and bridges, would be of the barrier type, set at least 2 feet from the edge of pavement. All curbs should be highly visible day and night.

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The grade of the toll road, wherever possible, would be laid above the general level of the surrounding land. Where divided roads are located on slopes, the two sides would be placed at different levels in the interest of economy of construction, additional safety through the reduction of headlight glare, and a more pleasing appearance.

On the roads as planned there would be no intersections at grade. At no point would a driver encounter another vehicle. crossing his path; and at no point, except at the especially designed accesses, would he encounter another vehicle entering the roadway. Railroad grade crossings would be avoided generally by carrying the highway overhead. In fewer instances the highway would pass beneath the railroad.

All intersecting highways of importance would be carried over or under the proposed roads. Cross roads serving light traffic would be closed and their traffic diverted via existing roads, or roads constructed for the purpose, to the nearest grade-separated intersection. The same considerations would govern in respect to the treatment of intersecting streets in suburban areas. Traffic on unimportant intersecting streets is frequently much greater than on the lesser roads in rural areas. For this reason grade-separation structures would probably be much closer. The construction of parallel streets would not only serve rerouted traffic from unimportant streets but also serve adjacent property cut off by the construction of the proposed road. A typical 4-lane highway in an urban area is shown in plate 30.

At all points where the selected routes intersect, the design would be such that traffic, regardless of direction, would be able to proceed or turn without crossing traffic on either road. All traffic would leave or enter at the right on suitable acceleration and deceleration lanes. The full clover-leaf type of grade-separation structure meets all conditions and requires but one structure. It is more confusing to the driver, however, than some “braided” types of intersection which may require more than one separation structure but which result in more direct access roads.

Where private property is divided by the construction of the roads use of the land would be restricted to a considerable extent. To minimize the restriction it would be necessary to provide crossing-separation structures to permit passage from one part of the property to the other sufficiently close together and of sufficient size to insure reasonable use of the land as a whole for its intended purpose. In rural areas simple cattle passes will often suffice though sometimes the structures may have to be built large enough to accommodate wagons and motor vehicles. In suburban areas, where the land is subdivided, the structure clearances and load capacities would have to be sufficient for use as a future street. In some cases it may be sufficient to agree to construct a grade separation structure at a future time when the need develops. In other cases, where the value of the land is low, acquisition of the affected land may be the most economical procedure. ​

Culverts, bridges over streams, railroad and highway separation structures, and all other structures such as retaining walls would be constructed so that vehicles will have adequate clearance and drivers will feel no sense of restriction at any point.

Structures carrying the traffic of the proposed roads would be designed in all respects except their clearances, in accordance with the Standard Specifications for Highway Bridges of the American Association of State Highway Officials. The live loading would be H-20. Structures carrying intersecting roads would be designed in accordance with the standard practice of the agency in control of the intersecting road but in no case for a live loading less than H-15.

The vertical clearance provided at undercrossings would be at least 14 feet within the limits of the pavement; and horizontal clearances would be such that the shoulders would be carried through the structure opening without reduction in width. Medial parkway strips would not be narrowed and one pier only would be permitted in the middle of them. Future sidewalks, if required, would be carried through in the shoulder area.

When the proposed roads are carried on structures of moderate length (up to about 100 feet) the width of the medial strip would not be reduced and the normal shoulder area would be used for sidewalks. For bridges over 100 feet long the medial strip might be narrowed but in no case to less than 6 feet between curbs. All curbs on bridges would be 2 feet outside the normal edge of the pavement so that the minimum medial distance between normal inside edges of pavements on divided roads would be at least 10 feet. Changes in width of medial strip would be accomplished by gradual transition to avoid all sense of forced alinement.

Substantial bridge railings would be located at the pavement curbs. Sidewalks would be located between the curb and pedestrian railings at the sides of the bridge.

Where it is necessary to omit shoulders, as at high retaining walls, barrier curbs would be placed 2 feet outside the normal edge of pavement and the nearest face of the retaining wall would be at least 2 feet from the face of the curb.

Guardrails, where required, would be placed clear of the normal shoulder and carried continuously past all culverts. The width of embankment would be increased to accommodate the rail. Railings would be extended well beyond the ends of fills to overlap adjacent cuts or shallow sloping fills.

Access points would not be spaced at regular intervals but would be located to give the maximum service commensurate with the cost of maintaining toll booths and toll operators. For example, the average distance between the access points proposed in New Jersey is 2.6 miles, the minimum 0.5 mile, and the maximum 7.5 miles. In Montana, the average distance between proposed access points is 79.4 miles, the minimum 9.2 miles, and the maximum 140 miles. A typical grade separation, access roads, and toll booths for a fourlane toll road are shown in plate 31. Traffic would always enter and leave the toll road on the right. Liberal deceleration and acceleration ​

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​lanes would be provided, clear of the normal traffic lanes, to permit traffic to slow down before entering the access drive and to pick up speed before weaving into the high-speed traffic stream on the toll road.

Access drives would lead by easy grades and curves past the toll booths which would be visible from the toll road and the intersecting road. Ample storage space for entering vehicles would be provided approaching the toll booths.

A typical grade separation, access roads, and toll booths for a twolane toll road are shown in plate 32. Traffic on the toll road should be prevented from making left turns. Two access drives and two toll booths, therefore, would be provided regardless of traffic density. To prevent all possible conflicts of turning traffic the toll road would have to be designed as a four-lane divided road at the intersection. A less complete facility, but one which might suffice on the more lightly traveled roads, would be provided by widening the two-lane road to three lanes, as shown in plate 32. The middle lane, in this case, should contrast in color and surface texture with the outside traffic lanes and generally would be used only by through traffic to pass vehicles slowing down to leave the toll road or vehicles just entering the toll road. Acceleration and deceleration lanes, therefore, would not be necessary with this type of facility.

As toll collection constitutes an appreciable operating expense, study was made of the possibility of utilizing only one toll booth at each access and providing traffic circulation so that all crossing of traffic would be avoided. The result is shown in plate 33. On a conservative basis it was estimated that the annual cost of operation of a second toll booth would be less than the excess of the annual interest and amortization charges on the cost of the extra grade separation structure and other additional construction over the relatively simple arrangement of two accesses. This is particularly marked for two-lane roads where the cost of constructing an appreciable length of four-lane divided road as against a three-lane road must be added to the extra cost.

At intersections with important existing highways on which the making of left turns is hazardous, four access roads or a full cloverleaf type of grade separation with four toll booths should be provided.

The proposed roads would be lighted to the extent justified. Lighting is considered to be necessary in tunnels, on long bridges, and access drives and in suburban areas where lighting of adjacent streets would confuse drivers if similar lighting were not provided on the road. While fixed sources of light are generally to be preferred, other methods of outlining the road at night, such as the use of reflectors, may be considered as supplements and possibly as a substitute for fixed-source lighting.

Because of the relatively high speeds expected on the proposed roads some variation from the standards recommended by the Manual on Uniform Traffic Control Devices of the Joint Committee of the American Association of State Highway Officials and the Conference on Street and Highway Safety would be required in the design, ​erection, and location of signs. Generally the signs would be much larger than those recommended in the manual so that they could be read at greater distances; and those intended to give notice of the approach to access points would be erected in multiple so that drivers would be informed repeatedly of the facility ahead some time before reaching it. The character of the road should obviate the necessity for a multiplicity of warning signs. All signs would be lighted or of the reflecting type so as to be easily readable at night.

The roadside and slopes would be protected against erosion largely by the use of flat and rounded slopes. Additional protection would be given by topsoiling and seeding to produce vegetative cover suited to location, soil, and climate.

The roadsides would be planted under the supervision of landscape architects with the general objective of giving a pleasing appearance and making the new construction fit into the surrounding landscape.

Only native trees and shrubs that require little or no maintenance would be planted. They would be arranged naturally in groups at some distance from the pavement so as not to present secondary hazards to cars out of control.

The desirability of providing roadside parks, picnic areas, and other facilities inviting drivers to stop and rest must be determined by future policy. Facilities that would invite short-trip traffic and make the long trips more pleasant would build up public good will and might add appreciably to the revenues collected.

Protection from encroachment is necessary on a toll road. Both sides of the road would have to be fenced except where steep slopes, dense forests, canyons or other natural conditions give the needed protection. The type of fence required will depend upon local conditions.

The standards of design described in the foregoing pages have been applied in detail to the approximate route locations as fixed on the large-scale maps, and all design decisions necessary for an estimate of cost have been made in great detail. Such decisions have been recorded in tables for the entire mileage of the selected routes. Straight-line diagrams of the tabulated data for portions of the mileage, representative of various sections of the country, are shown in plates 34 to 45.

On each of these diagrams the section of the selected routes covered is represented by a central line or lines. A single line indicates that the pavement designed for the particular section is two lanes wide; double lines indicate sections that would be constructed with divided four-lane pavements. Scaled distances along the central line or lines represent the lengths of continuous sections of each width of pavement; and at properly scaled intervals the positions of all cross roads, intersecting railroads, rivers, State and county lines, and other significant features of the locations as fixed are symbolically indicated. ​

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Wherever bridges or trestles over rivers and streams would be required on the route locations as projected they are shown on these diagrams. At intersections of the projected lines with all other roads and railroads the diagrams indicate the probable manner in which the grades at the intersection would be separated, whether by underpass or overpass.

The estimated 1937 traffic on all cross roads at their points of intersection with the projected route locations is shown by the length, to an indicated traffic scale, of short vertical bars appropriately positioned above the points at which the corresponding cross roads intersect the projected line. Consistent with the indications of this traffic scale, numerous lightly traveled cross roads are shown as scheduled for closing if the projected road is built, their traffic to be diverted to nearby crossings.

Finally, the straight-line diagrams and the tabulated information on which they are based show the location of all proposed access points on the routes as located, and their relation to cities and towns and important intersecting roads.

Coupled with the large-scale maps showing the approximate geographic position and courses of the routes, the diagrammed and tabulated decisions with respect to the design of the roads serve as the basis for the estimated cost of the proposed facilities.

The estimates of right-of-way and construction costs were made and compiled in the several district offices of the Bureau of Public Roads in accordance with uniform basic decisions laid down by the Chief of Bureau. All unit costs and construction quantities used were based on intimate knowledge of all local conditions and the current prices paid for the various items of work.

Right-of-way.—Right-of-way, exclusive of accesses, was assumed to consist of 36 acres per mile for rural areas and a minimum of 19 acres per mile for urban areas. These values are based on widths of 300 feet and 160 feet, respectively. For each access point, from 3 to 10 acres were added for two-lane construction and from 10 to 15 acres were added for four-lane construction. Property damage, if any, was estimated and added as a lump sum between control points. Right-of-way and property damage varied from a minimum of $5 per acre to $50,000 per acre.

Where it was necessary to relocate existing highways or construct new service roads between control points so that traffic on closed cross roads could be rerouted to nearby separated crossings or to restore service on public roads occupied by the new construction, estimates were made of the mileage involved and the costs per mile.

Grading. Estimates of grading quantities were based upon a uniform schedule of earthwork volumes per mile corresponding to five general types of topography, from which an appropriate selection was made for each varying section of the located lines. ​

The schedule referred to follows:

Symbol	Type of topography	Earthwork quantities per mile of selected route
		For sections with 2-lane pavements	For sections with 4-lane pavements and 20- foot central parkway	For sections with 4-lane pavements and 40- foot central parkway
		Cubic yards	Cubic yards	Cubic yards
RL	Relatively level . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .	30,000	50,000	60,000
GR	Gently rolling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .	50,000	90,000	100,000
HR	Heavy rolling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .	100,000	180,000	200,000
LM	Light mountainous . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .	200,000	350,000
HM	Heavy mountainous . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .	350,000	500,000

These quantities were understood to represent averages per mile and were not construed as applying to short sections of the most rugged topography. Quantities intermediate between the tabulated values were used where conditions warranted. The estimated unit cost of grading varied from $0.15 to $1 per cubic yard, the average being about $0.32 per cubic yard.

Retaining walls.—Where retaining walls were recommended, as in heavy mountainous areas, estimated quantities were determined between control points. Consideration was given to the use of viaducts in lieu of high fills and grading quantities were appropriately modified.

Drainage structures.—Costs of drainage structures up to 20-foot spans were determined at an estimated cost per mile between given control points.

Surfacing.—High-type surfaces of a thickness consistent with anticipated traffic requirements were estimated on the basis of 14,100 square yards per mile for two-lane sections and 28,200 square yards per mile for four-lane sections. ‘The unit costs varied from $0.65 to $3.30 per square yard, depending upon the type of surfacing used.

Miscellaneous.—Areas of clearing and grubbing were estimated to vary from about 8 acres per mile for two-lane sections to about 25 acres per mile for four-lane sections.

Curbs, where required to control drainage, were placed 2 feet outside the normal road surfacing and the estimated cost per mile included the cost of the extra 2 feet of pavement.

Guard railing was estimated where slopes as steep as 1 on 2 were required.

Large reflecting signs were provided in repetition approaching all accesses. A maximum amount of $1,000 per mile of highway regardless of width was allowed for this item. Fencing, on both sides of the highway, was estimated at an average of $3,000 per mile.

Topsoiling, seeding, and planting costs depend to a considerable degree on topography and climate. Allowances were made for this item in the amounts of $5,000 to $8,000 per mile in suburban areas, and $3,000 to $6,000 per mile in rural areas.

Bridges, viaducts, tunnels, and accesses.—The width of bridges was defined as the perpendicular distance face to face of the bridge; the length as the distance face to face of the abutments measured parallel to the centerline of the road. An undercrossing was defined as one at which the selected route would pass under, and an overcrossing as ​one at which the selected route would pass over, the intersecting road. On the above bases of length and width, estimates were made for the following classes of structures at the costs assigned to each:

For stream bridges, less than 100 feet in length, $10 per square foot. For long stream bridges the estimates varied in accordance with conditions found at the sites. Costs ranged from $6.50 to $28.50 per square foot.

