UTILIZATION OF COMPUTERS FOR MANAGEMENT AND DEVELOPMENT OF TRANSPORTATION SYSTEMS: PAPERS AND PROCEEDINGS OF A U.S.-U.S.S.R. SEMINAR, MOSCOW 1975

Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Utilization of Computers for the Management and Development of Transportation Systems: Papers and Proceedings of a U.S.-U.S.S.R. Seminar, Moscow 1975 State Dept. declassification & release instructions on file Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Utili7 ti.on of Co::puters for the 2iar'~a~;c~tLC It and Developra_,.ut of Transportation Systcirs: Papers and Proceedings of a U.S.-U.S.S.R. Scsni.nar, Moscow Sydney Shulr;an, Administrative Editor Translation and publication of this work was supported by grant No. GJ-41942 DCR 74-3.3801.A02 from the National. Science Foundation to the National Bureau of Economic Research, Tnc. However, any opinions, findings, conclusions or recor..?.acndaticits expressed here- in are those of the authors and do not necessarily reflect the views of the National Science Foundation or the National Bureau. Since the present volume is a record of conference proceedings, it has been exempted from the rules governing submission of manu- scripts to, and critical review by, the Board of Directors of the National Bureau. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 CONTENTS INTRODUCTION ....................?.........??..?................ i Harvey McMains AN OVF:IRVIt:61 OF U.S. TRANSPOR:TATI.ON: SIMILARITIES AND CONTRA:>Tc, 1'IT}i THE. U.S. S. P .. ................................... 1 Rolland Hurter FREIGHT Dt:"ODELTING: A POLICY-SENSITIVE APPROACH........... 25 Marc N. Terziev, Mushe Yen-40hiva tnd Paul 0. Roberts IWEDS /3W PRIORITIES IN RESEARCH ON RAIL SI:P.VICE RELIABILITY... 81 Jo.erh H. Su.`l.'nan ' i . ' ?1'i." d1'P)' ctif.l,~"H'i.rS TO TkAVHI, 1'MAIil) LuR. t:cASTI i ( .?????.?????????? 15 \.u ME dt; a ? Marvin L. M.-inhei.r. EYAMPLES OF COIIPUT);I: API'LIC4MUNS ICI THE J^~::SPOI.1'r~i.'IOI FIELD .......................................................... 193 Faye C. Johnson CO IT'UTY11 APPLICATION IN THE ALLOCATION OF AIRLINE RESOUI CF.S.... 223 Morton Ehrlich A SOFTWARE SYSTF'?1 FOR URBAN Y.obez t Y. Dial TRANSPORTATION PLANNING............ 271 AN EVALUATION OF TILE AIR QUALITY I"TACTS OF TRANSPORTATION CONTROL POLICIES IN U. S . URBAN AREAS ........................... 288 Gregory K. Ingram THE INTRODUCiTON OF MATIIF2.fATICAL-ECOL O'IIC METHODS AND COMPUTER TECIP.NOLOGY IN PLANNING AND MA AGING SOVIET TRANSPORTATION...... 336 Boris S. Nozin OPTIMIZING MODELS FOR PLANNING THE OPERATION AND DEVELOPMENT OF A TRANSPORT NET'v'OPJ'. ......................................... 343 I. T. Kozlov METHODS OF FIVE.-YEAR PLANNING OF TRANSPORT-ECONOMIC CONNECTIONS: THEORETICAL DEVELOPI-T.:TFS AND EXPERIENCE WITH PRACTICAL APPLICA- TIONS ........................................................... 353 P. I. Mokrousova and Z. I. Ffozgrina PROBLEMS OF OPTIMAL PLANTING AND MANAGEMENT OF AUTOBUS TRANSPORT IN THE GEORGIAN SSR ................................... 366 G. G. Tsonaja AUTOMATION OF BOOKING AND RESERVATION OPERATIONS ON SOVIET RAILROADS .................. .......... ......'......'..... 377 B. E. Marchuk Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 THE "SIREN" SYSTEM: A NATIONWIDE AUTOMATIC CONTROL SYSTEM FOR BOOKING AND RESERVING SEATS ON DOMESTIC AIRLINES............ 386 V.A. Thozhiksshvili et al. INFORMATION MODELING FOR MANAGING SOVIET MARITIME TRANSPORTATION .................................................. 405 V. S. Bondarenko Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 i INTRODUCTION The U.S.-U.S.S.R. Conference on Utilization of Computers for the Management and Development of Transportation Systems took place in the Soviet Union on June 28-July 10, 1975. Fifteen papers were presented at the conference and are included in these proceed- ings. The purpose of the conference was to share concepts and techniques being used in the Soviet Union and the United States in the planning, design, implementation and use of computer models, simulations and programs for managing and operating transportation systems. There were open and frank discussions in regard to all the material presented. Both sides agreed that the next activity would be the development of mutually beneficial, longer term joint research. Harvey McMains Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 AN OVERVIEW OF U.S. TRANSPORTATION: SIMILARITIES AND CONTRASTS WITH THE USSR Holland Hunter This brief essay offers a primarily statistical sketch of the United States transportation system as it has evolved in the last quarter century or so. It is intended to set the stage for the research papers that follow, papers describing ways in which systems analysis aided by computers is being used in United States transportation. The sketch highlights some features of freight and passenger transportation that distinguish the United States situation from that of other countries, in particular that of the USSR. Both the U.S. and the USSR are large countries with large economies and large transportation systems. The contrasts, however, are as interesting as the similarities, and in our view much can be learned by examining both to see what they imply for the improved performance of each system. Intercity Freight and Passenger Transportation Over the last half century, United States intercity transportation has been marked primarily by a decline in the relative role of the railroads, matched by the steady rise of other carriers. For freight transportation, trends over the last thirty-five years are shown in table 1. Railroads accounted for two-thirds of the intercity freight traffic during the 1939-1948 decade; in recent years this share has fallen below 40%. Pipelines and intercity trucks have rapidly and steadily increased their share, each now accounting for over 22% of total intercity freight traffic. Freighters and barges on the Great Lakes, the Mississippi-Ohio- Missouri River system, and the coastal waterways of the Atlantic, Gulf, and Pacific Coasts have steadily raised the volume of their traffic and * pAgggyS0 FqAraWj%"28NJjYJ 9 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 CIA-RDP79-00798A000200020005-9 Table 1 Domestic Intercity Freight Traffic, U.S., by Carrier, Five-Year Totals, 1939-43 through 1969-73, in-I illions of Metric Ton-I.Ei'lometers Motor Inland Oil Railroads Vehicles Waterways Pipelines Airways, Total 1939-43. 4070 457 912 520 - 5989 1944-48 5202 621 1032 848 1 7704 1949-53 4631 1295 1177 1057 3 8163 1954-58 4513 1745 1507 1527 4 9296 1959-63 4438 2197 1583 1723 7 9948 1964-68 5354 2746 1993 2424 16 12524 1969-73 5742 3264 2386 3319 26 14737 Percent Shares 1939-43 68.0 7.6 15.7 8.7 - 100 1944-48 67.5 8.1 13.4 11.0 - 100 1949-53 56.7 15.9 14.4 13.0 - 100 1954-58 48.6 18.8 16.2 16.4 - 3.00 1959-63 44.6 22.1 15.9 17.3 .1 100 1964-68 42.7 21.9 15.9 19.4 .1 100 1969-73 39.0 22.1 16.2 22.5 .2 100 Source: Compiled from annual data in ton-miles (1 metric ton - km - 1.46 short ton-mile) in U.S. Bureau of the Census, Historical Stat. of the U.S. (1960), Series Q1-11 (adjusted for coverage changes); Statistical Abstract of the U.S: 1974, p. 547; and U.S. Interstate Commerce Commission, 88th Annual Report, p. 120. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 maintained their share of about one-sixth of the total. United States intercity passenger travel is heavily dominated by the passenger automobile, as shown in table 2. Since 1950, privately owned automobiles have accounted for at least 86% of all intercity passenger travel; their share in 1960 reached 90% but since then has fallen back slightly. The balance is handled by airways, buses, rail- roads, and internal waterways, with the air share steadily rising to over 10% and the share of buses and railroads shrinking. The absolute volume of bus travel has been fairly steady, but rail passenger travel has fallen by two-thirds over the last quarter century. Today, air transport is clearly the dominant form of public intercity passenger transport, accounting for well over 70% of intercity passenger travel not done by automobile. The revenues earned by carriers for all their domestic freight and passenger service are displayed in table 3. Trends reflect the physical changes already noted but with significant distinctions. The railroad share of revenue, for example, is less than their share of freight, since railroads carry a good deal of low-value freight. The truck share of revenues, conversely, is higher than their share of freight, and, recently, intercity trucking has taken in more than 42% of all transportation revenues. The airline share of total passenger and freight revenues has grown rapidly from 4% to 20%. Pipeline revenues, though they have tripled over the last quarter century, are still only 3% of all transportation revenue since costs and charges for this form of movement are extremely low. Low per-unit costs also characterize internal waterway freight traffic, where the revenue share has been falling though the volume of traffic continues to grow and the freight share is stable. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 CIA-RDP79-00798A000200020005-9 Table 2 4 Domestic Intercity Passenger Taffic, U.S., by Carrier, Selected Years, 1950-1973, in billions of Passenger- kilometers Private Automobiles Airways Buses Railroads . Inland Waterways Total 1950 704.9 16.1 41.8 51.5 1.9 816.2 1955 1025.1 37.0 40.2 46.7 2.7 1151.7 1960 1136.2 54.7 30.6 35.4 4.3 1261.2 1965 1316.4 93.3 38.6 29.0 5.0 1482.3 1970 1651.2 191.5 40.2 27.7 6.4 1907.0 1973 Percent Shares 1950 86.4 2.0 5.1 6.3 0.2 100 1955 89.0 3.2 3.5 4.1 0.2 100 1960 90.1 4.3 2.4 2.8 0.4 100 1965 88.8 6.3 2.6 2.0 0.3 100 1970' 86.6 10.0 2.1 0.9 0.4 100 1973 Source: Passenger-tile data from U.S. Dept. of Commerce, Bureau of the Census, Statistical' Abstract of the U.S., 1975, p. 562. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Table 3 Revenues From Domestic Freight and Passenger Traffic, U.S., by Carrier, Selected Years, 1950-1973, in millions of Dollars Railroads Trucks Airlines Pipelines Buses Waterlines Total 1950 10,147 3,737 558 442 539 330 15,753 1955 10,831 5,535 1215 678 552 452 19,263 1960 10,203 7,214 2129 770 667 427 21,410 1965 11,054 10,068 3609 904 885 426 26,946 1970 12,824 14,585 7131 1188 1062 502 37,292 1973 15,864 20,800 9605 1446 1135 615 49,465 Percent Shares 1950 64.4 23.7 3.6 2.8 3.4 2.1 100 1955 56.2 28.7 6.3 3.5 2.9 2.4 100 1960 47.7 33.7 9.9 3.6 3.1 2.0 100 1965 41.0 37.4 13.4 3.3 3.3 1.6 100 1970 34.4 39.1 19.1 3.2 2.9 1.3 100 1973 32.1 42.1 19.4 2.9 2.3 1.2 100 Source: Statistical Abstract of the U.S., 1975, p. 560. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Table 4 presents summary data for 1973, showing not only the ton- kilometers of freight handled by each of the four major carriers but also their tons originated and the resulting quotient showing each carrier's average length of haul. Intercity freight typically moves for long distances in the United States, reflecting the continental dimensions of the economy. Railroads and pipelines have an average length of haul above the overall national average, while waterways and highways show a somewhat lower figure. These crude averages, both in aggregate and for the individual modes, summarize an underlying distribution including a great deal of short-haul movement offset by significant amounts of extremely long-haul traffic. Strictly local movement by trucks in urban areas is specifically excluded from these statistics. The massive expansion of automotive passenger and freight trans- portation is dramatically symbolized by the data in table 5 showing the route length of railroads and highways in the United States over the period 1890-1973. Initially, the total length of the railroad network was greater than the total length of surfaced highways, but by 1920 the highway network exceeded the railroad system in length. After 1930, U.S. railroads began a gradual abandonment of little-used roadway; the 1973 length of the railroad system is below that of 1910. In sharp contrast, however, the length of surfaced highways almost quadrupled from 1930 to 1973. It will be seen that the total length of all highways outside towns and cities has grown only modestly; the basic change has involved upgrading through providing existing roads with all-weather surfaces. These summary figures also understate the qualitative improve- ment that has come with modern highway construction, especially with the 69,000 kA Ppe'Qed8Fd R 9#"MX1;filel9 $ - DP3Mt-W?98,4bbof66610gdg_luger  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Table 4 Freight Shipments and Average Length of Haul, U.S., 1973, by Carrier, in Kilometers and millions of Metric Tons Ton-kilometers (billions) Tons Originated (millions) Average Haul (kilometers) Railroads 1,253 1,466 855 Highways 737 1,833 402 (a) Waterways 523 902 580 Pipelines 740 1,091 .678 Four-carrier Total 3,253 5,292 615 (a) Class I and II common and contract carriers, 1971. See ICC, Trans. Stat. of the U.S., part 7, release 2, pp. 48, 54, 164. Source: U.S. Dept. of Commerce, Bureau of the Census, Stat. Abstract of the U.S., 1975, pp. 580-81, 586, 596. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Length of Railroads and Highways, U.S., Selected Years, 1890-1973, in Thousands of Kilometers Highways (outside towns and cities) Railroads Surfaced Unsurfaced Total 1890 251 NA NA NA 1900 311 248 (a) NA NA 1910 388 328 NA NA 1920 418 594 4113 4707 (b) 1930 418 1117 3725 4842 1940 396 2156 2956 4812 1950 381 2702 2110 4812 1960 370 3484 1531 5015 1970 354 3880 1220 5100 1973 348 3920 1191. 5111 (a) 1904 (b) 1921 Source: U.S. Dept. of Commerce, Bureau of the Census, Historical Stat. of the U.S. to 1957, pp. 429, 458; Stat. Abstract of the U.S., 1975, pp. 564, 581. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 and freight movement by highway has been substantially enhanced by this national grid of limited-access, divided-lane superhighways. Of course, at the same time, these improvements in the highway system have been occurring, corresponding technological improvements have occurred in railroading (e.g., centralized traffic control and improvements in the geometry and weight of trackage), so that even though railroad system kilometers have contracted, the total capability of the railroad system has remained at least constant and probably enlarged. The usage of roads and highways outside cities in the United States is divided roughly three to one between passenger automobiles and trucks, with buses accounting for a negligible share of total vehicle kilometers. The figures in table 6 show that, measured in billions of vehicle- kilometers per year, the volume of use by passenger cars in 1973 was 3.5 times as large as in 1940, bus use had doubled, and truck use was five times as great. This growth in usage went well beyond the expansion in nonurban highway mileage, so that intercity traffic density per route kilometer more than doubled. As a crude overall average, in 1940 one could see thirteen vehicles per hour pass one point on the network every hour every day through the year. By 1973 this figure had risen to twenty-eight. The truck share of highway usage was gradually expanding at the expense of buses and passenger cars and, though the growth of bus usage appeared to be leveling off, growth in truck and passenger car use of the highways was vigorous through 1973. Higher fuel prices may check this growth somewhat, but the forces pressing for further growth seem very strong. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 16' INTERCITY MOTORWVEHICLE MOVEMENT AND DENSITY, U.S., SELECTED YEARS, 1940-1973 (in billions of vehicle-kilometers and hourly vehicle-kilometers per-kilometer of surfaced highway) ,Passenger Buses Trucks Cars Total Hourly Number of Vehicles 1940 193.9 2.3 48.6 244.8 13 1950 291.4 3.4 91.4 386.2 16 1960 488.1 3.7 131.5 623.3 20 1970 654.0 4.5 215.8 874.3 26 1973 715.0 4.7 247.8 967.5 28 Percent Shares 1940 79.2 0.9 19.9 100 1950 75.4 0.9 23.7 100 1960 78.2 0.6 21.2 100 1970 74.8 0.5 24.7 100 1973 73.9 0.5 25.6 100 Source: Derived 'from U.S. Department of Commerce, Bureau of the Census, Stat. Abstract 175, pp. 571 and 564 Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Urban Transportation In the last forty years urban passenger transportation in the United States has shifted markedly away from public carriers toward the private automobile. Table 7 shows the number of passengers carried by the major means of mass transit at various times between 1930 and 1973. On subways and elevated electric trains, the number dropped from 13 billion annually to less than 2 billion. Railroad commutation passen- gers dropped from 435 to 183 million per year. Passengers using buses increased markedly from 1930 to 1950, but their number has since been cut in half. The trolley bus similarly showed a rapid expansion up to 1950 and an equally sharp decline since then. Overall, the annual number of passenger trips made on these four major means of mass transit has dropped from 17.5 billion in 1950 to less than 7 billion in 1973. Much public policy has been directed toward promoting the use of mass transit, but the United States urban population has stubbornly continued to prefer the private passenger automobile. The census of 1970 asked a 15% sample of urban and rural households about how working members of each household got to work. Their answers are summarized in table 8. Two-thirds of the labor force rode to work in automobiles that they drove, and more than 10% rode as passengers. Those who walked to work made up 7.4%, and 9% used bus, street car, subway, elevated train, railroad, or taxicab. A few used other means, and about 4% of the urban labor force (over 12% of the rural labor force) worked at home. This pattern reflects in part the way that residences and work places have been dispersed in postwar U.S. metropolitan regions; it is increasingly inconvenient or even impossible to get from home to work and back by means other than the passenger automobile. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200Q20005-9 URBAN PASSENGER TRAFFIC, U.S., BY PUBLIC CARRIER, SELECTED YEARS, 1930-1973 '(in millions of passengers carried) Subway and Elevated Electric RR Railroad Commutation Motor Bus Trolley Bus Total 1930 13,072 435 2,479 16 16,002 1940 8,325 229 4,239 534 13,327 1950 6,168 ?277 9,420 1,658 17,523 1960 2,313 203 6,425 657 9,598 1970 2,116 206 5,034 182 7,538 1973 1,921 183 4,642 97 6,843 Sources: U.S. Dept. of Commerce, Bureau of the Census, Hist. Stat. of the U.S., p. 464; Stat. Abstract '75, p. 579; and (for railroads) Assoc. of Am Railroads, Railroad Trans., A Statistical Record 1921-63 (Wash., 1965), p. 24; Stat. of Railroads of Class I (Aug. 1974), p. 7. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 TABLE 8 MEANS OF TRANSPORTATION TO WORK, U.S., 1970 URBAN AND RURAL WORKERS (in millions of workers 16 years old or over) Urban Rural Passenger automobile As driver 38,133 12,565 50,698 As passenger 6,702 2,322 9,024 On foot 4,506 1,183 5,689 Bus or streetcar 4,116 129 4,245 Subway or elevated train 1,762 6 1,768 Railroad 473 29 502 Taxicab 278 18 296 Other, or worked at home 2,258 2,371 4,629 Total 58,228 18,623 76,851 Percent Shares Passenger automobile As driver 65.5 67.5 66.0 As passenger 11.5 12.5 11.7 On foot 7.7 6.3 7.4 Bus or streetcar 7.1 0.7 5.5 Subway or elevated train 3.0 -- 2.3 Railroad 0.8 0.2 0.7 Taxicab 0.5 0.1 0.4 Other, or worked at home 3.9 12.7 6.0 Total 100.0 100.0 100.0 Source: U. S. Department of Commerce, Bureau of the Census, Stat. Abstract '75 p. 578 Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The streets and highways of U.S. cities and towns are dominated by passenger automobiles, as shown in the data of table 9. Automatic counting devices and inspectors at selected locations regularly measure the number of vehicles of each type using the roads. Passenger cars accounted for 86% of all vehicle-kilometers in 1940, and their 84% share in 1973 was only slightly lower. The truck share rose from 13% to 16%, while the share of buses dropped from slightly under 1% to only 0.3%. The absolute volume of bus movement has stopped growing. Though the total length of urban streets and highways has expanded, traffic density (measured as the hourly number of vehicles passing a given point) has roughly doubled since 1940. Some Basic Dimensions of Soviet Transportation The statistics above were presented in metric tons and kilometers to facilitate comparisons with analogous Soviet measures of transporta- tion. Here a few Soviet statistics are presented to illustrate some basic contrasts between the transportation systems of the two economies. Table 10, similar in form to table 4, shows for 1973 the level of activity of the four major freight carriers. It is immediately apparent that railroads dominate Soviet freight transportation to a greater extent than has been true in the United States for many decades. Soviet railroads carry more than twice as much freight as U.S. railroads for approximately the same average distance. The Soviet figure for truck. traffic relates mainly to local rather than intercity movement (the average haul in the USSR is 16 kilometers compared to 402), so for comparability most of this Soviet truck traffic should be excluded from a comparison of intercity traffic. Conversely, a portion of Soviet Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 URBAN MOTOR-VEHICLE MOVEMENT AND DENSITY, U.S., SELECTED YEARS, 1940-1973 (in billions of vehicle-kilometers and hourly vehicle-kilometers per kilometer of surfaced highway) Passenger Cars Buses Trucks Total Hourly Number of Vehicles 1940 207.8 1.9 31.7 241.4 N.A. 1950 293.7 3.2 54.4 351.3 77 1960 458.3 3.4 71.9 533.6 88 1970 795.8 ' 3.5 129.7 929.0 117 1973 953.0 3.4 182.0 1,138.4 128 Percent Shares 1940 86.1 0.8 13.1. 100 1950 83.6 0.9 15.5 100 1960 85.9 0.6 13.5 100 1970 85.7 0.4 13.9 100 1973 83.7 0.3 16.0 100 Source: Derived from U. S. Dept. of Commerce, Bureau of the Census, Stat. Abstract '75, pp. 571 and 564. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Table 10 Freight Traffic, Shipments, and Average Length of Haul, USSR,.1973, by Carrier, in Billions of Metric Ton-Kilo- meters , Millions of. Metric Tons, and yalcTneters Ton-Kilometers (Billions) Tons Originated '(Millions) Average Haul "(Kilometers) Railroads 2,958 3,346 884 Highways 284 18,244 16 Waterways 190 419 453 Pipelines 439 421 1,043 Four-Carrier Total 3,871 22,430 173 Source: TsSU, Narkhoz SSSR 1973, pp. 503, 504, 510, 516-17 Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 17 maritime freight traffic is domestic, moving between Soviet ports, and should be included, though it is not covered in table 10. Soviet internal waterways are not as favorably located (e.g., the Volga River system does not directly connect Moscow with the eastern Ukraine or the Urals, nor is there a good water connection between the Urals and western Siberia) as those in the United States, and the volume of Soviet waterways freight traffic is thus only about a third of the U.S. level. Soviet pipelines, though less well developed than U.S. pipelines, are already moving almost 40% as much as U.S. pipelines over longer average distances. The aggregate volume of Soviet freight traffic, using comparable coverage, would probably be some 10Z-15% greater than U.S. intercity freight traffic. This aggregate measure is hard to interpret, since it covers differing commodity structures in the two countries' freight traffic, reflecting in turn the differences between the two economies in their output composition. Soviet intercity passenger traffic is only about one-third as great as passenger movement in the United States. The difference lies mainly, of course, in the absence of appreciable intercity travel by passenger automobile (it is not yet even estimated in Soviet transpor- tation"statistics). In marked contrast to U.S. railroads, Soviet rail- roads are still carrying an increasing volume of intercity passenger traffic; in 1973 they handled almost six times as many passenger- kilometers as U.S. railroads handled in 1950. Soviet bus traffic, similarly, in 1973 was six times the 1950 U.S. level. Soviet air traffic has been growing very rapidly and, in 1973, reached about 40% of the 1973 U.S. level. Modest movement on inland waterways is about the same in both. economies. While this is not the place to examine them in detail, Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 DOMESTIC INTERCITY PASSENGER TRAFFIC, USSR, BY CARRIER, SELECTED YEARS, 1950-1973 (in billions of passenger-kilometers) Railroads Buses Airways Inland Waterways Sea Total 1950 88.0 5.2 1.2 2.7 1.2 98.3 1955 141.4 20.9 2.8 3.6 1.5 170.2 1960 . 170.8 61.0 12.1 4.3 1.3 249.5 1965 201.6 120.5 38.1 4.9 1.5 366.6 1970 265.4 202.5 78.2 S.4 1.6 553.1 1973 296.6 253.9 98.8 5.9 1.9 657,1 Percent Shares 1950 89.5 5.3 1.2 2.8 1.2 100 1955 83.1 12.3 1.6 2.1 0.9 100 1960 68.5 24.5 4.8 1.7 0.5 100 1965 55.0 32.9 10.4 1.3 0.4 100 1970 48.0 36.6 14.1 1.0 0.3 100 1973 45.2 38.6 15.0 0.9 0.3 100 Source: TsSU, Narkhoz '73, p. 500 Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 major issues of national policy surround the question of whether the relative absence of intercity passenger automobile movement in the USSR can, or should, continue in the future. Table 12 shows the length of railroads and highways in the USSR in a format similar to that of table 5 above. One notes that, though the Soviet railroad network is very large, it has only about one-third the length of the U.S. system before the latter began contracting. Most observers would say that the U.S. system was overbuilt, but perhaps this crude comparison suggests that additional railroad mileage will be useful for the Soviet economy. As to highways, the contrast is most striking: in 1973, the U.S. had 3.6 times as long a road system as the USSR, and for surfaced highways the ratio was 6.6 to 1. Russian and Soviet writers have been commenting on the problem of "roadlessness" in Russia for at least a century and, clearly, much remains to be done. Foreign visitors riding along the skeletal existing paved highway system are unlikely to be aware of the lack of paved roads throughout most of the country. The data on Soviet urban passenger traffic in table 13 show how rapidly it has increased during the postwar period. The total number of passengers carried per year has risen from 9 to 53 billion, almost all moved by traditional carriers. The growth constrasts sharply with the U.S. decline shown in table 7 (the latter, of course, confined to the minority who do not travel by passenger automobile). In the USSR since 1950, the number of passengers carried by autobus has risen very rapidly, as has the much smaller number who use taxis. In 1950, streetcars dominated the scene, but their volume of traffic has been declining since 1965 and now accounts for only 15% of the total. Trolley bus, subway, and railway commutation traffic has steadily increased though not to the Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 TABLE 12 LENGTH OF RAILROADS AND HIGHWAYS, USSR, SELECTED YEARS, 1940-1973 (in thousands of kilometers) Highways Surfaced Unsurfaced 1940 106 143 1,388 1,531 1950 117 177 1,373 1,550 1960 126 271 1,095 1,366 1970 135 512 852 1,364 1973 137 598 800 1,398 Sources: TsSU, Transport i Sviaz SSSR (1972). pp.89, 262 Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Auto Bus 1950 1,001 1955 4,294 1960 10,797 1965 17,771 1970 25,901 1973 30,458 1950 11.5 1955 28.8 1960 43.3 1965 51.2 1970 56.2 1973 57.6 URBAN PASSENGER TRAFFIC, USSR, BY CARRIER SELECTED YEARS, 1950-1973 (in millions of passengers carried) Street car Trolley Bus Subway Railway Taxi Total 5',157 945 629 955 43 8,730 6,367 1,858 937 1,392 45 14,893 7,842 3,055' 1,148 1,713 389 24,944 8,242 4,298 1,652 2,049 717 34,729 7,962 6,122 2,294 2,616 1,144 46,039 7,998 7,298 2,727 2,970 1,461 52,912 Percent Shares 59.1 10.8 7.2 10.9 0.5 100 42.8 12.5 6.3 9.3 0.3 100 31.4 12.2 4.6 6.9 1.6 100 23.7 12.4 4.7 5.9 2.1 100 17.3 13.3 5.0 5.7, ' 2.5 100 15.1 13.8 5.1 5.6 2.8 100 Sources: TsSu, Transpoii.. i Sviaz,.(1972) pp. 99-100, 244, 246-47, 256-57; Narkhoz 173, pp 504, 522-23, 525, Nark hoz '58, p. 588 (for autobus 1950 and 1955). Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 same extent as bus traffic. These summary data are not conclusive, but they suggest that urban public transit carriers in the USSR have a record of healthy growth. Analytic Contrasts Between United States and Soviet Transportation. Behind these statistics for the two continental economies lie several fundamental contrasts in the conditions facing transportation agencies and the users of their services. It is worth noting them briefly for the light they shed on the problems that systems analysis can deal with. The most important concerns relations between supply and demand. In the United States, the demand for transportation confronts an ample supply of transportation capacity. Almost everywhere, in fact, increments of transportation demand could be quickly accommodated by at least one carrier, and rival transportation agencies are eager to handle more traffic. In the USSR, however, transport demand presses hard on transport supply, both freight and passenger, and added demand is not easily accommodated. The Soviet government did not inherit an over- built railroad system, nor has it put major resources into a well- developed system of local, district, and interregional paved highways. Soviet transport capacity has barely kept up with burgeoning demand. In the United States, the typical producing enterprise can choose among multiple sources of supply for its inputs, multiple routes linking the supplier with the enterprise, and multiple carriers to provide the freight service. The availability of alternatives gives the enterprise considerable leverage in obtaining good service. Prompt and flexible adjustments are facilitated since bottlenecks at particular points can Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 be bypassed. Speed and reliability of service are encouraged. There may be costs imposed on the overall economy by excess capacity in the transportation sector, not continuously and fully utilized, but these costs may be more than offset by benefits to the overall economy in reduced inventories, faster production, improved product quality, and speedier adaptation to customer needs. Several of the following research papers focus on factors that enter into the economic decisions made by shippers under these conditions. United States transportation agencies need accurate information on what their customers want, since without this information the carrier may not obtain and ratain the shipper's orders. The factors that enter into travelers' choices among modes of travel and specific passenger carriers are the object of similar analysis. Railroads, airlines, bus lines, and trucking firms in the United States are not free to set the conditions under which they offer service, solely on the basis of their own con- venience and internal cost-minimizing considerations. The choices made by shippers and travelers have a decisive influence on the growth and welfare of the transport sector. Other papers concentrate on ways that systems analysis is used by United"States transportation agencies to minimize their operating costs and provide efficient service. Mr. Johnson's paper shows how railroads use computers to keep track of freight cars and how trucking firms match trucks with shipment flows. Mr. Ehrlich's paper shows how Eastern Airlines uses an elegant systems analysis to find a cost-minimizing solution to the problem of assigning aircraft and flight crews.to a pattern of flights offered the public, a pattern which has already been carefully tailored to fit the evidence on what the public desires. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 24 The delegation of United States transportation specialists was impressed in July 1975 by what they heard and saw concerning the ways that Soviet transportation agencies are using systems analysis and computers. Clearly, simlar problems lead to similar answers. Soviet analysts are searching for cost-minimizing solutions in the internal operations of the carrier. Railroads plan their heavy freight traffic flows, and the Moscow subway carefully monitors its heavy passenger traffic. Aeroflot uses its ticketing and reservation service to mini- mize empty-seat-kilometers, and the maritime fleet keeps track of its farfiung merchant marine. Intracity Soviet truck traffic is centrally organized in interesting ways that go beyond the decentralized operations of United States trucking firms, suggesting that Soviet methods of trucking might be a fruitful topic for joint analysis. In spite of the differences between the USSR and the United States in balances of supply and demand for freight and passenger transportation, it seems clear that a great many problems of efficient operation for each means of transportation can usefully be studied by very similar methods of computer-aided systems analysis. Here an exchange of operat- ing experiences and a comparison of analytic methods can be illuminating for experts on both sides. In addition, it seems to us that further study of the factors influencing the demand for transportation, both in the minds of shippers and in the minds of travelers, can serve the interests of the Soviet economy even though intercarrier competition is absent. Long-run growth and efficiency in any economy require that economic activity should respond correctly to the objective needs-of consumers and producers, and for the transportation sector this means that demand-sensitive analysis is necessary, no matter who own the means of product`u roved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 FREIGHT DEMAND MODELLING: A POLICY SENSITIVE APPROACH Mark N. Terziev, Moshe Ben-Akiva, and Paul 0. Roberts 1. INTRODUCTION Determining the volume of cargo that will flow in a given freight market is the starting point for any quantitative analysis of freight policy. This is true whether the issues being addressed are those of a carrier who would like to consider changes in a particular pricing policy or a government attempting to justify the major capital expendi- ture for a new facility. In spite of what appears to be an obvious need for analysis tools, very little work has been done to provide such a capability in the freight area. One may account for this situation in several ways. First, there has not been data available to use in model development. This is not a condition that should be allowed to continue to exist since the data could be obtained once the needs are known precisely. Second, there has not been a clearly articulated statement of purpose for such a model. This is understandable in the light of rising government interest in the problems of the freight sector. Finally, the lack of an adequate theoretical framework has hindered both the collection of data and the statement of purpose for the appropriate analytical tools. This lack is one which we intend to address directly in this writing. Demand Supply Equilibrium in Freight Markets First, it is appropriate to attempt to clear up the second deficien- cy, the lack of a clearly stated purpose. This can best be done by putting the demand forecasting element into perspective relative to the demand-supply equilibrium of freight markets. The shipper of freight makes a number of decisions which influence the size and nature of the * Director, Center for Transportation Studies and Professor, M.I.T. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 market between any two points. It is useful to take the viewpoint of the shipper in constructing the demand element of an equilibrium model of the system. The attributes of the commodity being shipped and the characteristics of the shipper and the markets in which he is engaged will be important, as will information concerning the transportation system available to the shipper in making his decisions. These characteristics of the transportation system are influenced directly by the decisions made by the carriers competing in a given freight market. The size and type of equipment, its scheduling, reli- ability, etc., all determine directly, along with the tariff, the level of service which the shipper will receive and ultimately influence his demand for service. The supply element of the system treats the decisions made by the carrier in his offerings. Equilibrium occurs in the system because of the range of choice that exists and the feedback nature of the information between supply and demand. Thus, as the tariff for transport by one mode increases relative to alternative modes there is diversion to the lower cost modes by those shippers most sensitive to shipment costs. The output of the equilibrium process includes the volumes of shipments by the different modes of freight transport and the levels of service experienced by the shippers at these shipment levels. (See figure 1.1.) The Role of Government in the Process The process is influenced by government in a variety of ways, all on the supply side. Government typically controls entry, mergers, owner- ship, finances, rates, and routes by means of the regulatory agencies. Through the executive and administrative agencies taxes, tax credits, Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 FIGURE 1.1 NATURE OF THE EQUILIBRIUM PROCESS COMMODITY, SHIPPER AND. MARKET ATTRIBUTES MANAGEMENT OF CARRIER PRODUCTION PROCESS N' DEMAND FOR TRANSPORT SERVICES SUPPLY OF TRANSPORT SERVICES LEVELS OF LSERVICE EQUILIBRIUM PROCESS TRANSPORT VOLUME LEVELS GOVERNMENT, TAXATION REGULATION AND INFRASTRU?TUBE Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 tolls, subsidies, environmental and safety standards are set and transport infrastructure is provided. In those efforts government is attempting to act in a manner that is equitable and in the best interests of its constituency, within a rather broad interpretation of the meaning of this phrase. Making the Models Policy Sensitive For any set of models to be policy sensitive they must incorporate the variables reflected in the policies of interest. Thus, if the policy involves the impact of a change. in equipment on the competitive advantage of a particular mode, the supply models must be able to represent these changes in the level of service as they will eventually be perceived by the shipper. If the policy involves a change in pricing, the level of service vector must reflect the new tariff as seen by the shipper. A variety of supply side models may be needed to explore the full range of policies of interest since the control variables employed directly by the government and the carrier are on the supply side. On the demand side the different policies are represented by the list of characteristics making up the level of service vector. If a level of service vector can be specified which captures the principal deter- minants of travel demand on the part of the shipper, then a demand model employing this level of service vector can be used to handle a large range of policy alternatives. Each of the policy alternatives to be studied must be transformed by the supply models into the variables in this vector. As a consequence, one well-specified demand model can handle a variety of supply side policy investigations. Of course, specifying the variables to be incorporated in the level of service vector will be an imports t undertaking. . nApproved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 28  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Role of Each Element in the Equilibrium Process Each of the elements of the system has a different function. The demand model attempts to replicate the decision-making behavior of an individual shipper of a commodity faced with a number of alternatives. This behavior varies with the attributes of the product being shipped, the shipper, and the market. The supply models-must transform the policy variables under study into a level of service vector for each alternative which might be chosen. Both are involved in the equilibrium process since the level of service inputs into the demand element may not elicit travel demand volumes which are compatible with the original level of service estimates produced by the supply element. The volume must be consistent with the level of service at equilibrium. Our focus here is on the demand element since it is the least developed and the most crucial in some sense. That is, once a policy to be investigated has been transformed into the level of service attri- butes using even the roughest of supply models the volume levels can be obtained. Even if the transformation of the policy into level of service attributes is done on a completely intuitive basis, the model can be useful.- Therefore, it is necessary to consider the possible range of policy-questions which might be addressed. Possible Users of Such a Model A fundamental understanding of the way in which freight flows are determined would be of use to government planners, policy-makers and regulators, as well as carriers and shippers. An analysis of freight flows is required for the evaluation of government policy options in the following areas of interest: Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 1. Freight transportation facility planning in various corridors 2. Economic analysis of projects involving the modification or expansion of the freight transportation systems 3. Impact of changes in regulation which affect the price and level of service of freight carriage 4. Overall modal policy planning Carriers would also benefit from a better understanding of how their supply policies interact with the shippers' demand for the trans- port of goods. The major areas of concern to the carrier include the following: 1. Analysis of potential markets 2. Impacts of changes in the level of service 3. Impacts of changes in pricing policy 4. Evaluation of changes in regulations 5. Determining the feasibility of new services Shippers would like to coordinate their short-run policies with their long-run plans. However, the complex interaction of the shippers' behavior with the policies of the other parties makes the task of coordination very difficult. A better knowledge of this interaction process would help shippers deal with the following issues: 1. Evaluation of location options 2. Determination of capacity allocation and production plans Possible Policy Issues to be Investigated with the Model Perhaps the most important set of issues facing transportation policy-makers today are those dealing with the future of the railroads. How can they be made more competitive? Are there ways to rationalize the network with line abandonments, mergers, or government ownership of Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 the right-of-ways? Would new, advanced, multimodal services be success- ful? If so, how should the services be priced? How should tariffs be established? What impact would new services have on conventional service? For any of these to be handled in more than a superficial manner, a demand model of the type described here is necessary. Another important set of policy questions is concerned with dereg- ulation. The analysis of deregulation policies can be undertaken on a market-by-market basis with the techniques outlined here. To address the questions at a more macroscopic level it will be necessary to place the demand model into a more aggregate framework and consider the system- wide impacts. This model, however, represents the necessary first step in such a process. Policies involving fuel conservation and air quality have recently received attention. The demand element is especially important in this area since the ability to predict the impact of various policies on the overall level of demand may be crucial. The extent of the impact on choice of mode or shipment size of various transportation control strat- egies may also be of concern. Many other questions such as truck size-weight issues, expansion of the interstate system, rate absorption in ocean shipping, the imposition of tolls on inland waterways, the development of the domestic air freight system, etc., can be addressed. The key is the translation of the policy questions into level of service vectors for each of the alternatives under investigation, using either a formally developed set of supply models or good intuitive judgement as previously suggested. The demand model is therefore a crucial element in any quantitative analysis whether the policies to be investigated are those of a private sector entrepreneur, Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 a public sector decision maker, or a legislative body seeking the impact of proposed changes in legislation. The Need for Data on Shipper Behavior At the present time, forecasting freight movements is not widely done. A good bit of freight movement data exists, but it is hard to coordinate and use the data. Their volume alone makes it difficult to deal with. This would not be such a problem if the data did not lack several crucial elements needed for accurate forecasting. The data currently available are largely historical flows, by commodity, over given corridors and specific facilities. The response to government or carrier policy is by the shipper. Thus, the shipper's views are extreme- ly important. To be useful, the data must capture the behavior of the shipper. In making his choice, the shipper views the alternatives that are available to him and makes his choice between them based on the conditions of transport and the relative costs. Data concerning the choices made by the shipper rarely exist. It would be difficult to use the data on shipper behavior if it were available only in tabular form. It is necessary to capture the values of the shipper; for example, how he weighs transit time as opposed to reliability or cost. This can be most easily done by the use of a carefully structured econometric model which captures and makes available the "valued" choices of the shipper. This is not to say that these are not useful in their own right. Quite the contrary, there are a wide variety of uses for the data, including the calibration of other models for other uses. At the moment, however, data on the choice behavior of shippers is unavailable in.a coordinated and useful form. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Why Policy-Sensitive Freight Demand Models Don't Currently Exist Part of the reason the data does not exist and why models which incorporate it also do not exist is because the models of the past were not behavioral models. Instead they were aggregate models which captured correlations of aggregate quantities rather than individual shipper behavior. The development of disaggregate behavioral models using modern methods of econometrics is fairly recent. The development of data sets which can be used to calibrate or test them has not yet been accomplished. New methods for predicting passenger travel demand have advanced very rapidly over the past few years. The profession has come a long way since the invention of the "gravity model." Disaggregate behavioral econometric models employing less data collection and more efficient data utilization have been developed (CRA, 1972; Ben Akiva, 1973). The disaggregate approach appears to be equally attractive for freight demand models. In fact, preliminary investigations have shown that disaggreagte freight demand models are both workable and encour- aging. The impact of this new modelling approach is likely to have considerable more import than the various aggregate econometric models developed during the past ten years. The pioneer efforts were illustra- tive, but not very practical for prediction purposes. The Role of Data Collection The design of such a model must proceed in conjunction with the design of a data scheme and methods for data collection. Disaggregate models require much less data for calibration than aggregate models and, therefore, it is nowt entirely practical to gather the data needed for a freight pp Approved Re ease 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Objective of Current Work The overall objective of this research effort is to build upon the existing work that has been done in freight demand modeling by employing the recent developments in disaggregate passenger travel demand models. The first steps in this direction are to review existing sources of data (including disaggregate data sets if they are available) and to survey the literature on freight demand models with particular emphasis on previous research done on disaggregate models. The major elements of this research effort are the specification of a system of policy-sensitive disaggregate freight demand models based on a realistic theory of shipper's choice of origin, destination, frequency, shipment size, and mode of transport, and the specification of data requirements and their collection methods. Ultimately, this methodological phase should be followed by actual data collection, model estimation, sensitivity tests and validation, and, finally, the use of these models as policy analysis tools. 2. FRAMEWORK FOR FREIGHT DEMAND MODELLING In this section the framework for freight demand modelling is des- cribed in terms of the specific shippers' choices and the variety of factors that determine the pattern of commodity flows. Shipper Behavior ` The pattern of freight flows results from the actions of numerous actors. As noted previously, the basic decision-making unit in determin- ing the demand for freight transport is the individual shipper. Depending upon the ownership of the freight, the decision-maker is usually located at either the origin or the destination of a shipment. The behavior Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 that leads to a demand for freight transport can best be described from the point of view of this individual decision-maker. A strategic decision (and the most long-range action of any shipper) is a choice of location. For intercity freight the location of produc- tion plants and warehouses substantially determines the requirements for, and the characteristics of, available freight transport services.1 For a given set of production and consumption points, the pattern of commodity flows is determined by the individual shipper's selection of markets and suppliers. The quantity of freight of commodity type k that the producer at point i is shipping to his warehouse at destination j, for example, is determined by the shipper's choice to market his product in a specific volume in the market area served by the warehouse at point J. Given the quantity of commodity k shipped from origin i to destin- ation j over a certain time period, an individual shipment (as represented by a waybill) is determined by the choices of mode m and shipment size q. There are a variety of feasible combinations of modes and shipment sizes that can be used to transport a given annual volume between two locations. Note that the annual volume and the shipment size also deter- mine the frequency at which shipments are made. The Choice Hierarchy Thus, the basic unit of commodity flow--the individual shipment-- is determined by a complex hierarchy of choices made by an individual shipper. This hierarchy is depicted in figure 2.1. The sequence that is assumed in this hierarchy represents the different time lags in a shipper's response to achange in transport policy. For some shippers Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 FIGURE-2.1 HIERARCHY OF SHIPPER CHOICES Choice of location and level of activity Choice of markets and/or suppliers locations and volumes Choice of transpor mode and shipment I size Commodity . Flows V~ Y?3 .Vk ijmq Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 and commodity types, the transport mode and shipment size may be altered on very short notice and at a very small cost. However, a location change almost always requires significant time and capital expenditures. It is important to note that this choice hierarchy does not imply a long-run, sequential, causal relationship. In a long-range decision, a lower-level choice such as the choice of the transport mode, for example, influences the choice of location, and vice versa. This means that a lower-level choice is determined in two ways: strategic (long run) and tactical (short run). A change in a higher- level choice is likely to result in a reconsideration of all lower-level choices. Thus, in a strategic decision all the choices are jointly determined, and in a tactical decision some high-level choices are fixed and only lower-level choices are adjusted. Another important implication of this hierarchy is that at any given point in time we are likely to observe a shipper at a disequilibrium point. There is a threshold level below which level of service changes do not influence shippers' choice in the short run. For this reason, we can observe an inefficient pattern of commodity flows which are due to the cost involved in adjusting the choices high on the choice hier- archy. Factors Affecting Shipper Behavior The freight transportation situation at the level of an individual shipper can be described in terms of four groups of characteristics. First, there are shipper attributes which include those characteristics relating to the location of the plant, the location of supplies, and long-run operating policies. Second, there are market attributes which Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 are related to both the long-run choice of markets and the short-term equilibrium demand for the commodity being shipped. Third, there are commodity attributes which include the physical characteristics of the good as well as information concerning its handling and use. The fourth group consists of transport level of service attributes which depend not only on the mode, but also the commodity being shipped and the shipment size being considered. In the long run, the choice of location, the level of activity, the shipment size, and the choice of mode are variable at the discretion of the shipper. The commodity being shipped is assumed fixed, and a unique commodity type is associated with each basic decision-making unit. Commodity Attributes The list of commodity attributes that influence the demand for freight transport might include the following: 1. Value per pound--basic commodity value at the origin 2. Shipping density--both of the basic commodity and of the commodity when packed for shipping 3. Shelf life-number of days to spoilage or obsolesence 4. Product use--manufacturing, processing, final consumption 5. Method of inventory control--single-item, multi-item 6. Stockout consequence--no cost, contribution loss, proba- bility increase with days, shutdown A shipper would also consider the temporary storage facilities associated with the commodity being shipped, although this is variable over the long run. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Shipper Attributes Some shipper attributes which are fixed in the short run are variable in the long run and are determined by the strategic decisions at the top of the choice hierarchy. The choice of plant location and the choice of suppliers and markets fixes the distances over which each commodity must be transported. The choice of plant size (level of activity) brackets the range in the volume of each commodity which must be moved. These considerations are summarized by the following variables: 1. Annual production volume--amount produced 2. Number of establishments--number of production plants 3. Location of establishment--on rail siding, water access, etc. 4. Ownership--whether producer owns the freight 5. Price at origin--whether price is established at factory 6. Decision-maker--point where inventory decisions are made A shipper would also consider the use of private carriage. This would effectively replace the short-run mode choice decision with along-run investment decision. Market Attributes Market attributes reflect the market demand for the commodity being shipped. For the most part, the market equilibrium is variable over the short run but it can be assumed to be external to the freight demand decision. Therefore, market attributes influence the intermediate decisions relating to the level or volume of shipment. The market variables that influence shippers include: 1. Sales in consuming industry--amount consumed Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 2. Size of consuming industry--number of firms consuming 3. Characteristics of consuming population--socioeconomic characteristics 4. Size of consuming population--number 5. Location of establishment--on rail siding, etc. 6. Ownership--whether supplier owns the freight 7. Price at destination--whether price is established C.I.F. destination 8. Decision-maker--point where inventory decisions are made Mode/Size Choices In the short run the shipper is left with only the choices of mode and shipment size. The mode shipment size options considered by a shipper include all or some of the following: 1. Freight forwarder 2. Airfreight parcels 3. Air container 4. Private truck 5. Contract carrier 6. Common carrier truck LTL 7. Common carrier truck FTL 8. TOFC Plans I-V 9. Rail FCL 10. Rail unit train 11. Inland barge 12. Barge container 13. Sea container 14. Pipeline Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 In some cases, these tactical options will be precluded by higher order strategic decisions. For example,, the choice of plant location, supplier location, and market location will determine whether rail, barge, air, and pipeline are available options in the mode choice decision. Level of Service Attributes Once the list of possible mode/shipment size alternatives has been edited down to the available short-run options, then the final decision will be based on the modal level of service attributes. For each avail- able option this group of characteristics 1. Waiting time 2. Travel time 3. Time reliability 4. Loss and damage 5. Transport tariff 6. Other costs 7. Minimum shipment size 8. Special services The factors influencing shippers' behavior are summarized in figure 2.2. Here an overall view can be gained of the interrelationships between the variables which are important in the process. We now turn to an examination of the existing literature to determine the extent to which models employing these variables in the appropriate way already exist in useful form. 3. LITERATURE REVIEW A number of studies of freight demand have appeared in the transpor- tation and economics literature during the past ten years. The demand Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 C 0 C7 LU a Ra.. LL- C) 4JJ3 L I1 L 4j ro 4J ze Q -r- 1 4) C C a) rn ?O .C 4- C L SO.. 4- r O 0 Cl a) O r? C r- r 4.) rE L r0 O ro N to ru r-- O ] O 1 N (0 N Cl) U C > E aJ V (1) gCg ?r c[ -0j . .1~ CL N U Cl. ?r 4.3 C U. 4~ 0) C ??