For bridges over railroads $15 per square foot plus $10,000 and for railroad bridges $20 per square foot plus $10,000.

For highway separation bridges in rural areas $15 per square foot plus $10,000, and in urban areas $17 per square foot plus $16,000.

Cattle passes, or equivalent land purchases, were estimated at about $8,000 for each two-lane and $15,000 for each four-lane highway crossing.

Costs of tunnels were estimated individually in accordance with the geological formation encountered.

Three general types of accesses were estimated at the following lump sums:

(A) Accesses to two-lane roads widened to three lanes at the intersection, with two toll booths, at a lump sum of $70,000 for each point of access. This lump sum included:

Grading, paving, and appurtenances of the accesses.

Widening to a three-lane highway for about 2,000 feet.

Transitions for the approaches to the widened portion.

Additional width of grade-separation structure.

(B) Accesses to two-lane roads widened to four lanes divided at the intersection, with two toll booths, at a lump sum of $240,000 for each point of access. The items involved are the same as for type A except that the item of widening involves a four-lane divided highway for about 3,700 feet.

(C) Accesses to four-lane roads, with two or more toll booths, at a lump sum of $50,000 for each point of access. The items involved are the same as for type A except those due to the widening of the selected route.

Type A was used for all two-lane sections except those which are expected to carry near-capacity traffic, where widening to a four-lane divided highway may reasonably be expected in a comparatively short time, in which case type B was used.

The field form used for estimating costs is illustrated by the typical sheets shown in plates 46 and 47. Estimates prepared on these forms were summarized by access points, by counties, by sections, and by routes.

The total cost for right-of-way and construction of the 14,336.2 miles of the selected routes, as estimated in the manner above described, including 10 percent for engineering, contingencies, and interest during construction, is $2,899,770,145, which is at the average rate of $202,270 per mile. The average costs estimated vary from a maximum of $1,158,412 per mile for the 65.6-mile section from Jersey City, N. J., to New Haven, Conn., to a minimum of $63,450 per mile for the 119.7-mile section from Rupert, Idaho, to Brigham, Utah.

Table 4 gives a summary of the physical features involved and the estimated costs by routes.

Tables 5 to 15 show a distribution of construction costs by items for the system and for each route, subdivided by States. ​

Route No.	Route	Length in miles			Number of roads closed	Number of under passes	Number of over passes	Number of railroad under passes	Number of railroad over passes	Number of bridges	Number of tunnels	Number of accesses	Total construction cost by routes
		Total	2-lane pavement	4-lane pavement
1	Miami, Fla., to Madawaska, Maine	1,856.2	1,151.5	704.7	554	288	600	15	139	360		144	$464,886,080
2	Seattle, Wash., to Boston, Mass.	2,978.8	2,007.6	971.2	1,272	378	697	29	167	383	2	145	548,053,850
3	Laredo, Tex., to Chicago, Ill.	1,258.2	1,173.9	84.3	676	70	327	6	81	255	4	44	223,176,151
3 Mich.	Angola, Ind., to Port Huron, Mich.	174.7	54.7	120.0	123	12	100	3	13	37		16	48,363,666
4	Oakland, Calif., to Philadelphia, Pa.	2,816.8	2,373.1	443.7	1,148	232	442	19	148	496	11	105	466,339,733
4-A	Capital Branch	88.5	88.5		52	9	26	1	4	12		7	13,087,200
4 S	Whitewater, Calif., to Salt Lake City, Utah	593.6	593.6		60	10	37	2	13	259		12	58,039,418
4 N	Portland, Oreg., to Salt Lake City, Utah	770.7	770.7		183	40	72	2	22	93	1	31	104,810,492
5	San Ysidro, Calif., to Blaine, Wash.	1,406.4	604,0	802.4	377	253	275	6	64	333	8	84	371,527,504
6	Los Angeles, Calif., to Charleston, S.C.	2,392.3	2,172.7	219.6	753	139	382	1	101	683	1	80	337,870,583
Total		14,336.2	10,996.3	3,345.9	5,198	1,431	2,958	84	752	2,911	27	668	2,636,154,677

Route No.	Right- of-way, property damage, and relocation	Grading	Minor drainage	Surfacing	Clearing and grubbing	Curbs	Guardrails	Signs and markers	Fencing	Topsoil, seeding and planting	Bridges	Tunnels	Accesses	Total
1	$39,301,135	$75,698,021	$16,747,530	$91,773,392	$3,003,165	$1,798,035	$2,663,385	$1,882,900	$5,427,750	$7,799,480	$209,731,287		$9,060,00	$464,886,080
2	43,875,413	113,092,140	29,979,265	131,954,429	3,928,303	1,628,970	4,082,810	2,379,300	8,931,000	12,088,000	179,602,220	$7,572,000	8,940,000	548,053,850
3	13,588,986	37,850,560	11,522,130	45,498,033	3,439,182	1,638,259	1,233,270	1,255,210	3,765,430	5,691,720	95,040,371	1,003,000	3,650,000	223,176,151
3 Mich.	5,541,355	9,007,485	3,720,450	8,400,356	165,625	929,550	401,830	174,290	523,370	739,590	17,124,735		1,635,000	48.363,666
4	32,113,959	104,202,015	23,823,660	106,102,994	2,563,400	1,186,600	4,594,570	2,630,025	8,448,375	9,872,585	142,360,050	19,931,500	8,510,000	466,339,733
4-A	1,497,000	3,382,500	942,250	3,277,000	64,350	27,000	96,500	89,100	264,900	357,100	2,639,500		450,000	13,087,200
4 S	1,234,520	27,117,175	2,936,300	10,232,123	113,980		743,080	528,300	1,780,800	1,211,000	11,302,140		840,000	58,039,418
4 N	11,211,930	24,328,130	1,808,730	21,251,381	633,180		903,100	777,500	2,303,700	2,854,200	33,131,841	316,800	2,290,000	104,810,492
5	33,980,230	76,131,450	11,850,350	72,442,440	3,398,750	506,000	1,844,425	1,390,300	4,167,150	6,415,500	147,486,409	6,149,500	5,765,000	371,527,504
6	14,442,990	65,182,807	11,381,360	70,504,607	2,400,384	1,443,979	1,848,900	2,255,330	6,882,910	9,627,480	146,424,836		5,475,000	337,870,583
Total	196,787,518	535,992,283	114,712,025	564,436,785	17,710,319	9,158,393	18,411,870	13,362,255	42,495,385	56,656,655	984,843,389	34,972,800	46,615,000	[1]2,636,154,677

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Wherever bridges or trestles over rivers and streams would be required on the route locations as projected they are shown on these diagrams. At intersections of the projected lines with all other roads and railroads the diagrams indicate the probable manner in which the grades at the intersection would be separated, whether by underpass or overpass.

The estimated 1937 traffic on all cross roads at their points of intersection with the projected route locations is shown by the length, to an indicated traffic scale, of short vertical bars appropriately positioned above the points at which the corresponding cross roads intersect the projected line. Consistent with the indications of this traffic scale, numerous lightly traveled cross roads are shown as scheduled for closing if the projected road is built, their traffic to be diverted to nearby crossings.

Finally, the straight-line diagrams and the tabulated information on which they are based show the location of all proposed access points on the routes as located, and their relation to cities and towns and important intersecting roads.

Coupled with the large-scale maps showing the approximate geographic position and courses of the routes, the diagrammed and tabulated decisions with respect to the design of the roads serve as the basis for the estimated cost of the proposed facilities.

The estimates of right-of-way and construction costs were made and compiled in the several district offices of the Bureau of Public Roads in accordance with uniform basic decisions laid down by the Chief of Bureau. All unit costs and construction quantities used were based on intimate knowledge of all local conditions and the current prices paid for the various items of work.

Right-of-way.—Right-of-way, exclusive of accesses, was assumed to consist of 36 acres per mile for rural areas and a minimum of 19 acres per mile for urban areas. These values are based on widths of 300 feet and 160 feet, respectively. For each access point, from 3 to 10 acres were added for two-lane construction and from 10 to 15 acres were added for four-lane construction. Property damage, if any, was estimated and added as a lump sum between control points. Right-of-way and property damage varied from a minimum of $5 per acre to $50,000 per acre.

Where it was necessary to relocate existing highways or construct new service roads between control points so that traffic on closed cross roads could be rerouted to nearby separated crossings or to restore service on public roads occupied by the new construction, estimates were made of the mileage involved and the costs per mile.

Grading. Estimates of grading quantities were based upon a uniform schedule of earthwork volumes per mile corresponding to five general types of topography, from which an appropriate selection was made for each varying section of the located lines. ​

The schedule referred to follows:

Symbol	Type of topography	Earthwork quantities per mile of selected route
		For sections with 2-lane pavements	For sections with 4-lane pavements and 20- foot central parkway	For sections with 4-lane pavements and 40- foot central parkway
		Cubic yards	Cubic yards	Cubic yards
RL	Relatively level . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .	30,000	50,000	60,000
GR	Gently rolling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .	50,000	90,000	100,000
HR	Heavy rolling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .	100,000	180,000	200,000
LM	Light mountainous . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .	200,000	350,000
HM	Heavy mountainous . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .	350,000	500,000

These quantities were understood to represent averages per mile and were not construed as applying to short sections of the most rugged topography. Quantities intermediate between the tabulated values were used where conditions warranted. The estimated unit cost of grading varied from $0.15 to $1 per cubic yard, the average being about $0.32 per cubic yard.

Retaining walls.—Where retaining walls were recommended, as in heavy mountainous areas, estimated quantities were determined between control points. Consideration was given to the use of viaducts in lieu of high fills and grading quantities were appropriately modified.

Drainage structures.—Costs of drainage structures up to 20-foot spans were determined at an estimated cost per mile between given control points.

Surfacing.—High-type surfaces of a thickness consistent with anticipated traffic requirements were estimated on the basis of 14,100 square yards per mile for two-lane sections and 28,200 square yards per mile for four-lane sections. ‘The unit costs varied from $0.65 to $3.30 per square yard, depending upon the type of surfacing used.

Miscellaneous.—Areas of clearing and grubbing were estimated to vary from about 8 acres per mile for two-lane sections to about 25 acres per mile for four-lane sections.

Curbs, where required to control drainage, were placed 2 feet outside the normal road surfacing and the estimated cost per mile included the cost of the extra 2 feet of pavement.

Guard railing was estimated where slopes as steep as 1 on 2 were required.

Large reflecting signs were provided in repetition approaching all accesses. A maximum amount of $1,000 per mile of highway regardless of width was allowed for this item. Fencing, on both sides of the highway, was estimated at an average of $3,000 per mile.

Topsoiling, seeding, and planting costs depend to a considerable degree on topography and climate. Allowances were made for this item in the amounts of $5,000 to $8,000 per mile in suburban areas, and $3,000 to $6,000 per mile in rural areas.

Bridges, viaducts, tunnels, and accesses.—The width of bridges was defined as the perpendicular distance face to face of the bridge; the length as the distance face to face of the abutments measured parallel to the centerline of the road. An undercrossing was defined as one at which the selected route would pass under, and an overcrossing as ​one at which the selected route would pass over, the intersecting road. On the above bases of length and width, estimates were made for the following classes of structures at the costs assigned to each:

For stream bridges, less than 100 feet in length, $10 per square foot. For long stream bridges the estimates varied in accordance with conditions found at the sites. Costs ranged from $6.50 to $28.50 per square foot.

For bridges over railroads $15 per square foot plus $10,000 and for railroad bridges $20 per square foot plus $10,000.

For highway separation bridges in rural areas $15 per square foot plus $10,000, and in urban areas $17 per square foot plus $16,000.

Cattle passes, or equivalent land purchases, were estimated at about $8,000 for each two-lane and $15,000 for each four-lane highway crossing.

Costs of tunnels were estimated individually in accordance with the geological formation encountered.

Three general types of accesses were estimated at the following lump sums:

(A) Accesses to two-lane roads widened to three lanes at the intersection, with two toll booths, at a lump sum of $70,000 for each point of access. This lump sum included:

Grading, paving, and appurtenances of the accesses.

Widening to a three-lane highway for about 2,000 feet.

Transitions for the approaches to the widened portion.

Additional width of grade-separation structure.

(B) Accesses to two-lane roads widened to four lanes divided at the intersection, with two toll booths, at a lump sum of $240,000 for each point of access. The items involved are the same as for type A except that the item of widening involves a four-lane divided highway for about 3,700 feet.

(C) Accesses to four-lane roads, with two or more toll booths, at a lump sum of $50,000 for each point of access. The items involved are the same as for type A except those due to the widening of the selected route.

Type A was used for all two-lane sections except those which are expected to carry near-capacity traffic, where widening to a four-lane divided highway may reasonably be expected in a comparatively short time, in which case type B was used.

The field form used for estimating costs is illustrated by the typical sheets shown in plates 46 and 47. Estimates prepared on these forms were summarized by access points, by counties, by sections, and by routes.

The total cost for right-of-way and construction of the 14,336.2 miles of the selected routes, as estimated in the manner above described, including 10 percent for engineering, contingencies, and interest during construction, is $2,899,770,145, which is at the average rate of $202,270 per mile. The average costs estimated vary from a maximum of $1,158,412 per mile for the 65.6-mile section from Jersey City, N. J., to New Haven, Conn., to a minimum of $63,450 per mile for the 119.7-mile section from Rupert, Idaho, to Brigham, Utah.

Table 4 gives a summary of the physical features involved and the estimated costs by routes.

Tables 5 to 15 show a distribution of construction costs by items for the system and for each route, subdivided by States. ​

Route No.	Route	Length in miles			Number of roads closed	Number of under passes	Number of over passes	Number of railroad under passes	Number of railroad over passes	Number of bridges	Number of tunnels	Number of accesses	Total construction cost by routes
		Total	2-lane pavement	4-lane pavement
1	Miami, Fla., to Madawaska, Maine	1,856.2	1,151.5	704.7	554	288	600	15	139	360		144	$464,886,080
2	Seattle, Wash., to Boston, Mass.	2,978.8	2,007.6	971.2	1,272	378	697	29	167	383	2	145	548,053,850
3	Laredo, Tex., to Chicago, Ill.	1,258.2	1,173.9	84.3	676	70	327	6	81	255	4	44	223,176,151
3 Mich.	Angola, Ind., to Port Huron, Mich.	174.7	54.7	120.0	123	12	100	3	13	37		16	48,363,666
4	Oakland, Calif., to Philadelphia, Pa.	2,816.8	2,373.1	443.7	1,148	232	442	19	148	496	11	105	466,339,733
4-A	Capital Branch	88.5	88.5		52	9	26	1	4	12		7	13,087,200
4 S	Whitewater, Calif., to Salt Lake City, Utah	593.6	593.6		60	10	37	2	13	259		12	58,039,418
4 N	Portland, Oreg., to Salt Lake City, Utah	770.7	770.7		183	40	72	2	22	93	1	31	104,810,492
5	San Ysidro, Calif., to Blaine, Wash.	1,406.4	604,0	802.4	377	253	275	6	64	333	8	84	371,527,504
6	Los Angeles, Calif., to Charleston, S.C.	2,392.3	2,172.7	219.6	753	139	382	1	101	683	1	80	337,870,583
Total		14,336.2	10,996.3	3,345.9	5,198	1,431	2,958	84	752	2,911	27	668	2,636,154,677

Route No.	Right- of-way, property damage, and relocation	Grading	Minor drainage	Surfacing	Clearing and grubbing	Curbs	Guardrails	Signs and markers	Fencing	Topsoil, seeding and planting	Bridges	Tunnels	Accesses	Total
1	$39,301,135	$75,698,021	$16,747,530	$91,773,392	$3,003,165	$1,798,035	$2,663,385	$1,882,900	$5,427,750	$7,799,480	$209,731,287		$9,060,00	$464,886,080
2	43,875,413	113,092,140	29,979,265	131,954,429	3,928,303	1,628,970	4,082,810	2,379,300	8,931,000	12,088,000	179,602,220	$7,572,000	8,940,000	548,053,850
3	13,588,986	37,850,560	11,522,130	45,498,033	3,439,182	1,638,259	1,233,270	1,255,210	3,765,430	5,691,720	95,040,371	1,003,000	3,650,000	223,176,151
3 Mich.	5,541,355	9,007,485	3,720,450	8,400,356	165,625	929,550	401,830	174,290	523,370	739,590	17,124,735		1,635,000	48.363,666
4	32,113,959	104,202,015	23,823,660	106,102,994	2,563,400	1,186,600	4,594,570	2,630,025	8,448,375	9,872,585	142,360,050	19,931,500	8,510,000	466,339,733
4-A	1,497,000	3,382,500	942,250	3,277,000	64,350	27,000	96,500	89,100	264,900	357,100	2,639,500		450,000	13,087,200
4 S	1,234,520	27,117,175	2,936,300	10,232,123	113,980		743,080	528,300	1,780,800	1,211,000	11,302,140		840,000	58,039,418
4 N	11,211,930	24,328,130	1,808,730	21,251,381	633,180		903,100	777,500	2,303,700	2,854,200	33,131,841	316,800	2,290,000	104,810,492
5	33,980,230	76,131,450	11,850,350	72,442,440	3,398,750	506,000	1,844,425	1,390,300	4,167,150	6,415,500	147,486,409	6,149,500	5,765,000	371,527,504
6	14,442,990	65,182,807	11,381,360	70,504,607	2,400,384	1,443,979	1,848,900	2,255,330	6,882,910	9,627,480	146,424,836		5,475,000	337,870,583
Total	196,787,518	535,992,283	114,712,025	564,436,785	17,710,319	9,158,393	18,411,870	13,362,255	42,495,385	56,656,655	984,843,389	34,972,800	46,615,000	[1]2,636,154,677

​

​

​

State	Right-of- way, property damage, and relocation	Grading	Minor drainage	Surfacing	Clearing and grubbing	Curbs	Guardrail	Signs and markers	Fencing	Topsoil, seeding, and planting	Bridges	Tunnels	Accesses	Total
Florida	$3,216,360	$3,672,000	$657,430	$14,735,000	$322,400		$178,655	$358,000	$1,074,000	$1,136,790	$16,239,440		$1,060,000	$42,650,750
Georgia	411,630	2,122,500	962,200	3,357,512	203,815			150,000	226,400	200,000	5,658,485		560,000	13,854,542
South Carolina	838,550	2,158,500	400,400	7,018,275	423,710	$236,270	236,720	200,200	600,600	800,800	14,267,290		700,00	27,882,865
North Carolina	756,850	4,467,250	609,850	4,317,420	237,900		562,350	153,100	459,300	765,500	5,599,440		560,000	18,488,960
Virginia	2,233,520	5,69,781	1,085,150	9,974,675	309,000	60,715	549,450	183,150	549,450	909,790	8,096,746		940,00	30,552,327
Maryland	3,248,000	11,655,400	1,639,500	6,718,900	149,700	120,900	39,000	95,200	324,800	549,900	20,813,900		450,000	45,805,200
Delaware	391,800	1,541,00	248,500	965,00	21,400	28,500	9,000	14,000	48,800	99,600	2,065,800		100,000	5,533,400
New Jersey	13,189,600	6,714,100	752,400	6,452,900	144,300	163,000	216,900	77,200	331,600	527,000	38,147,800		1,250,000	67,876,800
New York	4,844,000	795,090	978,500	2,064,240	48,800	58,100	73,200	24,400	73,200	163,000	36,115,260		250,000	45,487,790
Connecticut	3,564,750	12,712,500	5,113,500	7,309,440	432,000	918,000	270,000	108,000	270,000	648,000	24,148,400		600,000	56,094,590
Rhode Island	182,800	364,000	72,800	513,240	21,840	95,550	4,550	4,550	27,300	45,500	392,340			1,724,470
Massachusetts	1,735,700	4,725,600	380,700	4,933,000	109,200		49,100	77,700	233,100	332,800	10,020,880		700,000	23,297,780
New Hampshire	146,075	1,419,000	214,200	1,556,640	77,100		18,310	18,400	55,200	92,000	3,684,000		150,000	6,430,925
Maine	2,381,500	16,177,300	2,530,400	17,897,150	433,100	71,000	366,600	363,000	1,089,000	1,304,800	12,333,506		1,190,000	56,137,356
Total	39,301,135	75,698,021	16,747,530	91,773,392	3,003,165	1,798,035	2,663,385	1,882,900	5,427,750	7,799,480	209,731,287		9,060,000	464,886,080

​

State	Right-of- way, property damage, and relocation	Grading	Minor drainage	Surfacing	Clearing and grubbing	Curbs	Guardrail	Signs and markers	Fencing	Topsoil, seeding, and planting	Bridges	Tunnels	Accesses	Total
Washington	$1,508,003	$20,597,750	$2,595,550	$8,378,117	$633,205		$569,000	$277,400	$832,200	$832,200	$10,668,140	$7,392,000	$770,000	$55,053,610
Idaho	477,800	2,146,200	287,800	2,149,200	196,00		246,100	87,100	261,300	261,300	4,381,600		210,000	10,614,400
Montana	1,441,420	18,783,000	1,064,500	16,046,505	944,400		636,400	92,900	2,071,000	2,071,000	8,432,080	180,000	560,000	52,324,105
North Dakota	883,200	3,386,100	822,600	14,506,400	7,500		177,700	351,000	1,053,000	1,404,000	5,478,000		1,120,000	29,289,500
Minnesota	4,323,555	5,038,750	379,840	8,282,622	386,560		352,000	246,200	738,600	1,253,000	6,826,060		870,000	28,697,227
Wisconsin	3,142,125	6,496,810	1,086,985	9,540,275	273,413		337,760	294,400	883,300	1,255,200	10,057,300		1,010,000	34,357,478
Illinois	4,950,200	7,770,100	1,174,060	6,693,400	179,730	$709,420	126,650	94,800	284,400	578,500	22,915,00		480,00	45,946,260
Indiana	1,725,550	6,925,550	1,361,700	8,320,410	71,500	487,100	123,000	142,700	428,100	509,100	9,456,750		750,000	30,301,460
Ohio	9,877,000	10,701,750	5,619,250	14,292,500	264,750	142,750	150,000	242,000	727,000	1,176,000	29,181,500		800,000	73,174,500
Pennsylvania	1,051,000	1,381,000	962,000	3,712,000	50,000	35,000	96,000	48,000	144,000	166,000	9,347,200		200,000	17,912,200
New York	12,531,560	12,725,130	13,979,000	32,571,000	770,000	235,200	1,155,000	385,100	1,155,100	2,025,800	51,871,200		1,400,000	130,807,150
Massachusetts	1,964,000	17,040,000	666,000	7,472,000	241,200	19,500	113,200	117,700	353,100	555,900	10,983,300		770,00	40,295,960
Total	43,875,413	113,092,140	29,979,265	131,954,429	3,928,303	1,628,970	4,082,810	2,379,300	5,931,000	12,088,000	179,602,220	7,572,000	8,940,000	548,053,850

State	Right-of- way, property damage, and relocation	Grading	Minor drainage	Surfacing	Clearing and grubbing	Curbs	Guardrail	Signs and markers	Fencing	Topsoil, seeding, and planting	Bridges	Tunnels	Accesses	Total
Texas	$4,048,076	$8,513,301	$1,688,430	$15,232,455	$309,602	$482,599	$36,625	$486,760	$1,460,280	$2,562,570	$36,139,356		$1,150,000	$72,110,013
Oklahoma	3,203,450	8,513,310	1,478,600	9,457,000	231,600	161,000	216,900	268,500	805,300	1,122,800	17,782,726		630,000	44,240,376
Missouri	2,968,700	14,570,800	6,730,800	11,768,538	694,150	86,150	711,175	280,650	841,950	1,256,456	12,555,174	$1,003,000	1,070,000	54,537,537
Illinois	3,368,760	5,883,950	1,624,300	9,040,050	203,830	908,550	267,570	219,300	657,900	749,900	28,563,115		800,000	52,288,225
Total	13,588,986	37,850,560	11,522,130	45,498,033	1,439,182	1,638,259	1,233,270	1,255,210	3,765,330	5,691,720	95,040,371	1,003,000	3,650,000	223,176,151

​

State	Right-of- way, property damage, and relocation	Grading	Minor drainage	Surfacing	Clearing and grubbing	Curbs	Guardrail	Signs and markers	Fencing	Topsoil, seeding, and planting	Bridges	Tunnels	Accesses	Total
Indiana	$115,750	$477,750	$118,500	$535,800	$5,400	$10,000	$5,900	$9,500	$28,500	$28,500	$586,200		$200,000	$2,121,800
Ohio	390,000	549,000	251,500	645,000	10,500	6,000	3,000	9,000	27,500	41,000	521,000			2,453,500
Michigan	5,035,605	7,980,735	3,350,450	7,219,586	149,725	913,930	392,930	155,790	467,370	670,090	16,017,535		1,435,000	43,788,366
Total	5,541,355	9,007,485	3,720,450	8,400,386	165,625	929,550	401,830	174,290	523,370	739,590	17,124,735		1,635,000	48,363,666

State	Right-of- way, property damage, and relocation	Grading	Minor drainage	Surfacing	Clearing and grubbing	Curbs	Guardrail	Signs and markers	Fencing	Topsoil, seeding, and planting	Bridges	Tunnels	Accesses	Total
California	$4,635,150	$16,889,115	$4,535,700	$10,098,850	$583,800		$431,900	$215,450	$611,280	$572,640	$22,872,075		$890,000	$59,335,970
Nevada	634,230	12,381,950	1,563,600	6,502,300	40,00		239,250	200,000	1,199,200	800,00	2,285,590	$1,319,500	420,00	27,585,620
Utah	829,425	9,532,500	834,000	4,604,355	59,200		468,000	191,000	573,000	573,000	2,969,160		550,000	21,183,640
Wyoming	949,300	11,450,000	3,310,000	11,773,500	66,800		445,000	334,000	1,002,000	1,278,000	5,621,940		350,000	36,580,540
Colorado	421,230	4,554,250	1,574,100	7,780,029	19,200		503,420	216,100	648,300	1,080,500	6,311,700		490,000	23,586,849
Kansas	2,027,374	4,316,100	1,399,795	12,325,494	64,125		491,360	361,200	1,083,000	1,800,100	6,647,380		1,120,000	31,656,528
Missouri	2,134,700	2,808,450	1,490,800	8,772,420	448,700		206,900	207,400	622,200	632,500	9,128,680		490,000	26,942,750
Illinois	3,525,400	5,377,250	1,298,550	7,375,550	168,200	$554,300	283,450	209,400	627,900	624,500	15,186,479		630,000	35,860,979
Indiana	1,827,550	5,046,800	1,086,400	5,881,100	101,400	217,300	171,700	146,00	439,800	439,800	9,023,938		1,000,000	25,382,397
Ohio	9,097,500	12,686,00	3,795,250	9,369,750	285,000	174,000	684,750	241,000	719,500	1,107,500	19,897,874		1,020,000	59,078,124
West Virginia	180,000	867,600	53,380	382,580	6,955		18,840	5,865	17,595	23,045	2,719,400		50,000	4,325,300
Pennsylvania	5,852,000	18,263,000	5,882,085	21,247,057	720,000	241,000	650,000	302,000	904,000	941,000	39,695,834	18,612,000	1,500,000	114,808.976
Total	32,113,959	104,202,015	23,823,660	106,102,994	2,563,400	1,186,600	4,594,570	2,630,025	8,448,375	9,872,585	142,360,050	19,931,500	8,510,000	466,339,733