- C N C Q1 C 4) E 4) ?SS. E o 4- .C 0 N r ?r C a) = r O N 4?) C L U1 L O +) N 4.3 ?r m ro O 4- C 4.1 ?r U C to C r- ?r +?/ C N 0 U1 4?) to O r- 0-0 .C ro ?r O 00 L () O .r r0 N 4-) CL 4-) 4J 1- Ln a) C N C O t 0) O CO N (1) 0) N r-?r N?r 0.U N 0. U Cl) gC ?r 'v N I/) 00. t/) _0.1 O 0. V! w V Iw - N 4) 4-, ?r = o +r 11 I~ O r go V ?r C W UU< ? 0 } a) a) 4.) U 0)) W ?r i?1 ?r E L?r4J 4-) o>a C1L. C:) C r N N?r ?r Q) C 4/Y S- il 4- ?r ro ro L Oct 3 F- a) N a) N 0 4- Q. O > Cl r N m 4-3 U 0 C 4- L O C ?r fU 3C O > ?r C S- C: V) O CL H CL Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 models developed in these studies generally fall into two categories and representative models from both groups are discussed in this section. The first group consists of very simple, macroscopic models which pre- dict only the total freight flow between all origins and destinations. The data required to calibrate this type of model is relatively easy to find and therefore most of these models have been empirically estimated. The principal use of these models is for the prediction of the impact of system-wide changes in prices or the level of service. The second group of models consists of microscopic demand models which address the problem of predicting the freight flow between origin- destination pairs. These models include variables relating to specific operations. Therefore, these models can be used to analyze policy operations dealing with operations on particular links in the freight transportation network. However, very few of the microscopic demand models have been thoroughly tested, although some preliminary empirical work has been done. The analysis of different freight transportation policy issues requires models with different levels of detail. Therefore, a freight demand model may not necessarily be applicable to all policy evaluation tasks. Both micro and macro models are useful tools. Sloss (1971) Sloss has presented a model for predicting the total volume of inter- city freight traffic carried by trucks. The dependent variable in his model is the annual tonnage of goods transported by for-hire trucks on intercity hauls (denoted Vt). The independent variables are: the average truck revenue per ton (Ct), the average rail revenue per ton (Cr), and Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 a variable representing the general level of economic activity (E). The economic activity variable was defined as the unweighted sum of farm cash income, the value of building permits issued and the value of shipments of manufactured goods. These variables were combined in a product form model which was calibrated using regression analysis. The general form of the model is: Vt a a0 C t a 1 Crag Ea3 The data for the model were obtained from annual reports published by the Dominion Bureau of Statistics in Ottawa, Canada. Sloss's empir- ical results imply that the volume of truck traffic is directly related to the price of rail service and inversely related to the price of truck service. Sloss also concluded that the quantity of truck traffic is positively correlated with the general level of economic activity. These results seem intuitively reasonable. Sloss's model could be used for a macro-level evaluation of alter- native pricing strategies. However, it could not be used to evaluate other system-wide options dealing with changes in operating speeds, improvements in reliability, etc. Nor could this model be used to pre- dict the impact of a policy dealing with changes in the price of carriage of a particular commodity between a particular origin and destination. A. D. Little (1974) As part of an analysis of domestic waterborne shipping, A. D. Little, Inc. has developed a model which predicts the percentage of intercity freight traffic moved by water carriers. Unlike most other models which Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 have appeared in the literature, this model emphasizes the strategic (long-run) aspects of the mode choice decision. In this model, the level of service variables such as time and cost have been replaced by variables which indicate the compatibility between the shipper's operations and the operations of waterborne carriers. For example, the following variables have been used to characterize shippers in a BEA region:2 1. Total flow--used because ships and barges are best suited for carrying high volumes 2. Value per ton--used because water modes typically carry low-value goods 3. Bulk commodity indicator--used because ships and barges are well suited for the loading and unloading of bulk goods 4. Seasonality--used because the high fixed cost of dock facilities makes it desirable to maintain a high volume of usage throughout the year It was found that these four variables are highly correlated with the fraction of plants located on bodies of water in BEA regions. No direct measures of level of service were included in this model. However, two proxy variables were included to represent the differences between the barge and truck (and rail) levels of service as they might be perceived in the long run. These variables are the highway distance (approximately the same as the rail distance) and the ratio of the water route distance to the highway distance. The variables described above were used in a nonlinear equation to predict the fraction of traffic moved by water carriers. The data used in this study were records of flows of fifteen commodity groups between BEA regions. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 In terms of policy analysis, strategic models of this kind can be quite useful. First, they can help identify key variables to use as long-run policy instruments. Second, they point out how the inherent advantages of a mode interact with shipper attributes and market attri- butes in the long-run decision-making process. However, it is obvious that these models cannot be used for the evaluation of specific pricing and operating policies which affect long-run, as well as short-run, shipper behavior. Perle (1964) Perle conducted one of the first major studies of freight demand. Perle used product form models with prices as the only indication of the level of service on each of the models. He calibrated one model for the total volume of truck freight and a second for the total volume of rail freight. The independent variables in both models are the average rail rate (Cr) and the average truck rate (Ct). Perle used dummy variables to represent the influence of certain commodity groups and certain regional characteristics. Since he was using time series data, he also included a dummy variable to represent the year. But he did not use any market attributes or variables related to the size and state of the economy. The general forms of the models are: brr brt ( r Ri Vr - arCr Ct i eri Tj Zk j drj k frk V btr btt In Ri t - atCr ~t i eti n Tj a Zk) j dtj k ftk Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Ri - 1 if observation is in ith region Tj - 1 if observation is in jth year - 0 otherwise Zk - 1 if observation is in kth commodity group - 0 otherwise Perle used ICC reports to find the total tons carried by each mode during several years. This data was then used to calibrate several variations of the basic model shown above. On the whole, Perle's models did not fit well. Several of the esti- mated coefficients had the wrong sign. However, the dummy variables representing commodity specific effects and regional effects significantly improved the fit of the models. The dummy variable representing the year was less useful. These results indicate that further effort should be made to explicitly include commodity and market attributes in freight demand models. In terms of policy analysis, the uses and shortcomings of Perle's models are similar to those of the Sloss model. His models can be used for the evaluation of pricing options which would affect an entire system. But Perle's models cannot relate price changes on particular hauls to impacts on traffic in particular market segments. Moreover, they neglect many other policy variables such as travel time and reli- ability. Nevertheless, Perle's work is an important contribution to the field of freight demand analysis. He used a careful, methodological approach and his results demonstrate the importance of commodity and market attributes. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Mathematica (1967) Mathematics did some theoretical-work in freight demand analysis as part of the Northeast Corridor Transportation Project. One of the models which they proposed is an adaptation of the Quandt/Baumol abstract mode model used in passenger demand modeling . The general form of the model V . a0 P al P a2 Y a3 Y a4 M as M a6 N a7 (Tb )bo(Tr )bi(Cb )do(Cr ) dl ijm i j i j i j ij ij ij ij ijm where: Vijm - volume of freight flow from i to j by mode m Pi, Pj a population of the origin and destination Yi, Yj ? gross regional product of the origin and destination Mi, Mj ? industrial character indices such as the percent of the labor force employed in mining and manufacturing Tij = least shipping time from i to j Tijm . travel time by mode m divided by the least from i to j Cij . least cost of shipping from i to j Cijm - cost of mode in divided by the least cost from i to j Nij . number of modes serving i and j Unlike the other models discussed above, this model deals with the flow of goods between particular origin-destination pairs. Furthermore, this model contains a greater range of market attributes and level of' service attributes, although it does neglect a significant number of policy variables, such as time reliability. A second flaw in the Quandt/Baumol model involves intermodal effects. In this model, changes in the cost and time on an inferior mode will have Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 no effect on the volume carried by the "best" model. This is certainly counter-intuitive. It is not readily apparent how the model could be modified to avoid this problem. Mathematics (1967) Mathematics has also proposed a freight demand model completely unlike those discussed above. This model was developed through the application of classical microeconomics and inventory theory. Without going through the derivation of the model, the general line of develop- ment is: 1. Express total annual variable transportation costs of the industry in city j which is receiving commodity k from city i as the sum of the direct shipping costs, total in-transit carrying costs,and safety inventory costs 2. Differentiate total cost to get marginal cost and apply the optimality rule that marginal cost equals marginal revenue Under some assumptions about the cost functions and some approximations to make the algebra work, the following demand function was derived: ijm - a0 + a1 (VP1j) + a2 Cijm + a3 (S1 Tijm) + a4 (S1 + Tijm)l/2 Vijm - volume of commodity k moving from i to j by mode m VPij - the difference in value of commodity k between city i and city j " time between shipments of commodity k to j Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Tijm ' average travel time of commodity k from i to 9 on mode m This kind of microeconomic, inventory-based model might be a good policy evaluation tool for a shipper doing an analysis of his location options and general operating policy. It may not be obvious from the general form of the model, but the following important factors are implicitly represented by the variables and parameters: 1. interest rate on capital 2. value of the commodity 3. price elasticity of demand for the commodity 4. warehousing costs 5. rate of sales of the commodity 6. cost of stocking-out of the commodity 7. ordering costs The derivation of the model from a microeconomic point of view allows the inclusion of these important factors. However, the transition from a model of an individual firm to a model of the aggregate behavior of all firms in the origin city was not made explicit in the Mathematica report. It is not entirely clear how the aggregation issue should be handled for disaggregate models of this type. Antle and Haynes (1971) Antle and Haynes have suggested still another approach to freight demand analysis. They used a linear discriminant function to predict the choice of mode, given some basic information about the shipment. The general form of their model is: ~p1oe834 Refie-s'% z0~47 -1/ 19a:5t.:64-R 9-(t0r i9r000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 where: X1 = annual tonnage shipped X2 = distance by principal mode X3 = average travel time by principal mode X4 = average shipment size X5 = rate on principal mode X6 = rate on competing mode X7 = handling cost on principal mode These seven independent variables are used to characterize a single shipping decision. To use the model, the values for a principal mode and a competing mode are substituted into the model and a value of Z is calculated. This value is compared with a test value Z to predict whether the principal or the competing mode will be chosen. If the distribution of each of the independent variables is known for a given commodity, for a given origin-destination city pair, then the volume Vim can be estimated. So, even though this model is based on discrim- inant theory, it can be used to produce the same kind of demand infor- mation as the other models discussed in this section. The Antle and Haynes model was calibrated on a small amount of data that was collected on the shipment of coal, coke, petroleum, and chemicals by barge and by rail in the Upper Ohio River Valley. Using just the section of the data on coal shipments, they estimated a model with only four significant independent variables: travel time and rate on the principal mode, shipment size, and handling cost. Although this model fitted the data reasonably well, it should be regarded with some suspicion because it lacks so many important variables. The failure of the rate on the competing mode to appear in the calibrated model was Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 particularly disappointing. This model could be used to study the volume of coal carried by each mode on a particular link in the freight transportation network. However, the model contains no commodity attributes, which means that a separate model would have to be calibrated for each commodity being studied if the model is to be used to evaluate policies related to particular goods. Despite its shortcomings, the Antle and Haynes study is important because it helped pave the way for the application of stochastic, disaggregate qualitative choice models to freight demand. Rullman (1973) Rullman used a binary logit model with aggregate data to predict the truck-rail modal split as a function of level of service attributes, commodity attributes, and market attributes. The general form of his model is: (Rail Share Commodity k ` Truck Share i to j f (distance, annual volume, value per ton, difference in rail and truck freight rates, difference in rail and truck transit time, difference in rail and truck transit time reliability) As a policy tool, Kullman's model has several desirable characteristics. It includes a number of level of service variables, including reliability. It also includes annual volume consumed, which is a market attribute. Furthermore, Rullman's model is to some extent commodity abstract because it includes commodity value. (See p. 38, last paragraph.) Although this model does neglect some important factors, it is a relatively sophisticated example of a microlevel model. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19: CIA-RDP79-00798A000200020005-9 As a tool for microlevel analysis Kullman's model has three short- comings. In the first place, it should include a wider range of commodity and market attributes as well as some shipper attributes. Secondly, Kullman's empirical work has shown that several important levels of service variables (such as travel time reliability) cannot be represented by aggregate data. Aggregate reliability data contains very little variation among observations and, therefore, the effect of reli- ability on mode choice cannot be determined. Third, since it is only a modal split model, in order to predict Vk ijm' an external estimate of the total volume of commodity k moving from i to j must be provided. The major contribution of Kullman's model is the inclusion of a wider range of variables than most other models. It also demonstrates the feas- ibility of using the logit model in freight demand analysis. Hartwig and Linton (1974) The work of Hartwig and Linton is the most recent effort in the area of disaggregate freight demand modeling. They used the logit, probit, and discriminant functions to model the individual shipper's mode choice between full-load truck and full-load rail. The data base used in this study consisted of 1213 freight waybills for full-load truck and rail shipments of consumer durables. From the bills they determined: 1. The origin and destination of the shipment from which they determined mileage 2. The date shipped and the date received from which they determined transit time 3. The freight rate and total charge 4. Shipment weight Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 5. The type of commodity being shipped from which they found the value per unit of the shipment In their models, Hartwig and Linton used the difference in truck and rail transit times, the difference in truck and rail freight charges, the difference in truck and rail reliability (as measured by the differ- ence in the standard deviation of the transit time distributions) and the value of the commodity as the independent variables. The dependent variable as in the Antel and Haynes and Kullman models is the mode choice probability. Using these variables, they experimented with logit, probit, and discriminant models. In general, they found that both logit and probit performed well, while the discriminant approach yielded some- what poorer results. The Hartwig and Linton study indicates that the disaggregate logit model can be used very successfully in freight demand modelling. However, their model needs to be expanded if it is to be used as a microlevel policy tool. Market attributes and shipper attributes should be added along with some additional level of service variables. Furthermore, the addition of commodity attributes would make the model useful to analyze a wider range of commodity types and differential process policies. In summary, a number of models have been developed and tested which can be used in macrolevel policy analysis. To date, these models have not been used extensively. More detailed models capable of predicting flows of particular commodities between particular cities have developed more slowly. The principal reason for the slow progress in this area is the scarcity of data at the required level of detail. Nevertheless, this second type of model is a potentially powerful method for performing a detailed analysis of intercity freight operations. It is important to Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 note that, given a microlevel demand model, an appropriate model for macrolevel analysis can in principle be developed by aggregating the micro model over the distribution of its independent variables. This aggregation of microlevel demand models is discussed in the following section. 