​

State	Right-of- way, property damage, and relocation	Grading	Minor drainage	Surfacing	Clearing and grubbing	Curbs	Guardrail	Signs and markers	Fencing	Topsoil, seeding, and planting	Bridges	Tunnels	Accesses	Total
Pennsylvania	$873,000	$756,500	$487,500	$1,663,000	$29,000	$17,000	$79,000	$43,000	$127,000	$127,000	$1,602,600		$140,000	$5,944,600
Maryland	624,000	2,626,000	454,750	1,614,000	35,350	10,000	17,500	46,100	137,000	280,100	1,086,900		310,00	7,142,600
Total	1,497,000	3,382,500	942,250	3,277,000	64,350	27,000	96,500	89,100	264,000	357,100	2,639,500		450,000	13,087,200

State	Right-of- way, property damage, and relocation	Grading	Minor drainage	Surfacing	Clearing and grubbing	Curbs	Guardrail	Signs and markers	Fencing	Topsoil, seeding, and planting	Bridges	Tunnels	Accesses	Total
California	$47,500	$4,659,700	$1,464,000	$2,166,300			$388,300	$146,400	$439,200		$4,836,600		$140,000	$14,288,000
Nevada	145,290	2,477,400	366,000	1,805,500	$12,200		34,100	61,000	366,000	$244,000	686,320		14,000	6,337,810
Arizona	1,565	683,200	25,800	126,400	8,600		18,920	4,300	25,800	17,200	91,200			1,002,985
Utah	1,040,165	19,296,875	1,080,500	6,133,923	93,180		301,760	316,600	949,800	949,800	949,800	5,688,020		36,410,623
Total	1,234,520	27,117,175	2,936,300	10,232,123	113,980		743,080	528,300	1,780,800	1,211,000	11,302,140		840,000	58,039,418

State	Right-of- way, property damage, and relocation	Grading	Minor drainage	Surfacing	Clearing and grubbing	Curbs	Guardrail	Signs and markers	Fencing	Topsoil, seeding, and planting	Bridges	Tunnels	Accesses	Total
Oregon	$9,625,900	$18,650,780	$679,250	$13,444,000	$473,600		$264,300	$381,500	$1,115,700	$1,666,200	$23,936,461	$316,800	$1,260,000	$71,814,491
Idaho	953,500	4,173,600	899,600	6,726,700	136,500		584,900	272,600	817,800	817,800	7,027,700		770,000	23,180,700
Utah	632,530	1,503,750	229,880	4,080,681	23,080		53,900	123,400	370,200	370,200	2,167,680		260,000	9,815,301
Total	11,211,930	24,328,180	1,808,730	24,251,381	633,180		903,100	777,500	2,303,7800	2,854,200	33,131,841	316,800	2,290,000	104,810,492

​

State	Right-of- way, property damage, and relocation	Grading	Minor drainage	Surfacing	Clearing and grubbing	Curbs	Guardrail	Signs and markers	Fencing	Topsoil, seeding, and planting	Bridges	Tunnels	Accesses	Total
California	$13,661,690	$41,790,000	$6,220,000	$39,125,200	$728,800		$1,164,925	$806,700	$2,417,850	$3,392,200	$57,384,591	$2,189,500	$2,915,000	$171,796,456
Oregon	16,111,500	21,745,800	1,332,350	15,235,050	883,600	$287,000	362,500	315,200	1,034,100	1,833,800	52,231,236	3,960,000	1,420,000	116,782,136
Washington	4,207,040	12,595,650	4,298,000	18,082,190	1,786,350	219,000	317,000	238,400	715,200	1,189,500	37,870,582		1,430,000	82,948,912
Total	33,980,230	76,131,450	11,850,350	72,442,440	3,398,750	506,000	1,844,425	1,390,300	4,167,150	6,415,500	147,480,409	6,149,500	5,765,000	371,527,504

State	Right-of- way, property damage, and relocation	Grading	Minor drainage	Surfacing	Clearing and grubbing	Curbs	Guardrail	Signs and markers	Fencing	Topsoil, seeding, and planting	Bridges	Tunnels	Accesses	Total
California	$1,780,390	$9,849,265	$2,110,750	$8,670,200			$410,800	$222,700	$688,100	$478,800	$14,683,260		$520,000	$39,394,265
Arizona	1,855,370	8,334,800	2,070,200	5,690,470			559,100	235,760	825,000	1,247,000	8,535,380		420,000	29,782,680
New  Mexico	1,855,370	1,877,000	546,400	4,911,300	$77,400	$275,000	108,000	154,800	464,400	476,700	1,744,300		215,000	17,232,580
Texas	5,537,015	26,582,352	3,313,200	26,938,000	759,014	992,458	162,730	777,020	2,331,060	4,155,630	61,018,876		1,490,000	134,057,355
Louisiana	595,070	3.035,650	817,900	5,840,403	544,650	92,821		182,550	547,650	547,650	11,361,290		350,000	23,916,234
Mississippi	1,181,480	2,834,020	353,560	3,543,270	274,500		140,170	152,400	457,200	609,600	10,526,300		350,000	20,830,774
Alabama	1,014,825	6,100,720	1,394,650	5,036,089	108,120		144,400	210,100	629,500	629,500	13,802,870		700,000	20,830,774
Georgia	1,712,630	5,155,000	541,000	5,653,500	401,000	3,000	213,000	200,500	601,500	1,004,00	20,236,900		840,000	36,592,530
South Carolina	413,330	1,414,000	233,200	4,212,375	175,700	80,700	80,700	119,500	358,500	478,000	4,515,660		560,000	12,641,665
Total	14,442,990	65,182,807	11,381,360	70,504,607	2,400.384	1,443,979	1,848,900	2,255,330	6,892,910	9,627,480	146,424,830		5,475,000	337,870,593

​Finally, table 16 gives the construction costs of each of the 75 sections of the entire mileage of selected routes, traffic facts for which are recorded in table 2. The various sections are arranged in table 16 in the descending order of average cost peer mile, and the descending order of traffic importance is indicated by the serial numbers in column 2 of the table.

Section			Number in order of cost per mile	Number in order of traffic volume	Route	Construction cost	10 percent engineering contingency and interest during construction	Total costs each section	Average cost per mile each section
From—	To—	Length
		Miles
Jersey City, N.J.	New Haven, Conn.	65.6	1	1	1	$69,083,460	$6,908,346	$75,991,806	$1,158,412
Junction, Route 4, Pa.	Jersey City, N.J.	106.8	2	2	1	75,458,300	7,545,830	83,004,130	77,192
Junction, Route 6, Calif.	San Fernando, Calif.	44.8	3	3	5	23,703,930	2,370,393	26,074,323	582,016
Baltimore, Md.	Junction, Route 4, Md.	76.2	4	7	1	35,874,400	3,587,440	39,461,840	517,872
New Haven, Conn.	Junction, Route 2, Mass.	99.8	5	10	1	46,407,020	4,640,702	51,047,722	511,500
Portland, Oreg.	Junction, Route 2, Wash.	146.7	6	22	5	64,155,201	6,415,201	70,570,721	481,055
Salem, Oreg.	Portland, Oreg.	56.9	7	14	5	23,502,849	2,350,285	25,853,134	454,361
Pittsburgh, Pa.	Carlisle, Pa.	166.6	8	19	4	64,806,102	6,480,610	71,286,712	427,891
Junction, Route 2, Wash.	Canadian boundary	124.7	9	25	5	47,631,362	4,763,136	52,394,498	420,164
Albany, N.Y.	Junction, Route 1, Mass.	147.2	10	17	2	54,495,650	5,449,565	59,945,215	407,237
Washington, D.C.	Balitmore, Md.	39.3	11	4	1	14,105,600	1,410,560	15,516,160	394,873
Seattle, Wash.	Ellensburg, Wash.	90.0	12	53	2	29,315,255	2,931,526	32,246,781	358,298
Carlisle, Pa.	Junction, Route 1, Pa.	94.8	13	13	4	33,181,874	3,318,187	36,500,061	385,022
Cleveland, Ohio	Buffalo, N.Y.	220.7	14	18	2	77,012,745	7,701,274	84,714,019	383,842
Perrysburg, Ohio	Cleveland, Ohio	79.3	15	20	2	27,136,750	2,713,675	29,850,425	376,424
Oakland, Calif.	Auburn, Calif.	110.0	16	16	4	38,279,100	3,827,910	42,107,010	373,700
Buffalo, N.Y.	Albany, N.Y.	287.6	17	11	2	91,696,915	9,169,691	100,866,606	350,718
San Ysidro, Calif.	Junction 6, Calif.	124.4	18	8	5	38,175,881	3,817,588	41,993,469	337,568
Columbus, Ohio	Pittsburgh, Pa.	195.0	19	32	4	58,448,516	5,844,852	64,293,368	329,710
Junction, Route 2, Mass.	Portland, Maine	133.9	20	5	1	39,086,265	3,909,625	42,994,880	321,097
Junction, Route 2, Ind.	Detroit, Mich.	102.2	21	15	[1]3	29,801,059	2,980,106	32,781,165	320,755
Junction, Route 3, Ill.	Junction 3, Mich.–Ind.	156.9	22	9	2	43,446,360	4,344,636	47,790,996	304,595
Junction 5, Calif.	Whitewater, Calif.	91.0	23	6	6	25,036,495	2,503,650	27,540,145	302,639
Detroit, Mich.	Port Huron, Mich.	72.5	24	29	[1]3	18,562,607	1,856,261	20,418,868	281,640
Tracy, Calif.	Junction, Route 4, Calif.	69.1	25	23	5	17,125,370	1,712,537	18,837,907	272,618
Ashland, Oreg.	Roseburg, Oreg.	122.9	26	47	5	30,370,800	3,037,080	33,407,880	271,830
Junction, Route 3, Tex.	Shreveport, La.	190.4	27	27	6	46,775,118	4,677,512	51,452,630	270,234
Portland, Oreg.	Boardman, Oreg.	[2]163.4	28	52	4N	39,832,691	3,983,269	43,815,960	268,152
Junction, Route 4, Ill.	Junction, Route 2, Ill.	155.5	29	33	3	37,131,697	3,713,170	40,844,867	262,668
Richmond, Va.	Washington, D.C.	108.3	30	12	1	25,609,005	2,560,900	28,109,905	260,110
Redding, Calif.	Ashland, Oreg.	138.2	31	59	5	31,735,255	3,173,526	34,908,781	252,592 ​
Indianapolis, Ind.	Columbus, Ohio	156.6	32	28	4	35,796,228	3,579,623	39,375,851	251,442
St. Louis, Mo.	Junction, Route 4, Ill.	88.88	33	38	3	19,529,208	1,952,921	21,482,129	214,916
Springfield, Mo.	St. Louis, Mo.	165.2	34	43	3	36,045,892	3,604,589	39,650,481	240,015
Auburn, Calif.	Reno, Nev.	106,5	35	46	4	22,439,290	2,243,920	24,683,219	231,767
Roseburg, Oreg.	Salem, Oreg.	133.3	36	39	5	27,240,636	2,724,064	29,964,700	224,791
Minneapolis, Minn.	Junction, Route 3, Ill.	392.6	37	26	2	73,009,823	7,300,982	80,310,805	204,561
Atlanta, Ga.	Augusta, Ga.	153.2	38	72	6	28,108,255	2,810,826	30,919,081	201,822
Portland, Maine	Bangor, Maine	121.3	39	30	1	22,203,316	2,220,332	24,423,648	201,349
San Fernando, Calif.	Tracy, Calif.	[3]291.7	40	21	5	51,864,880	5,186,488	57,051,386	195,582
Junction, Route 3, Mich.–Ind.	Perrysburg, Ohio	69.9	41	40	2	12,044,750	1,204,475	13,249,225	189,545
Junction, Route 6, Tex.	Tulsa, Okla.	270.5	42	33	3	46,561,539	4,656,154	51,217,613	189,345
San Antonio, Tex.	Junction, Route 6, Tex.	250,7	43	36	3	38,987,901	3,898,790	42,886,691	171,968
Junction, Route 3, Ill.	Indianapolis, Ind.	203,7	44	37	4	31,647,470	3,164,747	34,812,217	170,899
Tulsa, Okla.	Springfield, Mo.	171.3	45	48	3	26,347,441	2,634,744	28,982,185	169,190
Odessa, Tex.	Junction, Route 3, Tex.	337,9	46	31	6	50,921,061	5,092,106	56,013,167	165,788
Junction, Route 4, Pa.	Junction, Route 1, Md.	88.5	47	51	4-A	13,087,200	1,308,720	14,395,920	162,666
El Paso, Tex.	Odessa, Tex.	245,2	48	56	6	35,798,286	3,579,829	39,178,115	160,596
Jacksonville, Fla.	Junction, Route 6, S.C.	219.3	49	49	1	31,732,987	3,173,299	34,906,286	159,171
Boardman, Oreg.	Boise, Idaho	253.1	50	63	4-N	36,334,400	3,633,440	39,967,840	157,913
Shreveport, La.	Vicksburg, Miss.	168.8	51	60	6	24,137,084	2,413,708	26,550,792	157,291
Birmingham, Ala.	Atlanta, Ga.	141,2	52	64	6	20,178,426	2,017,843	22,196,269	157,197
St. Joseph, Mo.	Junction, Route 3, Ill.	275.7	53	41	4	39,238,016	3,923,802	43,161,818	156,554
Vicksburg, Miss.	Birmingham, Ala.	270,5	54	67	6	37,264,038	3,726,404	40,990,442	151,536
Whitewater, Calif.	Indio, Calif.	32.7	55	24	6	4,417,710	441,771	4,859,481	148,608
Junction, Route 6, S.C.	Richmond, Va.	362.6	56	50	1	48,077,192	4,807,719	52,884,911	145,849
Ellensburg, Wash.	Spokane, Wash.	145.9	57	74	2	19,061,250	1,906,125	20,967,375	143,711
Salt Lake City, Utah	Greeley, Colo.	463.3	58	66	4	56,632,098	5,663,210	62,295,308	134,460
Bangor, Maine	Canadian boundary	196.6	59	68	1	23,595,360	2,359,536	25,954,896	132,019
Mexican boundary	San Antonio, Tex.	156.2	60	69	3	18,572,473	1,857,247	20,429,720	130,792
Augusta, Ga.	Charleston, S.C.	116.3	61	70	6	12,293,750	1,229,375	13,523,125	116,278
Brigham, Utah	Salt Lake City, Utah	52.3	62	35	4-N	5,474,940	547,494	6,022,434	115,152
Junction, Route 4, Calif.	Redding, Calif.	153.7	63	44	5	16,021,340	1,602,134	17,623,474	114,662
Miami, Fla.	Jacksonville, Fla.	326.5	64	34	1	33,653,185	3,365,318	37,018,503	113,350
Las Vegas, Nev.	Salt Lake City, Utah	407.5	65	65	4-S	41,854,303	4,185,430	45,039,733	112,981
Fargo, N. Dak.	Minneapolis, Minn.	219.1	66	45	2	22,213,242	2,221,324	24,434,566	111,522
Junction, Route 6, Calif.	Ludlow, Calif.	69.1	67	42	4-S	6,642,760	664,276	7,307,036	105,746
Greeley, Colo.	St. Joseph, Mo.	529.7	68	54	4	49,445,719	4,944,572	54,390,291	102,681
Indio, Calif.	Phoenix, Ariz.	254.0	69	62	6	23,393,120	2,339,312	25,732,432	101,309
Boise, Idaho	Rupert, Idaho	182.2	70	57	4-N	16,264,000	1,626,400	17,890,400	98,191
Spokane, Wash.	Fargo, N. Dak.	1,169.6	71	75	2	98,621,110	9,862,111	108,483,221	92,752
Ludlow, Calif.	Las Vegas, Nev.	117.0	72	58	4-S	9,542,355	954,235	10,496,590	89,714
Phoenix, Ariz.	El Paso, Tex.	391.1	73	61	6	29,547,240	2,954,724	32,501,904	83,104
Reno, Nev.	Salt Lake City, Utah	514.9	74	73	3	36,425,320	3,642,532	40,067,852	77,817
Rupert, Idaho	Brigham, Utah	119.7	75	71	4-N	6,904,461	690,446	7,594,907	63,450
Total		14,336.2				2,636,152,677	263,615,486	2,899,770,145

​

It is concluded that:

The system of roads selected, conforming closely to the direction of section 18 of the act of June 8, 1938, vs feasible of construction at approximately the cost indicated. Moreover, it is probable that no reasonable change in the precise location of a system of approximately the same extent would materially affect the indicated average cost per mile.

It is assumed that construction on the selected routes, if it is undertaken, will be completed one-half by January 1, 1944, and the remaining half by January 1, 1946. Without any significant error it can be assumed that the whole system would come into use on January 1, 1945, with collection of revenues from that date on the entire system.

Traffic estimates have been projected to 1960, and cannot, with reasonable assurance of accuracy, be projected beyond that year. From January 1, 1945, to December 31, 1960, is a period of 16 years, and it is for that period only that revenues can be estimated with substantial accuracy.

The roads, as built, would have a probable average service life, as a whole, extending far beyond this 16-year period. Some elements of the construction obviously have longer lives than others, but all elements, with the possible exception of some very minor ones, such as signs, fencing, etc., should last well beyond the 16-year period.

For example, the probable average service life of the surfaces or pavements may be assumed to be at least 30 years. This life period reflects experience tables of similar past construction, together with the more favorable quality of the proposed construction. The estimated construction cost of the pavements, including curbs and accesses is $682,231,200, which is 23.5 percent of the $2,899,770,000, estimated as the total cost of all construction and right-of-way. The average life of the graded roadbed and right-of-way may be assumed to be at least 100 years. Only a general change in the geometric design of the roads as built could materially affect the accuracy of this assumption.^[1] The estimated cost of right-of-way, clearing and grubbing, grading, minor drainage, topsoil, seeding, and planting, totalling $1,014,044,700, represents 35 percent of the estimated total cost. The average life of major structures, such as bridges and tunnels, similarly may be estimated conservatively at 60 years, although for the modern types of structure proposed such a life period is probably short. Bridges and tunnels are estimated to cost $1,121,797,800, which is about 38.5 percent of the estimated total cost. Other miscellaneous items of the construction, such as guardrails, signs and markers, and fences are generally of shorter life than the three major items above mentioned Their estimated cost, $81,606,400, is only 3 percent of the total estimated cost. If these elements are assumed to have an average service life of only 10 years, the probable composite average life of all elements of the routes as constructed, including their rights-of-way, would be:

---

​

As previously stated, this estimated average service life of the selected roads as a whole materially exceeds the 16-year period for which it is reasonable to estimate revenues. It also is about twice as long as the 30-year period fixed for retirement of the debt.

Annual debt service charge.—Retirement of the debt in 30 years will, it is estimated, entail an annual debt service charge of 4.84 percent of the total estimated cost. This 4.84 percent rate covers annual interest on the loan at 2.6 percent and provides for retirement in 30 years by an added 2.24 percent. The 2.6 percent interest rate on the loan is approximately the composite rate of United States Treasury borrowing charges as of January 1939. It reflects the rates on both short-term and long-term Treasury borrowings. It therefore can be assumed that with this rate borrowing for the proposed road construction may either be of short- or long-term character. The retirement annuity of 2.24 percent to be added to the interest rate will retire or amortize the total cost in about 30 years if compounded at 2.6 percent annually. Thirty years is a common term for highway loans.^[1] It is also slightly longer than the term of any outstanding United States borrowings. The assumed annual debt service cost, on the basis of the United States Treasury borrowing rate, therefore, is 4.84 percent of $2,899,770,000 or about $140,401,000 annually. The corresponding annual debt service on an average construction cost of $202,270 per mile is approximately $9,790.

The annual debt service is the largest item of annual cost. It could be decreased by extending the term of the loan. The total cost of the loan, on the other hand, increases directly as the term increases. The 30-year loan, at 2.6 percent annual interest rate as indicated, reflects the United States Treasury rate and the longest term of Federal borrowing.^[2]

Annual costs of maintenance and minor reconstruction.—The annual costs of maintenance and minor reconstruction are entailed principally by the strict maintenance of the surfaced roadway and operating facilities and the drainage, and other structures, plus the maintenance of a good appearance of the right-of-way, together with any necessary reconstruction during the interval 1945–60. These annual costs vary from section to section. They are estimated to amount to $18,637,000 and are equivalent to approximately $1,300 per year for the average mile during the period 1945–60.

Annual operating cost.—The assumed annual operating cost consists principally of the collection and management of the tolls, the operation of a sufficient traffic police force, and the removal of snow. These items vary from section to section, but combined they are estimated at a total cost of $25,016,000, or approximately $1,740 per average mile per year for the period 1945-60.

Total annual cost.—The estimated total annual cost which is the sum of debt service, maintenance and minor reconstruction, and operating costs, is $184,054,000, or an average of approximately $12,840 per mile per year. This total cost figure is shown, as of the year 1960, in table 17, which table also shows the corresponding accumulated cost of $2,944,861,936 for the period 1945-60.