4. DISAGGREGATE MODELLING OF SHIPPER BEHAVIOR This section presents a brief description of the methodology suggested for modelling shipper behavior. The approach outlined here avoids many of the problems presented in the work which has been done to date as described in the previous section. The recommended approach involves the use of a disaggregate behavioral model. Why T)isaggregate Models? A freight demand model is most likely to be used in a study of freight facilities and policies or for a market analysis of freight movements of a certain type. The forecasts required are not for the individual shipper's freight demand but rather for some aggregate patterns of freight movements. Since the basic decision-making unit for freight demand is an individual shipper, it follows that the aggregate demand is simply a sum of individual shipper's demands. The starting point for a freight demand model formulation is a theory of the behavior of an individual shipper. However, for the aggregate forecasting of freight demand, the model of individual shipper's behavior must be aggregated. The aggregation is based on groupings of shippers by their geographical locations, industry type, etc. If data is avail- able at the level of the individual shipper, then this aggregation can be performed either before or after model estimation. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 An aggregate model is estimated, using the means or totals of the variables included in the model for an aggregate group of shippers. Sometimes parameters of the distributions of the independent variables within the aggregate groups are also included. A disaggregate model is estimated, using the values of the variables for individual shippers. The aggregation for forecasting is then performed by integrating the disaggregate demand model over the distribution of the independent variables' values for the aggregate group of shippers. The advantages of estimating a disaggregate model are numerous. One of the most important points is their efficient use of data. Since the data is not aggregated prior to model estimation, less original data is required to obtain reliable estimates of the model's coefficients. Aggregate data is characterized by a significant loss in the variability of important variables. Therefore, estimation of an aggregate model often fails to produce reliable coefficients for variables such as reliability, waiting time, etc., which do not vary substantially between large geographic zones but have considerable variations within these zones. Because a disaggregate model is not estimated using averages for specific aggregate groupings, it is not tied to a specific area or a specific aggregation scheme. Once estimated, a disaggregate model can be used for a wide range of applications at different areas and different levels of detail without a need for model reestimation. Disaggregate freight mode choice models have already been estimated on a trial basis by Hartwig and Linton (1974) and by Antle and Haynes (1971). These studies have proven that a disaggregate modelling approach is workable and attractive for freight demand modelling. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Modelling Qualitative Choice4 At the level of the individual shipper (or the single shipment), the decisions with respect to transport mode and shipment size, for example, are characterized as a selection from a set of qualitative alternatives. In qualitative choice, the alternatives can be indexed but cannot be rank ordered. Locational, modal, and shipment-size choices are characterized as qualitative choice problems. Consider an individual shipper making a selection from a set of alternatives At where i and j denote alternatives in the set. For example, the set of alternatives for a model of mode choice and shipment size, includes all the feasible combinations of available modes and shipment sizes. For a model that includes a destination choice as well, the set of alternatives includes all combinations of modes, sizes, and destinations. Each alternative in the choice set is associated with some measure of attractiveness (cost) which the shipper is attempting to maximize (minimize). Given that one and only one alternative is selected from the choice set then alternative i will be selected if and only if: Uit > Ujt, V j c At where Uit denotes the attractiveness of alternative i to shipper t. In a mode choice problem, for example, this implies that mode i will be selected if and only if its attractiveness is greater than or equal to the attractiveness of any other mode that is available. The attractiveness of alternative i is a function of the. attributes of the alternative (e.g., transit time, rate, loss and damage, consump- tion rate at destination, etc.). Two types of attributes directly Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 influence short-run freight shipment decisions: transport modal attri- butes (or level of service attributes) and market attributes. However, the same transport alternative will be evaluated differently by different shippers of different commodities. Thus, the attractiveness of a given freight transport alternative is expressed as a function of shipper and commodity attributes as well as the attributes of the alternatives. Given data on the observed behavior of shippers and the values of the important attributes, the attractiveness functions must be estimated if we are to be able to forecast freight demand under varying conditions. Due to measurement errors, unobservable information, and other deficiencies in the available data, we are, in general, unable to estimate these attractiveness functions with certainty. Therefore, the deter- ministic choice criterion will not always correctly predict the actual choices. We can express the attractiveness of an alternative as consist- ing of two parts, observable and random, as follows: Uit uit + #it (1) where uit is the observable part of the attractiveness function and eit is an observable random element. If the attractiveness measures of the alternatives include random components, then only the probability of choosing each option can be predicted, rather than a deterministic choice. The probability that alternative I will be selected by shipper t equals the probability that the attractiveness (cost) of alternative I is greater or smaller than, or equal to, the attractiveness (cost) of all other alternatives that are available. Formally, this statement can be expressed as follows: Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 P(i:At) - Prob [Uit >-U jt9 I e At] (2) where P(i:At) is the probability of shipper t selecting alternative I from his choice set At. Substituting equation (1) in (2) we get: P(i:At) - Prob [cjt - 'it < uit uit, i c At] (3) This expression implies that the joint probability distribution of the random components determines the form of the model that relates the systematic attractiveness functions to the choice probabilities. One specific assumption about the random elements joint distribu- tion leads to the multinomial logit model which is the only probabil- istic choice model that has been extensively applied to multiple choice problems. The random elements are assumed to be independently and identically distributed as follows: -w P(E- z W N M O I[) u') N S3 AOW 30 % a 0 In U) N S3A0W J0 % 0 co W -t 0 ? uI : z 0O a W a 0 M U) N S3AO 4 J0 % n 5 0 Qf 10 Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 O ? o L I I I o 0 0 0 0 0 0 0 J.NIOd 83OUO38 Approved For Release 2001/11/19 : CIA-RDP79-00798AO00200020005-9 1 -L----J- 0 0 0 o o 0 a 0 w 0 1- o z ar C; z U- 0  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 w 5i to I 1 L iO O O. o 0 ON o 0 O 0 0 0 (0 to cr N .I.NIOd U3C18OJ8 Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 I I I I I 0 0 0 0 0 0 rn OD fl.- to %-AVO -2 1 0 to . 88 Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 high mean transit times tend to be the most unreliable. Perhaps more meaningful from a rail operations perspective, it appears that the number of terminals at which a car is handled is the major determinant of perfor- mance. For example, consider figure 6. aLK5 is a measure of variation in transit time. Those moves with zero intermediate yardings exhibit slight variation and hence tend to be reliable. Those with two intermediate yards are substantially less reliable. On the basis that moves with more yardings are the long distance moves in a system, one might argue that distance is the cause of the unreliability. Some evidence that these reliability differences are caused by the number of intermediate yards rather than the distance is shown in figure 7. That this relationship between terminals and origin-destination service exists is not surprising when one considers rail operations. It is the nature of railroad operations that a car encounters numerous oppor- tunities for delay as it moves from its origin to its final destination. At each yard, cars moving to common, intermediate, or final destinations are consolidated into "blocks," placed in a train consisting of one or more blocks, and handled together to another yard which may be twenty or more than a thousand miles distant. Whenever a car is set off from a train or the train reaches its destination, the car is reswitched and consolidated with other traffic into a new block and a new train. This procedure is repeated until the car reaches its final destination. This process of switching and consolidation necessarily results in longer transit times than would be required for direct movement (such as by unit train). Equally as important, this process is unreliable. That is, each time a car is switched, the potential for a missed connection at that yard exists. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 N N I 0 co D ~A = w ..+N m I-- --~b D S`lnVH 3NIl*'1b101 30% 0 0 S-1nVH 3NI1 1VIOI 30 % 0 0 0~0 VQ' N S1nVH 3NI-I -1V.101. 30 % H 'Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/1.1/19 : CIA-RDP79-00798A000200020005-9 N N W W J O ~ Q 0 O } 0 } a N N A V NO N I 0 0 SWVd 0-0 dO % r-I 0 0 V N SWVd 0-0 d0 % 0 0 `- SUM 0-0 dO % U) cc N : 0 O H 0 0 SJIVd 0-0 d0 % 0 N L) = N I- ~ LL- O b U I qT 0 S?J IVd 0-0 d0 % 0 0 SdIVd 0-0 d0 % Approved For Release 2001/11/19: CIA-RDP79-00798A000200020005-9 W W F- Q  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Missed connections are critical in that they often lead to car delays in the order of twelve-twenty-four hours (the time until the next appro- priate outbound train), large variations in transit time and, hence, unreliable performance. Table 1 shows the magnitude of transit time delay and transit time variance as a function of the probability of a missed connection at a yard. These probabilities are quite realistic in the light of the various analyses of railroad operating data.6 AVERAGE DELAY TIME AND STANDARD DEVIATION OF DELAY TIME AS A FUNCTION OF THE PROBABILITY OF A MISSED CONNECTION Probability of Average Standard Deviation of Transit Missing Connection Delay (Hours) Times (Hours Among the causes for missed connections are outbound train cancel- lations, train length/weight constraints, RIPS, NO-BILLS, and late arrival of an inbound car. This last cause has been shown to be an important one. Specifically, if the car arrives later than some "threshold" time, its connection with an outbound is often missed. Of course, the outbound train could be held for the car, allowing the connection to be made despite the lateness of the arrival. However, this may well lead to further problems. Specifically, Belovarac and Rneafsey7 have shown that the primary cause of late arrivals at a yard is late departure from the preceding yard. Hence, holding trains to allow particular connections to be made may well lead to inbound lateness at succeeding yards and the possibilities of other missed Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 connections. Indeed, Folk8 had examined "no-hold" versus "hold" policies with respect to overall network effects on car performance. All in all, the question of yard performance and missed connections is a complex one, with the various components and operating policies of the rail network heavily interacting to affect performance. These research results indicated that potential for improvement in service existed through operating strategies that would either avoid inter- mediate yardings of cars (i.e., run-through trains) or improve the proba- bility of making connections when yardings were necessary (e.g., by opti- mizing inbound/outbound train connections or by limiting cancellations). A case study was performed in cooperation with the Southern Railway9 and various experimental alternatives designed to improve service were imple- mented. These implementations did lead to service improvements in the Southern's system and have been integrated into the Southern's continuing operating plan. IV RESEARCH NEEDS With the previous as background, this paper goes on to discuss research needs of the rail industry in the area of service and service reliability. The research needs that exist are subdivided into two major areas as follows : 1. The shipper's perspective 2. The supply of transportation service IV-A THE SHIPPER'S PERSPECTIVE The area can be further subdivided into the shipper's demand for transportation service and the shipper's operating response to rail Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 service.  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 IV-A-1 DEMAND From the viewpoint of the author, the major gap in rail service research (and, in fact, in freight service in general) is on the demand aide of the question. Specifically, we have only the most preliminary and intuitive ideas about the relationships between level of service provided by the industry and the volume and traffic mix attracted by the industry. There is a great shortage of knowledge about what service the shipper community actually wants and needs and, more importantly, how the shipper will make his model choice decision as a function of the service provided. Making major investment decisions or operating decisions in the absence of demand models (i.e., models for understanding the volume complications of service decisions) seems quite difficult. Yet, this seems to be what the industry does (although specific instances of demand sensitivity or insensitivity have been documented). Thus, a major research priority should be the development of a level- of-service and commodity-sensitive demand model for use as a planning tool by the rail industry in making investment decisions. Of potential major benefit in this endeavor may be newly developed, disaggregate, demand- modelling methodology. This methodology has the potential for overcoming what has long been the major roadblock in the development of such models; namely, the lack of an adequate data base.10 We should note that there is by no means complete agreement in the industry on what constitutes service and how service relates to demand. For example, in informal discussions, various rail officials have indi- cated that the shipper does not see himself as "buying" reliability from the industry and that modest changes in volume (if any) would occur were service reliability to be dramatically improved. By the same token, other Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 rail officials have indicated that service improvements can lead to sub- stantial attraction of new business. In fact, neither contention has been supported by a comprehensive set of data, models, and analysis. In addition to the obvious needs for data, other preconditions exist for success in this effort. Perhaps most important is the market's per- ception of what rail service is. In order to develop consistent and usable demand models, performance measures that are useful from the shipper's perception must be developed. Of course, these measures must exist (or be capturable) in the data base used in model calibration. In summary, to quote from existing work: If a railroad does not know how service levels affect traffic volumes, then that railroad does not know what product it should produce.11 Such a modelling effort will allow the industry to better understand this issue. IV-A-2 SHIPPER'S OPERATING RESPONSE TO RAIL SERVICE The previous section focussed on the attraction (or lack thereof) of traffic as a function of service. A second shipper-related area is composed of the operating behavior of a shipper who is, in fact, using rail. and how this behavior may be related to the quality of rail service. Shipper behavior and procedures are an important component in the utilization of the rail industry's resources. For example, consider car detention. A not-insignificant portion of the car cycle is time-spent with the car in shipper control.12 An empty car may wait to be loaded for some time and a loaded car may be used as a rolling or stationary warehouse by the consignee. Often demurrage is not an adequate incentive for the shipper to load or unload the cars. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 96 The working hypothesis here is that this shipper behavior is closely related to the service provided by the industry. For example, one reason advanced by the shipper community for "excess" car detention on loading is that poor car-availability leads to very conservative car- ordering policy. This, in turn, may lead to empty care waiting for long time periods at the shipper's siding if they are,in fact, delivered in a timely fashion. Unrealiable delivery of empties or spotting of loads may also lead to "erratic" shipper behavior because the shipper has difficulty in scheduling his crews around the undependable service provided by the industry. The above suggests that improvements in service (and service relia- bility in particular) may pay extra dividends in terms of an improvement in the car detention situation. That is, if the rail industry provides more reliable service, equipment utilization can be improved because of better shipper performance which can, in turn, lead (through better avail- ability of equipment) to still better rail services. Another related area is the regularization of shipper demands on the rail system. The irregularity of shipper demands causes poor allocation of resources as the rail system attempts to respond to peak demands for service (difficult to predict). This poor distribution of resources leads in turn to degradation of service on the network taken as a whole. Regularization of shipper demands can potentially lead to better service for all shippers. Again, a feedback phenomenon exists. Possibly, if service reliability can be improved, shippers can be enticed to regularize their inputs to the system, which will allow the rail industry to improve service still further. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The above are but two examples of the interaction of the shipper with the rail system. In all, there appears to be a great deal we do not know about shipper behavior patterns and how these relate to rail service. A research effort in this area can yield very meaningful results from the viewpoint of improved service and shipper satisfaction with rail service. IV-B THE SUPPLY OF TRANSPORTATION SERVICE. The improvement of the transportation service provided by the rail industry can take place on three fronts. These are: 1. Rail operations 2. Capital Expenditures on Rail Facilities 3. Institutional Changes To put these needs in perspective, it's important to note that the previously described M.I.T. research, virtually all of which is supply- oriented, has merely scratched the surface of the field. This research has 1. Described some service measures 2. Isolated some of the root causes of rail service unreliability 3. Developed various models that can be useful in improving rail service 4. Demonstrated the usefulness of these models in one particular operating theatre This research has had major limitations. It has focussed on the operating theatre only and, further, (in its implementation) has focussed on local and individual changes to operations and not on global changes to network operations. In short, there is a great deal to do in research in this area. The remainder of this section goes on to describe these research needs on the Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 supply side.  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 IV-B-1 RAIL OPERATIONS It is clear that changes to rail operations can cause major impacts on rail service. What is less clear is how best to proceed and how much these changes are likely to cost (or save). Three areas are discussed, these being: 1. Impacts of Network Wide Operating Changes 2. Data Systems 3. Cost Models Impacts of Network Operating Changes The previous research has shown that local changes in rail operations (e.g., changing a single inbound/outbound train connection) can lead to the desired service effect. What needs to be better understood is the benefits (from a service perspective) of wholesale, network-wide changes to rail operations. Models for the prediction of the benefits of imple- mentation of: 1. Blocking policy changes 2. Scheduling policy changes 3. Train length policy 4. Through trains carried out on a network basis are badly needed. It should be noted that a wide variety of models that begin to address these issues are available. Network simulation models have been developed by many railroads and by the industry through the A.A.R.13 These models allow an analyst to simulate rail operations at very fine levels of detail and can, in theory, be very useful in the examination of such issues as those noted above. However, it is the author's impression that these models have not been partiA t dwP&X R 449gbOW1 A0&e014MD OONS? OOf 5-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 questions. Why this is true (if indeed it is) is not clear. While these models have sometimes been criticized for being too expensive or difficult to use, it seems obvious that the costs of running the models will be trivial compared with the costs of implementing some operating change in the rail system. Given this situation, it is recommended-that the micro- simulation approach to rail network modelling be reexamined afresh to ascertain why efforts along these lines have not been particularly fruitful to date in the rail industry (unlike the experience in other industries such as air transportation, manufacturing systems, etc.). If, in fact, conceptual problems with the microscopic approach can be isolated, further research on correcting these deficiencies is indicated. In parallel with this reexamination of the traditional approach to rail systems modelling, some new approaches are appropriate as well. For example, less detailed network modelling approaches have proven fruitful overseas. In particular, ROUTESTRAT,14 developed by British Railways, has been very useful in scheduling and blocking the BNR system. This model, which simulates the operation of the systems at a rather macroscopic level works toward optimizing (rather than simply simulating) the rail system. Granting at the outset the major differences between the U.S. system and the British network (e.g., size, one-owner), it would still appear fruitful to consider the usefulness of such a modelling approach in rationalizing rail operations in this country. Data Systems This discussion of research needs in rail operation should go no further without alluding to the question of data systems. This is the topic of several other presentations so we need not dwell on it here. However, Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 as a precondition to improving service, the industry needs to measure what it is doing in rail operations and how well it is performing. Data systems that will allow the industry to perform such measurements are essential. There has been a good deal of progress in this area over the past several years. Among the major efforts are the work in terminal management systems performed under the auspices of the Labor-Management Committee1s as well as Southern's TPA,16 Southern Pacific TOPS,17 and other network control programs. While certainly the industry is in a much better position to measure its service than it was even a short time ago, further refinement of rail data systems is needed. In particular, for our service perspective, the need to measure performance on interline moves is clear. Also of major importance is capturing the portion of the move from shipper's dock to originating yard and from terminating yard to consignee's dock. These local moves are missing from many data systems and yet appear to have a major impact on service reliability. The above systems reflect the ability of computer and information system'technology to measure performance with an eye to isolating problem areas which can then be improved. This is but the first step in the use of computers, however. Research into utilizing the computer to allow the industry-to operate in ways inconceivable without the information processing and real time capabilities of the machine is needed. The author believes that the potential of this technology has barely been touched and that service and operating improvements of major impact are within the industry's grasp using this tool. Cost Models A final subject of proposed research in the rail operations area is twop the relatiApproved he- For elease 2s001/1 T/19 : CIA-RDP79 00798A00D200020005 9e  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 industry needs better ways of understanding the cost implications of various operating alternatives and levels of service. The relationships here are not at all well understood.18 One fascinating aspect of this cost question is the notion that im- proved levels of service (and, in particular, improvements in'mean transit time and service reliability) can yield better redistribution of empty cars and deadheading power, less inventorying of empties, better shipper car-detention performance, a shorter car cycle, and therefore, better equip- ment utilization. Hence, under certain circumstances, one may actually be able to lower costs while providing better service. The relationships described above are shown pictorially in figure B. The development of useful cost models is an industry-wide problem. What is emphasized here is that such models be designed in such a manner that the implications of operating changes (and service improvements) can be readily computed. These cost models, taken together with the service-sensitive demand models described earlier, would give the railroad analyst the ability to evaluate fully the implications of service quality modification from the profitability viewpoint. The relation among the various models is described pictorially in figure 9. IV-B-2 CAPITAL EXPENDITURES ON RAIL FACILITIES The potential changes in rail operations described in the previous section are characterized by being implementable within a short period of time. The implicit assumption is that these changes are being implemented within the constraints of existing resources. The area under discussion in this section relates to somewhat longer-term changes. These are changes in the physical facilities available to the rail-operating department, Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Strategies for Im.Oroving Reliability / Direct ` Indirect Impacts Impac t / Reduced Trip Times Improved Distribution Of Empties Increased Traffic Levels .1 1 Shorter Load/Unload Times Improved Freight Car Utilization Increased Operating Efficiency Reduced Need Ability to For New Cars Move More Traffic Capital Costs Ope 1 rating Revenues and Costs PROFITABILITY FIGURE 8 A MODELLING FRAMEWORK Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 103 Operating Changes Network / Cost Models Service Changes Demand Models Volume and Traffic Mix Implications Shipper Operating Behavior Models Cost Implications Rail Industry Profitability FIGURE 9 IMPLICATIONS OF SERVICE QUALITY MODIFICATION Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 104 obtained through a capital investment program. The research area is the development of models for effective investment planning and for providing a useful framework for rail investment planning. The need is for models that will allow the analyst to predict the impact of particular investment alternatives on service quality and operating costs and hence to he able to make an informed choice among investment alternatives. However, these individual impact prediction models are but a first step. The inherent difficulty in developing such models is compounded by the environment in which investment decisions among alternatives is being made. 1. The investment alternatives are not independent--there are many different investments under consideration at any Point in time. Yard con- struction and upgrading, rolling stock of different types, power, electrifi- cation, new track, and structure are but several of the investment possi- bilities available. A new level of difficulty is introduced when one recog- nises that the impact of various alternatives on service and cost are not independent. For example, the impact of the purchase of new power units is related to whether or not a particular terminal is upgraded. How these impacts interact is a difficult modelling issue, as in the complexity intro- duced by the fact that the combinations of investments can grow to be extremely large. 2. There is a great deal of uncertainty in the system. The railroad investment planner faces the classic case of decision-making under un- certainty. Among the major stochastic elements in the process are: A. Traffic levels B. Levels of investment in the future C. Competitive and regulatory elements Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 D. Uncertainty in the prediction abilities of the impact models themselves.  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 In all, the railroad investment problem is a topic worthy of sub- stantial research. In addition'to the development of a variety of impact models (the most notable needs being in the area of yard design and capacity and placement of terminals in the network), a framework for rail investment planning under uncertainty is needed. This framework could usefully build upon the work of Pecknold19 which deals with multistage investment planning in highway systems. In summary, investment decisions should be made with service quality in mind. A basic research need is the development of a framework for the understanding of the impacts on service quality of various investment decisions taken in various combinations under conditions of uncertainty with respect to future traffic and investment levels. IV-B-3 INSTITUTIONAL CHANGES Operating changes are implementable in short order. Changes derived from capital expenditures take somewhat longer. Still longer term in nature are various institutional changes. These are changes in the basic frame- work within which the industry operates. By their very nature, insti- tutions were constructed in such a way as to strike a proper balance between various interest groups and any attempt to change (at a particular point in time) "the system" is likely to appear to some group as an attempt to take away some hard-won gains. Yet, while implementation difficulties are inherent in the-process, research into the impacts of proposed changes is appropriate and useful. If the impacts on all actors (industry, labor, shippers, government, etc.) can be understood, trade-offs can be established and compromises reached. There are any number of institutional issues one could address. For the purpose here, only those with quite direct impact on service and Apps Fr*11Q@WJ4dti0' 3iM ."1? $ DP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 106 Work Rules The relation between operating policy and service quality is clear. Likewise, the relation between operating policies and current operating work rules is strong. A better understanding of how work rules affect operating policies (particularly train length20) and how relaxation of particular rules can lead to service improvements is needed. Network Shape Issues How the rail network is physically configured and how resources are allocated to this network are closely related to service and service quality. At the same time, network shape is institutionally bound up with the regulatory climate, specifically the I.C.C. Network changes occur very slowly (e.g., through abandonment and mergers), mostly as a result of regulation. A more precise understanding of how service quality relates to network configuration would be useful in illuminating the trade-offs inherent in any network change alternative. Fractional Per Diem The rail industry operates on a 24-hour per diem system, with a midnight cut-off. Of current research interest is the possibility of implementing a fractional per diem system. Both 8-hour and hourly systems have been suggested. An understanding of the service implications of these alternatives is required. Organization Structure in Railroad Companies The typical railroad company in the U.S. has not changed its organi- zation form for decades. By no means is it clear that the railroad company is optimally structured to address the service needs of its shippers. The organization form of some companies seems more suited to the basically noncompe titly 1~~I~tp9-~07a.1'82~3at MPPI VV clearly no longer exists.  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 107 A fresh look at how a rail freight transportation company should be structured to be able to address 'today's issues and the issues of the future is needed. Such questions as: 1. How are investment decisions reached? 2. What are the basic information flows in the company and are they the right ones? 3. What is the proper training for a railroad executive? 4. Is the traditional departmental structure of the industry operating, transportation, traffic, etc.) the optimal one? 5. How are level-of-service versus cost trade-offs made? Who makes them? Much work has been done on organizational structure.21 Some attempt to utilize these efforts in the rail industry is appropriate. V SUMMARY Research needs in the area of service reliability have been described. Two major areas have been discussed. These are the shipper's perspective and the supply of transportation service. Within the first of.these is the area of highest priority in the author's view, namely, the development of a better and more quantitative understanding of the relation between service quality and the demand for rail freight service. Also noted here as a lower priority was the issue of the shipper operating responses to rail service and how these are related to equipment utilization and, hence, to rail costs and service. The supply of transportation service was subdivided into the areas of rail operations, capital expenditures, and institutional changes. setting of priorities here is difficult in that the areas are interrelated and research costs are likely to be very different in size. However, the Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 author is inclined to set priorities as follows: Impacts of Network-Wide Operating Changes on Service (IV-B-1 p. 98) Impacts of Various Capital Investment Alternatives on Service (IV-B-2 p. 101) Data Systems (IV-B-1 p. 99) Overall Investment Framework (IV-B-2 p. 101) Cost Models (IV-B-1 p. 100) Various Institutional Changes (IV-B-3 n. 105) Hourly Per Diem Work Rules Network Shape Organization Structure A final comment. Service and service reliability is without question an important issue in the rail industry. It is also a researchable question. However, research is not enough. It can only highlight the needs and suggest industry strategies. A continuing and disciplined program of imple- mentation, experimentation, and innovation within the rail industry is re- quired if this research is not to produce a set of dust catchers. By the same token, the research community should discipline itself to produce intellectually sound but pragmatic, implementable, research results. Based on recent experiences with the interaction of the rail industry and the research community, the author has confidence that a great deal can be accomplished in the future in this area. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 BIBLIOGRAPHY 109 America's Sound Transportation Review Organization. The American Railroad Industry Today: A Prospectus. Washington, D. C., June 1970. Association of American Railroads. Yearbook of Railroad Facts. Washington, D.C. 1971. Belovarac, K. and J. S. Kneafsey. Determinants of Line Haul Reliability. Studies in Railroad Operations and Economics, vol. 3. Research Report R72-38, 1972. Ben-Akiva, Moshe. "Structure of Passenger Travel Demand Models." Ph. D. dissertation, M.I.T., June, 1973. Marc Terziev and Paul Roberts. "Freight Demand Modelling A Policy Sensitive Approach." Center for Transportation Studies, M.I.T., presented to the 47th National Operations Research Society of America meeting, Chicago, Illinois, April, 1975. Chandler, A. D., Jr. Strategy and Structure. M.I.T. Press, 1962. Charles River Associates. The Role of Factor Prices in Transportation Planning for Developing Countries. Study for the Office of Inter- national Affairs, U. S. Department of Transportation. Folk, J. F. "Models for Investigating the Unreliability of Freight Shipments by Rail." Ph.D. dissertation, M.I.T. Operations Research Center, 1972 (unpublished). Models for Investigating Rail Trip Time Reliability. Studies in Railroad Operations and Research, vol. 5, Research Report R72-40, 1972. Some Analyses of Railroad Data. Studies in Railroad Operations and Economics, vol. 6. M.I.T. Research Report R72-41, 1972. A Brief Review of Various Network Models. Studies in Railroad Operations and Economics, vol. 7. M.T.T. Research Report R72-42. Hartwig, James and William Linton. Dis aggregate Mode Choice Models of Intercity Freight Movement. M.S. Thesis, Northwestern University, Depart- ment of Civil Engineering, June, 1974. Jennings, A. A. "The Effect of Train Length on the Reliability of Operation of Freight Yards." S.M. thesis. M.I.T. Department of Civil Engineering, 1972 (unpublished). Kneafsey, James T. Costing in Railroad Operations: A Proposed Methodology. Studies in Railroad Operations and Economics, vol. 13. M.I.T. Research Report R75-15. Kolsen, H. M. The Economics and Control of Road Rail Competition. Sydney, Australia: Sydney University Press, 1968. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Kullman, Brian C. "Choice of Mode Between Rail and Truck in the Intercity Freight Market." Ph.D. dissertation, M.I.T. Department of Civil Engi- neering, 1972 (unpublished). Lang, A. S. and R. M. Reid. Railroad Car Movement Reliability: A Prelimi- nary Study of Line Haul Operations. Studies in Railroad Operations and Economics, vol. 1. M.I.T. Research Report R70-74. and C. D. Martland. Reliability in Railroad Operations and Economics. Studies in Railroad Operations and Economics, vol. 8. M.I.T. Research Report R72-74, 1972. Martland, Carl D. Rail Trip Time Reliability: Evaluation of Performance Measures and Anaylsis of Trip Time Data. Studies in Railroad Operations and Economics, vol. 2. M.I.T. Research Report R72-37, 1972. Improving Railroad Reliability: A Case Study of the Southern Railway, Studies in Railroad Operations and Economics, vol. 10. M.I.T. Research Report R74-28. Procedures for Improving Railroad Reliability, Studies in Railroad Operations and Economics, vol. 12. M.I.T. Research Report R74-30. "Origin to Destination Unreliability in Rail Freight Trans- portation," Engineer's thesis. X.I.T. Department of Civil Engineering, 1972 (unpublished). Midwest Research Institute. The AAR Network Simulation System, program documentation for the network simulation model developed for the Associ- ation of American Railroads, 1971. Moody's Investors Corporation. Moody's Transportation Manual. New York: Moody Publishing Co., 1971. O'Doherty, J. D. "Classification Yard Effects in Rail Freight Movement Reliability." Civil Engineer's thesis, M.I.T.,1972 (unpublished). Pecknoid, Wayne M. "Evolution of Transport Systems: An Analysis of Time Staged Investment Strategies Under Uncertainty." Ph.D. thesis, M.I.T., 1970. Project Team of Labor/Management Task Force on Terminals. A Program of Experiments Involving Changes in Terminal Operations on the St. Louis Terminal Division Missouri Pacific Railroad 1974 Progress Report. Railroad Systems and Management Association. The Measure of RAilroad Freight Service. Chicago, Illinois, 1972. Reebie Associates. "Toward an Effective Demurrage System." Final Report to the Federal Railroad Administration, July, 1972. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Reid, R. M., J. D. O'Doherty, J. M. Sussman, and A. S. Lang. The Impact of Classification Yard Performance on Rail Trip Time Reliability. Studies in Railroad Operations and Economics, vol. 4. M.I.T. Research Report R72-39, 1972. Roberts, P. 0., Jr. "The Logistics Management Process as a Model of Freight. Traffic Demand." Harvard Business School Working Paper, HBS71-11, April, 1971 , and D. T. Kresge. Techniques of Transport Planning, vol. It. The Brookings Institution, 1972. ROUTESTRAT. British Railways, 1973. Sussman, Joseph M. "A Systems Model of the U.S. RAilroad Industry." pre- sented at the ORSA/TIMS meeting, Chicago, April, 1975. and Carl D. Martland, Reliability in Railroad Operations: Execu- tive Summary. Studies in Railroad Operations and Economics, vol. 9. M.I.T. Research Report R73-4, 1972. Improving Railroad Reliability: A Case Study of the Southern Railway, Executive Summary. Studies in Railroad Operations and Economics, col. 11. M.I.T. Research Report R-74-29. Southern Pacific Railway. Total Operations Processing System (TOPS). Southern Railway. Time Performance Analyzer Manual, 1971. Transportation Association of America. Transportation Facts and Trends. Washington, D.C., 1971. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 112 1. J. Sussman, "A Systems Model of the U. S. Railroad Industry" presented at the ORSA/TIMS National meeting, Chicago, May 1975. 2. Joseph Sussman, Carl D. Martland, and A. Schaffer Lang, Reliability in Railroad Operations: Executive Summary, Studies in Railroad Operations and Economics, vol. 9, M.I.T. Report R73-4, 1972. 3. Carl D. Martland, Rail Trip Time Reliability: Evaluation of Performance Measures and Analysis of Trip Time Data, Studies in Railroad Operations and Economics, vol. 2, M.I.T. Report R72-37, 1972. 4. A. Scheffer Lang and Carl D. Martland, Reliability in Railroad Operations, Studies in Railroad Operations and Economics, vol. 8, M.I.T. Report R72-74, 1972. 2 5. a LH is the variance of transit time. 6. Robert M. Reid, John D. O'Doherty, Joseph M. Sussman, and A. Scheffer Lang, The Impact of Classification Yard Performance on Rail Trip Time Reliability, Studies in Railroad Operations and Economics, vol. 4, M.I.T. Report No. R72-39, June, 1972. 7. K. Belovarac and J. T. Kneafsey, Determinants of Line Haul Reliability, Studies in Railroad Operations and Economics, vol. 3, M.I.T. Report No. R-72-38, June, 1972. 8. J. F. Folk, Models of Investigation Rail Trip Time Reliability, Studies in Railroad Operations and Economics, vol. 5, M.I.T. Report No.-R72-40, June, 1972. 9. Joseph M. Sussman and Carl D. Martland, Improving Railroad Reliability- A Case Study of the Southern Railway, Studies in Railroad Operations and Economics, M.I.T. Report 74-29, 1974. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 10. Moshe Ben-Akiva, Marc Terziev and Paul Roberts, "Freight Demand Model- ling: A Policy Sensitive Approach," Center for Transportation Studies, M.I.T. presented to the 47th National Operations Research Society of America Meeting, Chicago, Illinois, April, 1975; James Hartwig and William Linton, "Disaggregate Mode Choice Models of Intercity Freight Movement," M.S. thesis, Northwestern University, June, 1974; and Moshe Ben-Akiva, "Structure of Passenger Travel Demand Models," Ph.D. disser- tation, M.I.T., June, 1973. 11. Carl D. Martland, Procedures for Improving Railroad Reliability, Studies in Railroad Operations and Economics, vol. 12, M.I.T. Report R74-30. 12. Reebie Associates, Toward an Effective Demurrage System, Report FRA-OE-73-1, National Technical Information Service PB 212-069. 13. Midwest Research Institute. The AAR Network Simulation System, program documentation for the network simulation model developed for the Associ- ation of American Railroads, 1971. 14. ROUTESTRAT. British Railways, 1973. 15. Project Team of Labor/Management Task Force on Terminals, A _Program of Experiments Involving Changes in Terminal Operations on the St. Louis Terminal Division Missouri Pacific Railroad, 1974 Progress Report. 16. Time Performance Analyzer Manual, Southern Railway, 1971. 17. Total Operations Processing System (TOPS), Southern Pacific Transpor- tation Co. 18. J. T. Kneafsey, Costing in Railroad Operations: A Proposed Methodology, Studies in Railroad Operations and Economics, vol. 13, Research Report R75-15, 1975. 19. Wayne M. Pecknold, "Evolution of Transport Systems: An Analysis of Time Staged Investment Strategies Under Uncertainty," Ph.D. disser- to +vet?IIoTReIWg?2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 20. A. Scheffer Lang and Carl D. Martland, op. cit. 21. Alfred D. Chandler, Jr., Strategy and Structure, M.I.T. Press, 1962. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 CURRENT APPROACHES TO TRAVEL DEMAND FORECASTING* ** Marvin L. Manheim 1. Introduction One purpose of this paper is to present a brief overview of the major methods now in use in the U.S. for forecasting future passen- ger travel in urban areas. Many of these methods have been applied also to forecasting intercity and national passenger travel and to predicting freight movements as well. In the next section, we summarize some of the issues currently being addressed in urban transportation planning studies in the U.S. Then we review briefly the basic theory of transportation systems analysis underlying travel forecasting methods. In the fourth sec- tion, we summarize the major alternative approaches available today and show their interrelations in section 5. Examples of two major approaches are given in section 6. The last section presents our conclusions. 2. The Role of Travel Forecasting Models in the Analysis of Tranpor- tation Plans and Policies Now, more than ever before, a multiplicity of urban and regional objectives is leading to the proposal of a wide range of policies to control and shape travel patterns. The number, range, and complexity of these proposed policies is unprecedented. In order to appraise the * This paper draws upon numerous articles and reports to which many other individuals have contributed. Where specific acknowledge- ment is practical, appropriate references have been cited. The author particularly wishes to acknowledge the contributions of several indi- viduals whose individual and collaborative work, and words, are infused throughout this paper, Moshe Ben-Akiva, William Jessiman, Steven Lerman, Wayne Pecknold, and Earl Ruiter, who could almost be listed as co-authors. ** Appro F6? ea1J 01/11/19: CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 116 advantages and disadvantages of these proposals, it is essential to be able to predict how travel patterns will be affected. Among the issues facing urban transportation planners are these: 1. air quality 2. energy 3. land use policy 4. urban congestion 5. transportation impacts on special groups, such as: elderly, handicapped, low-income, etc. 6. public transportation financing and new technology develop- ment In response to these issues, a wide variety of transportation ,options are being considered. Some of these provide new auto or transit services, while others are disincentives as, for example, steps to reduce auto use: 1. new highway facilities 2. new transit service offerings such as rapid transit ex- tensions, feeder transit service coordination, express bus, subscription bus, jitney, dial-a-ride, taxi, dual-mode, light rail transit, etc. 3. taxes on gasoline 4. gasoline rationing 5. gasoline allocation schemes 6. parking restrictions, bans, or surcharges Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 7. vehicle exclusion policies--areas, days of the week, time of the day, registration sticker schemes 8. time bans on driving on particular days 9. car pooling programs and incentives 10. restrictions on auto ownership 11. taxes on vehicle ownership 12. congestion tolls 13. staggered work hours 14. parking changes 15. changes in transit fares and subsidies 16. ramp metering and other improvements to highway facilities 17. vehicle emission controls 18. land use controls In developing a regional or subregional transportation plan for a particular urban area, policy components such as these are combined into overall programs. The challenge of travel forecasting methods is to be able to predict the responses of potential travellers to such elements. For example, consider these questions on the impacts of various policies designed to reduce air pollution from transportation: How will trip-makers respond to a forced reduction in employee parking at factories and offices? How will they respond to an early morning on-street parking ban, such as the one scheduled for Boston in the spring of next year? Will the result be a decrease in Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 118 trip-making? A change of destination? A shift to public transpor- tation, to car pools, or to late arrival (i.e., staggered work hours for employees)? What would the imposition of selective parking surcharges on existing fees do to demand by the various modes? What is the impact of the imposition of tolls on certain. facilities? Would prohibitions on entry by private autos into certain areas have a similar effect? Do these policies have un- desirable differential impacts on different segments of society? What are the short-term and long-term shifts in residence, loca- tion, choice of work place, or household automobile ownership level that will occur as a result of various such air pollution control strategies? Questions such as these must be answered before a rational policy for reducing air pollution can be selected. Understanding travel demand behavior plays a critical role in arriving at these answers. 3. The Theoretical Basis of Travel Forecasting Modern travel forecasting methods are based on the theory of transportation systems analysis. This theory has emerged from several-sources. I In outline, the prdoblem of predicting the flows in a transportation system is a simple application of economic theory: the flows which will result from a particular transporta- tion system (T) and pattern of socioeconomic activities (A) can be determined by finding the resulting equilibrium in the transportation market. If: Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 119 V - volume of flow L - level of service experienced by that volume F - (V,L) - flow pattern Then, we find equilibrium by establishing a supply function (S) and demand function (D), and solving for the equilibrium flows (F ) consistent with both relations:2 (1.1) L - S(V,T) V - D(L,A) Fo - (V0,L0) (See figure 1, Basic Theory) While simple in outline, the application of the theory becomes complex in practice for several reasons: 1. The consumer considers many service attributes of the transport system when making a choice (e.g., line-haul travel time, transfer time, walk distance, out-of-pocket cost, privacy, etc.), and thus, L must be a vector with many components 2. Determining the demand functions (as well as other elements) to use is difficult 3. The equilibrium occurs in a network, where flows from many origins to many different destinations interact, com- peting for the capacity of the network; and the form of* these interactions is affected by the topology of the net- work Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A0002000f?005-9 VO FIGURE 1,. BASIC THEORY Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 VOLUNE V  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Thus, fairly elaborate computational schemes are required to ac- tually determine the equilibrium flows F 0 for a particular (T,A). In the case of a multimodal network, the symbol V represents an array of volumes: (1.2) V - {Vkdmr}, for every k,d,m and r, where Vkdmr is the volume flowing from origin zone k to destination zone d via mode m and path r of that mode, and the brackets { } indicate a set of elements Vkdmr' Ideally, once we have established our demand and supply functions, we would then like to be able to turn directly to an equilibrium-calculating procedure to "solve" the e two sets of relationships to find the equilibrium flow pattern. The result of this computation would-be the two arrays comprising that flow pattern: (1.3) Fo . (V0,Lp), where V0 {Vkdmr} for every k,d,m, and r; and Lo {Lkdmr} for every k,d,m, and r. In words: we should get out of our equilibrium procedure the volumes, and the levels of service experienced by those volumes, from k to d by mode m and path r. Unfortunately, at this state of the science of transportation modelling, while several systems of transportation models exist, there is not even one operational model which solves for these equilibrium flows exactly and directly.3 There are available a number of different systems of models, each of which represents a Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 different operational approach to. computing equilibrium in trans- port. networks. The differences in these approaches are reflected both in the computational algorithms and in the structure of the demand models which are used. One particular computational scheme is that which has been used historically in urban transportation planning studies. In this ap- proach the equilibrium flows are estimated in a sequence of steps, commonly called trip generation, modal split, and traffic assign- ment.4 Correspondingly, the demand function, D, is represented. as a sequence of functions: trip generation (and attraction) equa- tions, trip distribution procedures, modal split equations, and the minimum-path rules of the traffic assignment procedures. We will refer to this approach as the UTMS--the Urban Transportation Model System. More recently, other alternative approaches have been developed. In the following sections of this paper, we will summarize the major alternative approaches which now exist. 4. The Major Alternative Approaches In the preceding sections, the basic concept of a demand func- tion was introduced as a way of representing consumer behavior. A wide variety of different types of demand models can be developed. The objective of this section is to present some of the most impor- tant distinctions among the types of demand models used in travel forecasting in order to illustrate the variety of modelling choices available. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved* F,oi Release 2001/11 /t.9 CI'A-RDP79?-00798A000200020005-9* FIGURE The Demand Function VOLUME V LEVEL OF SERVICE TIME, t Approved For Release 2001111/19 CIA-RDP79-00798AO.00200020005'9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 In this discussion, we will tend to emphasize primarily "struc- tural" or "abstract" features of the-various choices. However, we must never forget that the basis of everything we do in demand modelling is based on trying to represent the behavior of the con- sumer. To emphasize this, we will relate the discussion of modelling choices to the way in which the choices open to the individual con- sumer are assumed to be perceived and operated upon. In general, in urban transportation, there is a wide range of choices open to a traveller. These choices are among combinations (f,d,m,r,h,ao, req, emp), where: f - frequency of trips d destination m - mode r - route h - time of trip so - number of autos owned res - residential location emp - employment location For most of urban travel forecasting to date, it has been assumed that (res) and (emp) are fixed for each traveller (or alter- natively, an urban growth and land use model is used to predict these long-run effects separately from the short-run travel decisions), and so travel forecasts deal primarily with choices of (f,d,m,r,h,ao). Further, in the past it has also been usual to separate choices of time of trip and of auto ownership from the other choices, re- ducing the primary focus of travel demand models to (f,d,m,r). Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Looking at the behavior of groups of consumers, we are thus concerned with predicting the aggregate total volume choosing a particular combination, in this form: Vkdmr - the volume of trips from origin zone k to destination d by mode m and path r Note that we have specified the origin of the trips (k), and that frequency has been replaced by the total number of trips made (i.e., frequencies of one, two, or more trips per individual per time period). There are a wide variety of different ways in which specific demand models might be constructed for use in transportation analyses. In this section, we will discuss some of the major differ- ences in types of demand models: variables included, functional forms, and three structural features which will be our primary concern: aggregate versus disaggregate, probabilistic versus deterministic, and simulteneous versus sequestial. 