---

​

Description		Number in order of revenue as a percentage of cost	Number in order of traffic volume	Route	For the year 1960							For the period 1945–60
From—	To—				Length	By individual sections				Total by accumulated sections		Total costs for each section	Total costs accumulated by sections
						Debt service[1]	Maintenance and operation	Total costs	Average cost per mile	Length	Costs
					Miles					Miles
Jersey City, N.J.	New Haven, Conn.	1	1	1	65.6	$3,679,371	$686,800	$4,366,171	$66,557	65.6	$4,366,171	$69,858,736	$69,858,768
Junction, Route 4, Pa.	Jersey City, N.J.	2	2	1	10.8	4,018,894	1,160,400	5,179,294	48,495	172.4	9,545,465	82,868,794	152,727,440
Junction, Route 5, Calif.	Whitewater, Calif.	3	6	6	91.0	1,333,439	437,000	1,770,939	19,461	263.4	11,316,404	28,335,024	181,062,464
Washington, D.C.	Baltimore, Md.	4	4	1	39.3	751,261	218,250	969,511	24,669	302.7	12,285,915	15,512,176	196,574,640
Junction, Route 2, Mass.	Portland, Maine	5	4	1	133.9	2,081,726	943,650	3,025,376	22,594	436.6	15,311,291	48,406,016	244,980,656
Miami, Fla.	Jacksonville, Fla.	6	34	1	326.5	1,792,362	689,750	2,481,112	7,602	763.1	17,793,403	39,713,792	284,694,448
Baltimore, Md.	Junction, Route 4, Pa.	7	7	1	76.2	1,910,663	430,500	2,341,163	30,724	839.3	20,134,566	37,458,608	322,153,056
Richmond, Va.	Washington, D.C.	8	12	1	108.3	1,303,931	470,750	1,834,681	16,941	947.6	21,969,247	29,354,895	351,507,952
San Ysidro, Calif.	Junction, Route 6, Calif.	9	8	5	124.4	2,033,240	511,000	2,544,240	20,452	1,072.0	24,513,487	40,707,840	392,215,792
Whitewater, Calif.	Indio, Calif.	10	24	6	32.7	235,286	129,750	365.036	11,163	1,104.7	24,878,523	5,840,576	398,056,368
Junction, Route 3, Ill.	Junction, Route 3, Mich.–Ind.	11	9	2	156.9	2,313,944	969,150	3,283,094	20,925	1,261.6	28,161,617	52,529,504	450,585,872
Brigham, Utah	Salt Lake City, Utah	12	35	4-N	52.3	291,594	128,450	420,044	8,031	1,313.9	28,581,661	6,720,704	457,306,576
Odessa, Tex.	Junction, Route 3, Tex.	13	31	6	337.0	2,712,046	611,850	3,323,896	9,837	1,651.8	31,905,557	53,182,336	510,488,912
Junction, Route 6, Calif.	San Fernando, Calif.	14	3	5	44.8	1,262,467	442,00	1,704,467	38,046	1,696.6	33,610,024	27,271,472	537,760,384
Buffalo, N.Y.	Albany, N.Y.	15	11	2	287.6	4,883,759	1,581,600	7,465,259	22,480	1,984.2	40,075,383	103,445,744	641,206,128
Junction, Route 16, Calif.	Ludlow, Calif.	16	42	4-S	69.1	353,792	133,650	487,442	7,054	2,53.3	40,562,825	7,799,072	649,005,200
San Fernando, Calif.	Tracy, Calif.	17	21	5	291.7	2,762,313	898,500	3,660,813	12,550	2,345.0	44,223,638	58,573,008	707,578,208
Minneapolis, Minn.	Junction, Route 3, Ill.	18	26	2	392.6	3,888,489	1,431,500	5,319,989	13,551	2,737.6	49,543,627	85,119,824	792,698,032
Junction, Route 4, Calif.	Redding, Calif.	19	44	5	153.7	853,293	290,550	1,143,843	7,442	2,891.3	50,687,470	18,301,488	810,999,520
San Antonio, Tex.	Junction, Route 6, Tex.	20	36	3	250.7	2,076,488	481,050	2,557,538	10,202	3,142.0	53,245,008	40,920,608	851,920,128
Portland, Maine	Bangor, Maine	21	30	1	121.3	1,182,544	363,250	1,545,794	12,7444	3,263.3	54,790,802	24,732,704	876,652,832
St. Joseph, Mo.	Junction, Route 3, Ill.	22	41	4	275.7	2,089,809	563,550	2,653,359	9,624	3,639.0	57,444,161	42,453,744	919,106,576 ​
Junction, Route 3, Ill.	Indianapolis, Ind.	23	37	4	203.7	1,685,538	455,550	2,141,088	10,511	3,742.7	59,585,249	34,257,408	953,363,984
Carlisle, Pa.	Junction, Route 1, Pa.	24	13	4	94.8	1,767,260	392,000	2,159,260	22,777	3,837.5	61,744,509	34,548,160	987,912,144
Junction, Route 2, Ind.	Detroit, Mich.	25	15	[2]3	102.2	1,586,198	617,700	2,204,898	21,574	3,939.7	63,949,407	35,278,368	1,023,190,512
Tracy, Calif.	Junction, Route 4, Calif.	26	23	5	69.1	912,094	252,750	1,164,844	16,857	4,008.8	65,114,251	18,637,504	1,041,828,016
Junction, Route 3, Tex.	Shreveport, La.	27	27	6	190.4	2,491,233	447,600	2.938,833	15,435	4,199.2	68,053,084	47,021,328	1,088,849,344
Ludlow, Calif.	Las Vegas, Nev.	28	58	4-S	117.0	508,224	190,500	698,724	5,972	4,316.2	68,757,808	11,179,584	1,100,028,928
Fargo, N. Dak.	Minneapolis, Minn.	29	45	2	219.1	1,183,073	697,750	1,880,823	8,584	4,535.3	70,632,631	30,093,168	1,130,122,096
New Haven, Conn.	Junction, Route 2, Mass.	30	10	1	99.8	2,471,629	524,400	2,996,029	30,020	4,635.1	73,628,660	47,936,464	1,178,058,560
Greeley, Colo.	St. Joseph, Mo.	31	54	4	529.7	2,633,469	1,359,400	3,992,869	7,538	5,164.8	77,621,529	63,885,904	1,241,944,464
Indianapolis, Ind.	Columbus, Ohio	32	28	4	156.6	1,906,500	468,200	2,374,700	15,164	5,321.4	79,996,229	37,995,200	1,279,939,664
Phoenix, Ariz.	El Paso, Tex.	33	61	6	391.1	1,573,680	736,650	2,310,330	5,907	5,712.5	82,306,559	36,965,280	1,316,904,944
Cleveland, Ohio	Buffalo, N.Y.	34	18	2	220.7	4,101,683	962,100	5,063,783	22,944	5,933.2	87,370,342	81,020,528	1,397,925,472
Oakland, Calif.	Auburn, Calif.	35	16	4	110.0	2,038,737	530,00	2,568,737	23,352	6,043.2	89,939,079	41,099,792	1,439,025,264
Boise, Idaho	Rupert, Idaho	36	57	4-N	182.2	866,217	484,400	1,350,617	7,413	6,225.4	91,280,696	21,609,872	1,460,635,136
Shreveport, La.	Vicksburg, Miss.	37	60	6	168.8	1,285,536	343,200	1,628,736	9,649	6,394,2	92,918,432	26,059,776	1,486,694,912
Salem, Oreg.	Portland, Oreg.	38	14	5	56.9	1,251,757	292,250	1,544,007	27,135	6,451.1	94,462,439	24,704,112	1,511,399,024
Junction, Route 4, Ill.	Junction, Route 2, Ill.	39	14	5	155.5	1,977,627	451,000	2,428,627	15,618	6,606.6	96,891,066	38,858,032	1,550,257,056
Perrysburg, Ohio	Cleveland, Ohio	40	20	2	79.3	1,445,298	357,900	1,803,198	22,739	6,685.9	98,694,264	28,854,168	1,579,108,224
Junction, Route 6, S.C.	Richmond, Va.	41	50	1	362.6	2,560,582	843,900	3,404,482	9,389	7,048.5	102,098,746	54,471,712	1,633,579,936
St. Louis, Mo.	Junction, Route 4, Ill.	42	38	3	88.8	1,040,122	258,200	1,278,322	14,396	7,137.3	103,377,068	20,453,152	1,654,033,088
Albany, N.Y.	Junction, Route 1, Mass.	43	17	2	147.2	2,902,427	841,600	3,744,027	25,435	7,284.5	107,121,095	59,904,432	1,713,937,520
Pittsburgh, Pa.	Carlisle, Pa.	44	19	4	166.6	3,451,560	606,500	4,058,060	24,358	7,451.1	111,179,155	64,928,960	1,778,866,480
Tulsa, Okla.	Springfield, Mo.	45	48	3	171.3	1,403,259	346,950	1,750,209	10,217	7,622.4	112,929,364	28,003,344	1,806,869,824
Junction, Route 3, Mich.–Ind.	Perrysburg, Ohio	46	40	2	69.9	641,501	219,750	861,251	12,821	7,692.3	113,790,615	13,780,016	1,820,649,840
Jacksonville, Fla.	Junction, Route 6, S.C.	47	49	1	219.3	1,609,093	523,950	2,214,043	10,096	7,911.6	116,004,658	35,424,688	1,856,074,528
Detroit, Mich.	Port Huron, Mich.	48	29	[2]3	72.5	988,641	321,250	1,309,891	18,067	7,984.1	117,314,549	20,958,256	1,877,032,784
Springfield, Mo.	St. Louis, Mo.	49	43	3	165.2	1,919,797	357,800	2,277,597	13,787	8,149.3	119,592,146	36,441,552	1,913,474,336
Junction, Route 4, Pa.	Junction, Route 1, Mo.	50	51	4-A	88.5	697,022	207,750	904,772	10,223	8,237.8	120,496,918	14,476,352	1,927,950,688
Roseburg, Oreg.	Salem, Oreg.	51	39	5	133.3	1,450,831	356,600	1,807,431	13,559	8,371.1	122,304,349	28,918,896	1,956,869,584
El Paso, Tex.	Odessa, Tex.	52	56	6	245.2	1,906,610	442,800	2,349,410	9,582	8,616.3	124,653,759	37,590,560	1,994,460,144
Indio, Calif.	Phoenix, Ariz.	53	62	6	254.0	1,245,913	426,00	1,671,913	6,582	8,870.3	126,325,672	26,750,608	2,021,210,752
Columbus, Ohio	Pittsburgh, Pa.	54	22	4	195.0	3,112,956	630,000	3,742,956	19,195	9,065.3	130,068,628	59,887,296	2,081,098,048
Portland, Oreg.	Junction, Route 2, Wash.	55	22	5	146.7	3,416,893	716,750	4,133,643	28,178	9,212.0	134,202,271	66,138,288	2,147,236,336
Junction, Route 2, Wash.	Canadian boundary	56	25	5	124.7	2,536,837	519,400	3,056,237	24,509	9,336.7	137,258,508	48,899,792	2,196,136,128 ​
Junction, Route 6, Tex.	Tulsa, Okla.	57	55	3	270.5	2,479,88	555,750	3,035,609	11,222	9,607.2	140,294,116	48,569,728	2,224,705,856
Auburn, Calif.	Reno, Nev.	58	46	4	106.5	1,195,112	374,500	1,569,612	14,738	9,713.7	141,863,728	25,113,792	2,289,819,648
Ashland, Oreg.	Roseburg, Oreg.	59	47	5	122.9	1,617,543	413,700	2,031,243	16,528	9,836.6	143,894,971	32,499,888	2,302,319,536
Las Vegas, Nev.	Salt Lake City, Utah	60	65	4-S	407.5	2,229,152	965,000	3,194,152	7,838	10,244.1	147,089,123	51,106,432	2,353,425,968
Birmingham, Ala.	Atlanta, Ga.	61	64	6	141.2	1,074,699	346,800	1,421,499	10,067	10,385.3	148,510,622	22,743,984	2,376,169,952
Boardman, Oreg.	Boise, Idaho	62	63	4-N	253.1	1,935,163	767,750	2,702,913	10,679	10,638.4	151,213,535	43,246,608	2,419,416,560
Salt Lake City, Utah	Greeley, Colo.	63	66	4	463.3	3,016,214	1,293,250	4,309,464	9,302	11,101.7	155,532,999	68,951,424	2,488,367,984
Rupert, Idaho	Brigham, Utah	64	71	4-N	119.7	367,730	314,250	681,980	5,697	11,221.4	156,204,979	10,911,680	2,499,279,664
Redding, Calif.	Ashland, Oreg.	65	59	5	138.2	1,690,213	336,400	2,026,613	14,664	11,359.6	158,231,592	32,425,808	2,531,705,472
Seattle, Wash.	Ellensburg, Wash.	66	53	2	90.0	1,561,325	285,000	1,846,325	20,515	11,449.6	160,077,917	29,541,200	2,561,246,672
Vicksburg, Miss.	Birmingham, Ala.	67	67	6	270.5	1,984,675	555,750	2,540,425	9.392	11,720.1	162,618,342	40,646,800	2,601,893,472
Bangor, Maine	Canadian boundary	68	68	1	196.6	1,256,684	581,500	1,838,184	9,350	11,916.7	164,456,526	29,410,944	2,631,304,416
Portland, Oreg.	Boardman, Oreg.	69	52	4-N	163.4	2,121,481	343,000	2,464,481	15,083	12,080.1	166,921,007	30,431,696	2,670,736,112
Mexican boundary	San Antonio, Tex.	70	69	3	156.2	989,166	279,300	1,268,466	8,121	12,236.3	168,189,473	20,295,456	2,691,031,568
Augusta, Ga.	Charleston, S.C.	71	70	6	116.3	654,763	294,450	949,213	8,162	12,352.6	169,138,686	15,187,408	2,706,218,976
Reno, Nev.	Salt Lake City, Utah	72	73	4	514.9	1,940,005	1,149,800	3,089,805	6,001	12,867.5	172,228,491	49,436,880	2,755,655,856
Spokane, Wash.	Fargo, N. Dak.	73	75	2	1,169.6	5,252,541	3,344,000	8,596,541	7,350	14,037.1	180,825,032	137,544,656	2,893,200,512
Ellensburg, Wash.	Spokane, Wash.	74	74	2	145.9	1,015,199	315,800	1,366,999	9,369	14,183.0	182,192,031	21,871,984	2,915,072,496
Atlanta, Ga.	Augusta, Ga.	75	72	6	153.2	1,497,040	364,800	1,861,840	12,153	14,336.2	184,053,871	29,789,440	2,944,861,939
Total					14,336.2	140,404,071	43,652,800	184,053,871	12,838			2,944,861,936

​

The annual cost would continue after 1960 at approximately the same average annual rate; and, until 1975, when the indebtedness would be completely retired, it would include the regular annual payment for debt service. The total of these payments over the 30-year period would be $4,212,032,130; and the difference between this amount and the $2,899,770,145 borrowed, or $1,312,261,985, represents the total cost of borrowing. This $1,312,261,985 of direct finance cost is 45.3 percent of the net cost of construction.

With payment of the sixteenth annual installment of the 4.84 percent debt service charge at the end of the year 1960, approximately 44 percent of the debt would have been retired. On the basis of the composite service life of 65.5 years, as previously estimated for all elements of the facilities, and assuming a straight-line depreciation, the accumulated depreciation by 1960 would be less than 25 percent. Comparison of the residual value of more than 75 percent with the unretired 56 percent of the debt, indicates adequate security for the refinancing of any necessary reconstruction.

For the entire system and 75 constituent sections, what is believed to be the maximum possible estimate of toll-paying traffic that would have used the selected routes in 1937 is shown in table 2. (See p. 24.) The total for all routes is 5,823,745 vehicle-miles per day, or 2,125,666,925 vehicle-miles per year. These estimates are based on actual traffic counts made during the year 1937.

In consideration of growth trends of population and motor-vehicle registration and the increased annual travel of vehicles, it has been estimated (see pp. 33 and 34) that utilization of the system in 1960 would be 2.5 times the 1937 value, and that the accumulated utilization during the period 1945 to 1960, inclusive, would be 34.2 times the 1937 value. It has not been considered advisable to attempt to estimate traffic beyond the year 1960.

It has been concluded that the toll rates that would probably produce the most favorable return for the system as a whole would average 1 cent per mile for each passenger car and 3.5 cents per mile for each motortruck and bus, the latter rate varying considerably with the weight and capacity of the vehicles. Assuming motortruck and bus traffic to constitute 20 percent of the total traffic, these rates result in an approximate average rate of 1% cents per mile for each vehicle without regard to type.

This rate has been applied to the forecast vehicle mileage for the year 1960 and for the period 1945-60, for the system as a whole and for each of the 75 sections previously identified, and the corresponding gross revenues are shown respectively in tables 18 and 19. For the entire system of 14,336 miles, the gross revenue for the year 1960 totals $84,037,000, as shown in table 18. For the period 1945-60 the revenues are estimated at a total of $1,154,237,000, as shown in table 19.^[1]

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​

Description		Number in order of revenue as a percentage of cost	Number in order of traffic volume	Route	By individual sections				Totals accumulated by sections
From—	To—				Length	Revenue	Costs	Revenue as a percentage of cost	Length	Revenue	Costs	Revenue as a percentage of cost
					Miles			Percent	Miles			Percent
Jersey City, N.J.	New Haven, Conn.	1	1	1	65.6	$4,773,166	$4,366,171	109.3	65.6	$4,773,166	$4,366,171	109.3
Junction, Route 4, Pa.	Jersey City, N.J.	2	2	1	106.8	5,359,401	5,179,294	103.5	172.4	10,132,567	9,545,465	106.2
Junction, Route 5, Calif.	Whitewater, Calif.	3	6	6	91.0	1,625,161	1,770,939	91.8	263.5	11,575,728	11,316,404	103.9
Washington, D.C.	Baltimore, Md.	4	4	1	39.3	858,305	969,511	88.5	302.7	12,616,033	12,285,915	102.7
Junction, Route 2, Mass.	Portland, Maine	5	5	1	133.9	2,566,097	3,025,376	84.8	436.6	15,182,130	15,311,291	99.2
Miami, Fla.	Jacksonville, Fla.	6	34	1	326.5	2,066,984	2,482,112	88.3	763.1	17,249,114	17,793,403	96.9
Baltimore, Md.	Junction, Route 4, Pa.	7	7	1	76.2	1,948,475	2,341,163	83.2	839.3	19,197,589	20,134,566	95.3
Richmond, Va.	Washington, D.C.	8	12	1	108.3	1,396,703	1,834,681	76.1	947.6	20,594,292	21,960,247	93.7
San Ysidro, Calif.	Junction, Route 6, Calif.	9	8	5	124.4	1,933,343	2,544,240	76.0	1,072.0	22,527,635	24,513,487	94.8
Whitewater, Calif.	Indio. Calif.	10	24	6	32.7	267,473	365,036	73.3	1,104.7	22,795,108	24,878,523	91.6
Junction, Route 3, Ill.	Junction, Route 3, Mich.–Ind.	11	9	2	156.9	2,393,515	3,283,094	72.9	1,261.6	25,188,623	28,161,617	89.4
Brigham, Utah	Salt Lake City, Utah	12	35	4-N	52.3	293.758	420,044	69.9	1,313.9	25,482,381	28,581,661	89.2
Odessa, Tex.	Junction, Route 3, Tex.	13	31	6	337.9	2,229,553	3,323,896	67.1	1,651.8	27,711,934	31,905,557	86.9
Junction, Route 6, Calif.	San Fernando, Calif.	14	3	5	44.8	1,659,032	1,704,467	62.1	1,696.6	28,770,966	33,610,024	85.6
Buffalo, N.Y.	Albany, N.Y.	15	11	2	287.6	3,999,194	6,465,359	61.9	1,984.2	32,770,160	40,075,383	81.8
Junction, Route 6, Calif.	Ludlow, Calif.	16	43	4-S	69.1	301,447	487,442	61.8	2,053.3	33,071,607	40,562,825	81.5
San Fernando, Calif.	Tracy, Calif.	17	21	5	291.7	2,237,203	3,660,813	61.1	2,345.0	35,308,810	44,223,638	79.8
Minneapolis, Minn.	Junction, Route 3, Ill.	18	26	2	392.6	3,066,415	5,319,989	57.6	2,737.6	38,375,225	49,543,627	77.5
Junction, Route 4, Calif.	Redding, Calif.	19	44	5	153.7	655,844	1,143,843	57.3	2,891,3	39,031,069	50,687,470	77.0
San Antonio, Tex.	Junction, Route 5, Tex.	20	36	3	250.7	1,360,262	2,557,538	53.2	3,142.0	40,391,331	53,245,008	75.9
Portland, Maine	Bangor, Maine	21	30	1	121.3	811,939	1,545,794	52.5	3,263.3	41,203,270	54,790,802	75.2
St. Joseph, Mo.	Junction, Route 3, Ill.	22	41	4	275.7	1,371,323	2,653,359	51.7	3,539.0	42,574,593	57,444,161	74.1
Junction, Route 3, Ill.	Indianapolis, Ind.	23	37	4	203.7	1,099,686	2,141,088	51.4	3,742.7	43,674,279	59,585,249	73.3
Carlisle, Pa.	Junction, Route 1, Pa.	24	13	4	94.8	1,101,118	2,159,260	51.0	3,837.5	44,775,397	61,744,509	72.5
Junction, Route 2, Ind.	Detroit, Mich.	25	15	3 Mich.	102.2	1,121,581	2,024,898	50.9	3,939.7	45,896,978	63,949,407	71.8
Tracy, Calif.	Junction, Route 4, Calif.	26	23	5	69.1	588,770	1,164,844	50.5	4,008.8	46,485,748	65,114,251	71.4
Junction, Route 3, Tex.	Shreveport, La.	27	27	6	190.4	1,422,427	2,938,833	48.4	4,199.2	47,908,175	68,053,084	70.4
Ludlow, Calif.	Las Vegas, Nev.	28	58	4-S	117.0	334,957	698,724	47.9	4,316.2	48,243,132	68,751,808	70.2
Fargo, N. Dak.	Minneapolis, Minn.	29	45	2	219.2	899,067	1,880,823	47.8	4,535.3	49,142,199	70,632,631	69.6
New Haven, Conn.	Junction, Route 2, Mass.	30	10	1	99.8	1,425,849	2,996,029	47.6	4,635.1	50,568,048	73,628,660	68.7
Greeley, Colo.	St. Joseph, Mo.	31	54	4	529.7	1,863,093	3,992,869	46.7	5,164.8	52,431,141	77,621,529	67.5
Indianapolis, Ind.	Columbus, Ohio	32	28	4	156.6	1,090,934	2,374,700	45.9	5,321.4	53,522,075	79,996,229	66.9
Phoenix, Ariz.	El Paso, Tex.	33	61	6	391.1	1,023,696	2,310,330	44.3	5,712.5	54,545,771	82,306,559	66.3
Cleveland, Ohio	Buffalo, N.Y.	34	18	2	220.7	2,238,510	5,063,783	44.2	5,933.2	56,784,281	87,370,342	65.0
Oakland, Calif.	Auburn, Calif.	35	16	4	110.0	1,124,703	2,568,737	43.8	6,043.2	57,908,984	89,939,079	64.4
Boise, Idaho	Rupert, Idaho	36	57	4-N	182.2	583,713	1,350,617	43.2	6,225.4	58,492,697	91,280,696	64.1 ​
Shreveport, La.	Vicksburg, Miss.	37	60	6	168.8	673,674	1,628,736	41.4	6,394.2	59,166,371	92,918,432	63.7
Salem, Oreg.	Portland, Oreg.	38	14	5	56.9	637,632	1,544,007	41.3	6,451.1	59,804,003	94,462,439	63.9
Junction, Route 4, Ill.	Junction, Route 2, Ill.	39	33	3	155.5	992,111	2,428,627	40.9	6,606.6	60,796,114	96,891,066	62.7
Perrysburg, Ohio	Cleveland, Ohio	40	20	2	79.3	730,810	1,803,198	40.5	6,685.9	61,526,924	98,694,264	62.3
Junction, Route 5, S.C.	Richmond, Va.	41	50	1	362.6	1,379,156	3,404,482	40.5	7,048.5	62,906,080	102,008,746	61.6
St. Louis, Mo.	Junction, Route 4, Ill.	42	38	3	88.8	517,609	1,278,322	40.5	7,137.3	63,423,689	103,377,068	61.4
Albany. N.Y.	Junction, Route 1, Mass.	43	17	2	147.2	1,501,047	3,744,027	40.1	7,284.5	64,924,736	107,121,095	60.6
Pittsburgh, Pa.	Carlisle, Pa.	44	19	4	166.6	1,623,921	4,058,060	40.0	7,451.1	66,548,657	111,179,155	59.9
Tulsa, Okla.	Springfield, Mo.	45	48	3	171.3	691,249	1,750,209	39.5	7,622.4	67,239,906	112,929,364	59.5
Junction, Route 3, Mich.–Ind.	Perrysburg, Ohio	46	40	2	69.9	335,433	861,251	38.9	7,692.3	67,575,339	113,790,615	59.4
Jacksonville, Fla.	Junction, Route 6, S.C.	47	49	1	219.3	861,017	2,214,043	38.9	7,911.6	68,436,356	116,004,658	5.0
Detroit, Mich.	Port Huron, Mich.	48	29	3 Mich.	72.5	504,071	1,309,891	38.5	7,984.1	68,940,427	117,314,549	58.8
Springfield, Mo.	St. Louis, Mo.	49	43	3	165.3	847,997	2,277,597	37.2	8,149.3	69,788,424	119,592,146	58.4
Junction, Route 4, Pa.	Junction, Route 1, Md.	50	51	4-A	88.5	330,580	904,772	36.6	8,237.8	70,119,004	120,496,918	58.2
Roseburg, Oreg.	Salem, Oreg.	51	39	5	133.3	643,301	1,807,431	35.6	8,371.1	70,762,305	122,304,349	57.9
El Paso, Tex.	Odessa, Tex.	52	56	6	245.2	829,008	2,349,410	35.5	8,616.3	71,591,313	124,653,759	57.4
Indio, Calif.	Phoenix, Ariz.	53	63	6	254.0	571,348	1,671,913	34.2	8,780.3	72,162,661	126,325,672	57.1
Columbus, Ohio	Pittsburg, Pa.	54	32	4	195,0	1,262,734	3,742,956	33.7	9,665.3	73,425,395	130,068,628	56.5
Portland, Oreg.	Junction, Route 2, Wash.	55	22	5	146.7	1,307,952	4,133,643	31.6	9,212.0	74,733,347	134,202,271	55.7
Junction, Route 2, Wash.	Canadian boundary	56	25	5	124.7	963,904	3,056,237	31.5	9,336.7	75,697,251	137,258,508	55.1
Junction, Route 6, Tex.	Tulsa, Okla.	57	55	3	270.5	929,290	3,035,608	30.6	9,607.2	76,626,541	140,294,116	54.6
Auburn, Calif.	Reno, Nev.	58	46	4	106.5	435,566	1,569,612	27.7	9,713.7	77,062,107	141,863,728	54.3
Ashland, Oreg.	Roseburg, Oreg.	59	47	5	122.9	499,285	2,031,243	24.6	9,836.6	77,561,392	143,894,971	53.9
Las Vegas, Nev.	Salt Lake City, Utah.	60	65	4-S	407.5	777,749	8,194,152	24.3	10,244.1	78,339,141	147,089,123	53.3
Birmingham, Ala.	Atlanta, Ga.	61	64	6	141.2	298,367	1,421,499	21.0	10,385.3	78,637,508	148,510,622	53.0
Boardman, Oreg.	Boise, Idaho	62	63	4-N	253.1	545,173	2,702,913	20.2	10,638.4	79,182,681	151,213,513	52.4
Salt Lake City, Utah	Greeley, Colo.	63	66	4	463.3	858,985	4,209,464	19.9	11,101.7	80,041,666	155,522,999	51.5
Rupert, Idaho	Brigham, Utah	64	71	4-N	119.7	130,548	681,980	19.1	11,221.4	80,172,214	156,204,979	51.3
Redding, Calif.	Ashland, Oreg.	65	59	5	138.2	384,349	2,026,613	19.0	11,359.6	80,556,563	158,231,592	50.9
Seattle, Wash.	Ellensburg, Wash.	66	53	2	90.0	331,277	1,846,325	17.9	11,449.6	80,887,840	160,977,917	50.5
Vicksburg, Miss.	Birmingham, Ala.	67	67	6	270.5	446,201	2,540,425	17.6	11,720.1	81,334,041	162,618,342	50.0
Bangor, Maine	Canadian boundary	68	68	1	196.6	318,939	1,838,184	17.4	11,916.7	81,652,980	164,456,526	49.7
Portland, Oreg.	Boardman, Oreg.	69	52	4-N	163.4	413,455	2,464,481	16.8	12,080.1	82,066,435	166,921,007	49.2
Mexican boundary	San Antonio, Tex.	70	69	3	156.2	204,424	1,268,466	16.1	12,236.3	82,270,859	168,189,473	48.9
Augusta, Ga.	Charleston, S.C.	72	73	4	116.3	144,276	949,213	15.2	12,352.6	82,415,135	169,138,686	48.7
Reno, Nev.	Salt Lake City, Utah	72	73	4	514.9	442,234	3,089,805	14.3	12,867.5	82,857,369	172,228,491	48.1
Spokane, Wash.	Fargo, N. Dak.	73	75	2	1,169.6	892,919	8,596,541	10,4	14,037.1	83,750,288	180,825,032	46.3
Ellensburg, Wash.	Spokane, Wash.	74	74	2	145.9	123,322	1,366,999	9.0	14,183.0	83,873,610	182,192,031	46.0
Atlanta, Ga.	Augusta, Ga.	75	72	6	153.2	162,911	1,861,840	8.8	14,336.2	84,036,521	184,053,871	45.7
Total					14,336.2	84,036,521	184,053,871	45.7
Total annual costs for the year 1960 $184,058,871 Total annual revenue for the year 1960 84,036,521 ⁠Deficit for the year 1960 100,017,350 Percentage revenue is of cost for the year 1960 45.7

​

Description		Number in order of revenue as a percentage of cost	Number in order of traffic volume	Route	By individual sections				Totals accumulated by sections
From—	To—				Length	Revenue	Costs	Revenue as a percentage of cost	Length	Revenue	Costs	Revenue as a percentage of cost
					Miles			Percent	Miles			Percent
Jersey City, N.J.	New Haven, Conn.	1		1	65.6	$65,559,143	$69,858,736	93.8	65.6	$65,559,143	$69,858,736	93.8
Junction, Route 4, Pa.	Jersey City, N.J.	2		1	106.8	73,811,054	82,868,706	88.8	172.4	139,170,197	152,727,440	91.1
Junction, Route 5, Calif.	Whitewater, Calif.	3	6	6	91.0	22,321,485	28,335,024	78.8	263.4	161,491,682	181,062,464	89.2
Washington, D.C.	Baltimore, Md.	4	4	1	39.3	11,788,774	15,512,176	76.0	302.7	173,280,456	196,574,640	88.1
Junction, Route 2, Mass.	Portland, Maine	5	5	1	133.9	35,245,186	48,406,016	72,8	436.6	208,525,642	244,980,656	85.1
Miami, Fla.	Jacksonville, Fla.	6	34	1	326.5	28,389,899	39,713,792	71.5	163.1	236,915,541	284,694,448	83.2
Baltimore, Md.	Junction, Route 4, Pa.	7	7	1	76.2	26,762,184	37,458,608	71.4	839.3	263,677,725	322,153,056	81.8
Richmond, Va.	Washington, D.C.	8	12	1	108.3	19,183,635	29,354,896	65.4	947.6	282,861,360	351,507,952	80.5
San Ysidro, Calif.	Junction, Route 6, Calif.	9	8	5	124.4	26,554,351	40,707,840	65.2	1,072.0	309,415,711	392,215,792	78.9
Whitewater, Calif.	Indio, Calif.	10	24	6	32.7	3,673,730	5,840,576	62.9	1,104.7	313,089,441	398,056,368	78.7
Junction, Route 3, Ill.	Junction, Route 3, Michi.–Ind.	11	9	2	156.9	32,874,784	52,529,504	62.9	1,261.6	345,964,225	450,585,872	76.8
Brigham, Utah	Salt Lake City, Utah	12	35	4-N	52.3	4,034,745	6,720,704	60.0	1,313.9	349,998,970	457,306,576	76.5
Odessa, Tex.	Junction, Route 3, Tex.	13	31	6	337.9	30,622,783	53,182,336	52.6	1,651.8	380,621,753	510,488,912	74.6
Junction, Route 6, Calif.	San Fernando, Calif.	14	3	5	44.8	14,545,739	27,271,472	53.3	1,696.6	395,167,492	537,760,384	73.5
Buffalo, N.Y.	Albany, N.Y.	15	11	2	287.6	54,928,688	103,445,744	53.1	1,984.2	450,096,180	641,208,128	70.2
Junction, Route 6, Calif.	Ludlow, Calif.	16	42	4-S	69.1	4,140,355	7,799,072	53.1	2,053.3	454,236,535	649,005,200	70.0
San Fernando, Calif.	Tracy, Calif.	17	21	5	291.7	30,727,845	58,573,008	32.5	2,345.0	484,964,380	707,578,208	68.5
Minneapolis, Minn.	Junction, Route 3, Ill.	18	26	2	392.6	42,117,026	85,119,824	49.5	2,737.6	527,081,406	792,698,032	66.5
Junction, Route 4, Calif.	Redding, Calif.	19	44	5	153.7	9,007,972	18,301,488	49.2	2,891.3	536,089,378	810,999,520	66.1
San Antonio, Tex.	Junction, Route 6, Tex.	20	36	3	250.7	18,683,118	40,920,608	45.7	2,142.0	554,772,496	851,920,128	65.1
Portland, Maine	Bangor, Maine	21	30	1	121.3	11,151,936	24,732,704	45.1	3,263.3	565,924,432	876,652,832	74.6
St. Joseph, Mo.	Junction, Route 3, Ill.	22	41	4	275.7	18,835,034	42,453,744	44.4	3,539.0	584,759,466	919,106,576	63.6
Junction, Route 3, Ill.	Indianapolis, Ind.	23	37	4	203.7	15,104,122	34,257,408	44.1	3,742.7	599,863,588	953,363,984	62.9
Carlisle, Pa.	Junction, Route 1, Pa.	24	13	4	94.8	15,123,787	34,548,160	43.8	3,837.5	614,987,375	987,912,144	62.3
Junction, Route 2, Ind.	Detroit, Mich.	25	15	3 Mich.	102.2	15,404,843	35,278,368	43.7	3,939.7	630,392,218	1,023,190,512	61.6
Tracy, Calif.	Junction, Route 4, Calif.	26	23	5	69.1	8,086,727	18,637,504	43.4	4,008.8	638,478,945	1,041,828,016	61.3
Junction, Route 3, Tex.	Shreveport, La.	27	27	6	190.4	19,536,955	47,021,328	41.5	4,199.2	658,015,900	1,088,849,344	60.4
Ludlow, Calif.	Las Vegas, Nev.	28	58	4-S	117.0	4,600,618	11,179,584	41.2	4,316.2	662,616,518	1,100,028,928	60.2
Fargo, N. Dak.	Minneapolis, Minn.	29	45	2	219.1	12,348,628	30,093,168	41.0	4,535.3	674,965,146	1,130,122,096	59.7
New Haven, Conn.	Junction, Route 2, Mass.	30	10	1	99.8	19,583,946	47,936,464	40.9	4,635.1	694,549,092	1,178,058,560	59.0
Greeley, Colo.	St. Joseph, Mo.	31	54	4	529.7	25,589,466	63,885,904	40.1	5,164.8	720,138,558	1,241,944,464	58.0
Indianapolis, Ind.	Columbus, Ohio	32	28	4	156.6	14,983,909	37,995,200	39.4	5,321.4	735,122,467	1,279,939,664	57.4
Phoenix, Ariz.	El Paso, Tex.	33	61	6	391.1	14,060,407	36,965,280	38.0	5,712.5	749,182,874	1,316,904,944	56.9
Cleveland, Ohio	Buffalo, N.Y.	34	18	2	230.7	30,745,800	81,020,528	37.9	5,933.2	779,928,674	1,397,925,472	55.8
Oakland, Calif.	Auburn, Calif.	35	16	4	110.0	15,447,730	41,099,792	37.6	6,043.2	795,376,404	1,439,025,264	55.3
Boise, Idaho	Rupert, Idaho	36	57	4-N	182.2	8,017,267	21,609,872	37.1	6,225.4	803,393,671	1,460,635,136	55.0 ​
Shreveport, La.	Vicksburg, Miss.	37	60	6	168.8	9,252,878	26,059,776	35.5	6,394.2	812,646,549	1,486,694,912	54.7
Salem, Oreg.	Portland, Oreg.	38	14	5	56.9	8,757,833	24,704,112	35.5	6,451.1	821,404,382	1,511,399,024	54.3
Junction, Route 4, Ill.	Junction, Route 2, Ill.	39	33	3	155.5	13,626,580	38,858,032	35.1	6,606.6	835,030,962	1,550,257,056	53.9
Perrysburg, Ohio	Cleveland, Ohio	40	20	2	79.3	10,037,632	28,851,168	34.8	6,685.9	845,068,594	1,579,108,224	53.5
Junction, Route 6, S.C.	Richmond, Va.	41	50	1	362.6	18,942,628	54,471,712	34.8	7,048.5	864,011,222	1,633,579,936	52.9
St. Louis, Mo.	Junction, Route 4, Ill.	42	38	3	88.8	7,109,325	20,453,152	34.8	7,137.3	871,120,547	1,654,033,088	52.7
Albany, N.Y.	Junction, Route 1, Mass.	43	17	2	147.2	20,616,786	59,904,432	34.4	7,284.5	891,737,333	1,713,937,520	52.0
Pittsburgh, Pa.	Carlisle, Pa.	44	19	4	166.6	22,304,453	64,928,960	34.4	7,451.1	914,041,786	1,778,866,480	51.4
Tulsa, Okla.	Springfield, Mo.	45	48	3	171.3	9,494,262	28,003,344	33.9	7,622.4	923,536,048	1,806,869,824	51.1
Junction, Route 3, Mich.–Ind.	Perrysburg, Ohio	46	40	2	69.9	4,607,150	13,780,016	33.4	7,692.3	928,143,198	1,820,649,840	51.0
Jacksonville, Fla.	Junction, Route 6, S.C.	47	49	1	219.3	11,826,018	35,424,688	33.4	7,911.6	939,969,216	1,856,074,528	50.6
Detroit, Mich.	Port Huron, Mich.	48	29	3 Mich	72.5	6,923,380	20,958,256	33.0	7,984.1	946,892,596	1,877,032,784	50.4
Springfield, Mo.	St. Louis, Mo.	49	43	3	165.2	11,647,186	36,441,552	32.0	8,149.3	958,539,782	1,913,474,336	50.1
Junction, Route 4, Pa.	Junction, Route 1, Md.	50	51	4-A	88.5	4,540,495	14,476,352	31.4	9,237.8	963,080,277	1,927,950,688	50.0
Roseburg, Oreg.	Salem, Oreg.	51	39	5	133.3	8,835,707	28,918,896	30.6	8,371.1	971,915,984	1,956,869,584	59.7
El Paso, Tex.	Odessa, Tex.	52	56	6	245.2	11,386,377	37,590,560	30.3	8,616.3	983,302,361	1,994,460,144	49.3
Indio, Calif.	Phoenix, Ariz.	53	62	6	254.0	7,847,429	26,750,008	29.3	8,870.3	991,149,700	2,021,210,752	49.0
Columbus, Ohio	Pittsburgh, Pa.	54	32	4	195.0	17,343,572	59,887,296	29.0	9,065.3	1,008,493,362	2,081,098,048	48.5
Portland, Oreg.	Junction, Route 2, Wash.	55	22	5	146.7	17,964,644	66,138,288	27.2	9,212.0	1,026,458,006	2,127,236,336	47.8
Junction, Route 2, Wash.	Canadian boundary	56	25	5	124.7	13,239,162	48,899,792	27.1	9,336.7	1,039,697,168	2,196,136,128	47.3
Junction, Route 6, Tex.	Tulsa, Okla.	57	55	3	270.5	12,763,748	48,569,728	26.3	9,607.2	1,052,460,916	2,244,705,856	46.9
Auburn, Calif.	Reno, Nev.	58	46	4	106.5	5,982,469	25,113,792	23.8	9,713.7	1,058,443,385	2,269,819,648	46.6
Ashland, Oreg.	Roseburg, Oreg.	59	47	5	122.9	6,857,647	32,499,888	21.1	9,836.6	1,065,301,032	2,302,319,536	46.3
Las Vegas, Nev.	Salt Lake City, Utah	60	65	4-S	407.5	10,682,336	51,106,432	20.9	10,244.1	1,075,983,368	2,353,425,968	45.7
Birmingham, Ala.	Atlanta, Ga.	61	64	6	141.2	4,098,049	22,743,984	18.0	10,385.3	1,080,081,417	2,376,169,952	45.5
Boardman, Oreg.	Boise, Idaho	62	63	4-N	253.1	7,487,919	43,246,608	17.3	10,638.4	1,087,569,336	2,419,416,560	45.0
Salt Lake City, Utah	Greeley, Colo.	63	66	4	463.3	11,798,111	68,951,424	17.1	11,101.7	1,099,367,447	2,488,367,984	44.2
Rupert, Idaho	Brigham, Utah	64	71	4-N	119.7	1,793,072	10,911,680	16.4	11,221.4	1,101,160,519	2,499,279,664	44.1
Redding, Calif.	Ashland, Oreg.	65	59	5	138.2	5,279,009	32,425,808	16.3	11,359.6	1,106,439,528	2,531,705,472	43.7
Seattle, Wash.	Ellensburg, Wash.	66	53	2	90.0	4,550,071	29,541,200	15.4	11,449.6	1,110,989,599	2,561,246,672	43.4
Vicksburg, Miss.	Birmingham, Ala.	67	67	6	270.5	6,128,538	40,646,800	15.1	11,720.1	1,117,118,137	2,601,893,472	42.9
Bangor, Maine	Canadian boundary	68	68	1	196.6	4,380,610	29,410,944	14.9	11,916.7	1,121,498,747	2,631,304,416	42.6
Portland, Oreg.	Boardman, Oreg.	69	52	4-N	163.4	5,678,773	39,431,696	14.4	12,080.1	1,127,177,520	2,670,736,112	42.2
Mexican boundary	San Antonio, Tex.	70	69	3	156.2	2,807,752	20,295,456	13.8	12,236.3	1,129,985,272	2,691,031,568	42.0
Augusta, Ga.	Charleston, S.C.	71	70	6	116.3	1,981,616	15,187,408	13.0	12,352.6	1,131,966,888	2,706,218,976	41.8
Reno, Nev.	Salt Lake City, Utah	72	73	4	514.9	6,074,057	49,436,880	12.3	12,867.5	1,138,040,945	2,755,655,856	41.3
Spokane, Wash.	Fargo, N. Dak.	73	75	2	1,169.6	12,264,188	137,544,656	8.9	14,037.1	1,150,305,133	2,893,200,512	39.8
Ellensburg, Wash.	Spokane, Wash.	74	74	2	145.9	1,693,823	24,871,984	7.7	14,183.0	1,151,998,956	2,915,072,496	39.5
Atlanta, Ga.	Augusta, Ga.	75	72	6	153.2	2,237,569	29,789,440	7.5	14.336.2	1,154,236,525	2,944,861,936	39.2
Total					14,336.2	1,154,236,525	2,944,861,936	39.2
Total annual costs for the period 1945–60 $2,944,861,936 Total annual revenue for the period 1945–60 1,154,236,525 ⁠Deficit for the period 1945–60 1,790,625,411 Percentage revenue is of cost for the period 1945–60 39.2

​

In addition to the estimated toll revenues tables 18 and 19 also show the combined debt service, maintenance, and operating costs for the system as a whole and separately for each of its 75 sections, for the year 1960 and for the period 1945-60, respectively. Relations of sectional and total revenues and costs are also indicated by solvency or operating ratios.

Table 18 shows for the year 1960 a deficit of $100,017,350, with a corresponding solvency or operating ratio of 45.7 percent.

Table 19 shows for the period 1945–60 a deficit of $1,790,625,411 with a corresponding solvency or operating ratio of 39.2 percent. In both tables 18 and 19, the 75 sections are arranged in the descending order of the solvency or operating ratios; and their order on the basis of traffic volume is indicated by the serial numbers in column 2.

It is to be noted that the indicated deficits, which are believed to be minimum values, occur for the system as a whole, notwithstanding the use of a liberal estimate of initial use of the toll roads in 1945 and a liberal rate of annual increase of the toll-paying traffic—a rate substantially greater than the estimated general rate of increase in all motor-vehicle traffic.

It may be argued that, since State gasoline taxes have been justified as charges for road use, such tax earnings should contribute to the support of the system of toll roads in proportion to the gasoline consumed on them. Assuming gasoline tax earnings at 0.28 cent per mile for passenger cars and 0.56 cent per mile for trucks and busses the average annual earnings in the period 1945-60 would amount to $15,270,000. Should it be found possible to credit this amount to the toll system it would make no important change in the conclusions reached since the average annual deficit for the entire system would be reduced by only about 14 percent.

From the fact that the system as a whole shows the above-noted deficits, it does not necessarily follow that all sections would show a deficit, since the various sections operate under different relative conditions of first cost, annual cost, and annual revenue. However, examination of the data presented in table 19, particularly the solvency or operating ratios in column 9 and the accumulated ratio in column 13, shows that there is no section or combination of sections that has a solvency or operating ratio above 93.8 percent for the period 1945–60. In the year 1960, table 18 indicates that four sections cumulatively might earn a slight excess of revenue over costs.

It is here to be observed, however, that, in general, unless the various sections and groups of sections form parts of a larger connected toll system the previously estimated toll-paying traffic may not be realized.

Finally, therefore, it is concluded:

That, since a liberal estimate of revenue for the period 1945–60 is less than 40 percent of a conservative estimate of debt service, maintenance, and operating costs for the same period, a toll system on the roads selected as directed in section 18 of the act of June 8, 1938, is not feasible.