4.1 Variables Included Recall that there are two basic sets of variables, activity system variables (A) and level-of-service variables (L) in the demand function (1.1). One important set of choices concern what activity system and level-of-service variables to use. The activity system may be described in terms of such variables as population, employ- ment, income, household size, stage in family-life-cycle, etc. The level of service of the transportation system could be described in terms of travel time, separated into in vehicle and excess time, time reliability, service schedule, out-of-pocket cost, perceived security, tolls, etc. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 4.2 Functional Forms of the Models A wide variety of alternative functional forms are possible. The most common are the product, linear, exponential, and logistic or logit forms. 4.3 Aggregate and Disaggregate Recall that we are typically dealing with the consumer's choice of the set of travel options (f,d,m,r). If we consider an individual traveller (or household) i at location k, we can ask, which combina- tion (f,d,m,r) does this individual pick? In this case, our demand function is dlsag re ate; it predicts the choice of a single decision-making unit (either individual or household). We can write the demand function as Xfdalr - gi (A,L) (4.3-1) where: Sfdmr - 1 if I chooses (f,d,m,r); 0 if I chooses some other combination Let us now consider a group of individuals, e, which we will define as a "market segment." (Generally, we try to group indi- viduals or households into market segments such that the travel behaviors of all the individuals in a single market segment are relatively similar.) In this case, we write: (4.3-2) Vkdmr - f5 (A,L) This aggregate demand function gives the number of individuals in market segment e at location k who will choose (d,m,r). Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved'ror Release 2001/11/19: CIA-RDP79-00798AA00200020005-9 FIGURE 4.2-1 ALTERNATIVE FORMS OF DEMAND FUNCTIONS LEVEL OF.SERVICE (e.g..,cost, time) Approved For Release 2001/11/19: CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A00020002000-9 4.4 Probabilistic and Deterministic A probabilistic demand model gives an estimate of the relative likelihood of different choices being made. A deterministic demand model, on the other hand, predicts that one and only one specific choice will be made. Usually, disaggregate travel demand models are also formulated as probabilistic models. If we consider an individual traveller or household i, we can ask, what is the probability pi that this indi- vidual at location k will choose a particular combination of (f,d,m,r)? In general, we know this will be a function of some of the social, economic, and other characteristics of that indi- vidual (Ai), the characteristics of the activities which could be undertaken at various destinations d, (Ad), and the level-of- service characteristics Lkdmr for each path r in a mode m from location k to destination d: (4.4-1) Pi(f,d,m,r) - gi({Ai,Ad, Lkdmr} for all d,m,r] We write this as a probability in part because there will likely always be some inherent randomness in each individual's decision process. Usually, aggregate models have been assumed to be determinis- tic, although a probabilistic form would also be reasonable: (4.4-2) Pke(Vkdmr) - fe (A,L) 4.5 Simultaneous and Sequential In analyzing the travel behavior of any individual or group or individuals, a number of alternative assumptions about the Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 pattern of behavior can be made. One assumption of particular im- portance is whether individuals make simultaneous or sequential choices. At the disaggregate level, we can write the two cases as follows:5 (4.5-1) Sequential: Pi(f) ? pi(dif)?pi(mlf,d)?pi(rIf,d,m) (4.5-2) Simultaneous: Pi(f,d,m,r) These two equations are mathematically equivalent only if, in (4.5-1) pi(f), the probability of a given level of trip frequency (f) is indeed independent of destination (d), mode (m), and route W. Similar conditions must hold for pi(dif), etc. If these con- ditions are met, then the following behavioral interpretation can be given to (4.5-1): the potential traveller chooses first how many trips to make, then a destination, then (conditional on choice of destination and frequency) a mode, and then (conditional on having made all the other choices), a route. If these conditions (or an- alogous conditions for an alternative sequence of decisions), are not met, then (4.5.2) can be chosen. The corresponding behavioral interpretation is that the individual chooses his trip frequency, destination, mode, and route simultaneously. "Alternative estimation (model calibration) approaches are available for each case. Estimation of a simultaneous model, such as (4.5-2), is appropriate regardless of any behavioral choice se- quence which may exist. Once such a simultaneous model has been estimated, any desired marginal and conditional probability functions can be derived using the basic formulas of probability theory--for example, a .model split probability function, conditional on choice Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 of destination and trip frequency as in (4.5-1): p(mlf,d). How- ever, since simultaneous models are harder to estimate, information on the actual sequence of choices, if available either from prior empirical studies or from behavioral theories, can be used to sim- plify estimation by using sequential models. If the proper se- quence is assumed, the results should be identical, since the two cases are mathematically equivalent and, thus, either can be con- verted to the other, using the mathematics of probability theory. If the sequence assumed as a basis for estimation is not correct, this will become evident in one or both of the following ways: 1. If both types of models are estimated, they will not obey the relationships required by probability theory. Ben- Akiva (1973) has demonstrated this case. 2. If only a simultaneous model is estimated, it will not be possible to derive sequential submodels with the neces- sary independence properties. The most general assumption is that the decision process of the individual traveller is a simultaneous one and, therefore, we should estimate a simultaneous model. Then, any desired sequence of models can be derived. Although from a behavioral point of view it would seem best to begin with an assumption of a simultaneous choice model (where there are no behavioral arguments for any particular sequential model), there may be practical problems. Because of the larger number of possible combinations of choices, the number of explanatory variables and allowable interactions between variables may provide some difficulty, Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 and the model may become very complex. However, these problems could be resolved in any of several ways other than by assuming a sequential model, such as reducing the number of attributes a traveller is assumed to consider or the number of potential desti- nations. A similar distinction can be made at the aggregate level: (4.5-3) Sequential: Vk - f 1(Ak,Dd'`Lkdmr) Vkd f2(Ak,Dd'Lkdmr'Vk) Vkdm f3(Ak'DdLkdmr'Vkd) Vkdmr - f4(Ak,Dd'Lkdmr'Vkdm) (4.5-4) Simultaneous: Vkdmr - f(Ak,Dd'Lkdmr) Again, we note that the sequence in (4.5-3) is one of many possible sequences. It is important to note that the sequence in (4.5-3) is the same general form as in the traditional four-step demand models used in urban transportation and introduced in section 3--The Urban Transportation Model System (UTMS). Recent theoretical results, including the development of a "General Share Model" [12], show that any desired sequence, such as (4.5-3), can be derived from a given simultaneous form (4.5-4); and that, under certain conditions,6 an equivalent simultaneous form (4.5-5) can be derived from the sequential form (4.5-3). (The logic of these results is very similar to the basic mathematics of probability theory which apply at the disaggregate levels,) Again, however, in each case it is likely that equivalent forms (the two simultaneous forms or the Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 132 two sequential forms) obtained in the two different ways (direct estimation or mathematical derivation of one from the other) will. be different. Therefore, the most general approach at the aggregate level is also to assume a simultaneous choice form, estimate that form, and then derive analytically the corresponding desired sequential forms, just as was suggested for the disaggregate models above. In. this way, some of the objections to the conventional four- step models (cf. section 6.1.5 below) can be overcome; since level- of-service variables will appear in each step, there can be explicit behavioral structure, and valid estimation procedures can be used. 4.6 Other Modelling Choices In addition to those explicitly described in this section, other key modelling choices include: choice of market segments; commodity-dependent versus commodity-independent attributes (e.g., "abstract mode"); incorporation of activity variables explicitly or via stratification. These are, in general, choices which must be made by examination of the results of statistical testing of hypotheses reasoning. 5. Relationships of Major Model Development Alternatives The preceding discussion suggests a bewildering variety of com- binations of modelling choices. In this discussion, we will focus on the three sets of structural relationships: aggregate versus disaggregate; probabilistic versus deterministic; simultaneous ver- sus sequential. There are at present four basic alternatives for Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 1. Aggregate, deterministic, simultaneous models--Charles River Associates San Francisco direct demand model (CRA,1967), for example 2. Aggregate, deterministic, sequential models--the traditional UTMS models, introduced in section 3, for example 3. Disaggregate, probabilistic, simultaneous models--as esti- mated by Ben-Akiva (1973), for example 4. Disaggregate, probabilistic, sequential models--the bulk of the behavioral disaggregate modal split models [Stopher, 1969; Stopher and Lisco; Quarmby; Reichman and Stopher; Charles River Associates (1972); McFadden] In addition to these four alternative forms, there are also four basic ways to use these estimated models in forecasting. Because we must forecast total trips made (by various modes to various destina- tions, etc.) rather than probabilities of trips made, disaggregate models must be aggregated in the forecasting process. Prediction of equilibrium flows requires an equilibration method used with an aggregate demand model (either estimated in aggregate form or constructed from an estimated disaggregate model by aggre- gation). If the resulting aggregate model is simultaneous, then equilibrium can be computed in a single step with a "direct" approach. If the demand model is sequential, i.e., a sequence of equations, then equilibrium is usually computed in a sequence of steps, in an "indirect" approach. These two choices for forecasting are indi- cated as E and F in figure 6-1. The four basic alternative ways to estimate and use models for forecasting as shown in figure 6.1 are: Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 134 1. Estimation of an aggregate, deterministic, simultaneous model for all aspects of trip choice; and using that same, model for forecasting in a direct approach. (This is re- presented by line CE in the figure.) 2. Estimation of a disaggregate, probabilistic, simultaneous model of all aspects of trip choice, and then using an aggregation process to obtain an aggregate simulteneous model for forecasting in a direct approach. (This is represented by line AE in the figure). 3. Estimation of an aggregate, deterministic, sequential model of trip choice, by estimating each component in the sequence, and then using each of the aggregate model components separately for forecasting in an indirect ap- proach. (Represented by line DF in the figure.) 4. Estimation of a disaggregate, probabilistic, sequential model, also estimating each component separately, then using an aggregation process to separately aggregate each component up to a sequential aggregate model, and then using the aggregate model components for forecasting, in an indirect approach. (Represented by line BF in the figure.) In the past, these four approaches have seemed to be essen- tially different and competitive. However, recent research results- show that these approaches are all interrelated; they are different views of the same travel behavior. Once this is understood, rela- tions among the different views can be developed and, thus, addi- tional approaches become available. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19: CIA-RDP79-00798A000200020005-9. 135 m 0 IL Approved For Release 2001/11/19': CIA-RDP79-007984000200'020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The first step in laying out these interrelations is to note the connection between simultaneous and sequential forms at the disaggregate level, that of the individual consumer. (The basic theory was developed by Ben-Akiva (1973). It is possible to go from simultaneous disaggregate to sequential disaggregate models, using the basic mathematics of probability theory; and under specific conditions to go from sequential to simultaneous dis- aggregate models. The second step is to note the connection between simultaneous and sequential forms at the aggregate level, that of a "market seg- ment" composed of a group of individual consumers. The basic theory here was developed in the concept of the General Share Model (Manheim, 1973). This development shows how it is possible to go from simul- taneous aggregate ("explicit") to sequential aggregate models, using relations very analogous to those applying at the disaggregate level; and under special conditions to go from sequential aggregate to simultaneous aggregate models. The third step is to note the connection between aggregate and disaggregate forms. A general theory of aggregation is not yet available; however, assumptions can be made which: lead to directly useable practical procedures (Koppelman, 1975). Once these relationships are recognized, additional demand modelling approaches become available, as shown in figure 6-2. For example, an aggregate simultaneous model can be estimated directly or by aggregating a disaggregate simultaneous model. From this can be derived an aggregate sequential form of use in an indirect fore- casting approach, such as the four steps used in the traditional UTMS Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 and embodied in numerous software packages. This is represented by lines CF and GF respectively in Figure 6-2. Similarly, for the se- quential model, we can derive a simultaneous form of that model for forecasting in a direct approach. In Figure 6-2, this is repre- sented by lines BHE and DE respectively. So, for example, in recent work for CALTRANS (Nestle and Young) the present California genera- tion, distribution, and mode split relations were combined into a single simultaneous model. Thus, we now have a great number of ways to estimate and use demand models (eight ways, structurally, as shown in Figure 6-2). The benefit of this wide range of alternative combinations of estimation and forecasting techniques is that we can exploit the data efficiency of disaggregate models, and produce models similar to those conventionally used today, but which are behaviorally more valid for use in policy-oriented studies. Moreover, because of these relationships which exist between alternative estimation methods and alternative forecasting methods, we can base the choice of forecasting methods on grounds solely of computational efficiency. We are thus free-to chgose behavioral assumptions and estimation methods without concern for which form will be used for forecasting: 1. the "software" for forecasting can be designed to operate either with the conventional 4-step models or with simul- taneous models; 2. disaggregate methods can be used for efficiency in model development; 3. aggregation of disaggregate models can be done to produce both simultaneous and sequential forms, to allow the user Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19.:'CIA-RDP79-00798A00020002.0005-9 ? 138 Approved For Release 2001/11%19 .' CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 of the models to choose which ones are most useful in a specific forecasting task. 6. Examples of Major Demand Modelling Choices? In the preceding section, the set of combinations of major de- mand modelling choices which have been chosen so far for demand model development was identified below: Group I - aggregate, sequential, and deterministic Group II - aggregate, simultaneous, and deterministic Group III - disaggregate, sequential, and probabilistic Group IV - disaggregate, simultaneous, and probabilistic In the following sections, we will give examples of two of these groups: I and IV. 6.1 The Traditional Four-Step Approach: Aggregate Sequential Models To review: The basic choice open to prospective travellers is among combinations (f,d,m,r,h;ao,res,emp) where: f - frequency of trips8 d = destination m=mode r - route h - time of trip ao = number of autos owned res - residential location emp = employment location For most urban travel forecasting, it has been conventional to assume that residential location (res) and employment (emp) are fixed for each traveller (or alternatively, an urban growth and land use model Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 140 has been used to predict these "long-run". effects separately from the "short-run" travel decisions). Thus, models have dealt primarily with choices of (f,d,m,r,h;ao). Furthermore, typically the choices of time of travel and of automobile ownership are usually dealt with separately, leaving (f,d,m,r) as the primary concern of travel models. Usually, we are interested in the behavior of groups of indi- viduals. A market segment is defined as a group of individuals (or households) with similar travel behavior. Then, if we consider all of the individuals in market segment e who reside in zone k of an urbanized area, the demand function can be described as: (6.1-1) Ve - f(A,L) where A,L are a variety of relevant activity system and servica variables describing the choices available; and Vee dmrh;ao is the total number of trips made by members of market segment e in origin zone k owning "ao" automobiles, to destination d by mode m and route r at time h. In the typical approach, where it is assumed that choices of time of travel and of auto ownership are made separately from the others,-this becomes: (6.1-2) Vkd - f(A,L) Historically, this demand model has been broken into four com-. ponents: (6.1-3) Vkdmr - f 1(A,L) ? f2(A,L) . f3(A,L) ? f4(A,L) Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 where f 1 f2 - trip generation submodel - distribution submodel = modal split submodel - route choice ("network assignment") submodel By breaking the demand function into four submodels, it was possible to break the forecasting of future travel into a sequence of four steps: trip generation: Vk = total volume of trips generated by zone k in market segment e (6.1-4) Vk = f1(A,L) trip distribution: Vkd = total volume of trips originating in zone k and travelling to destination zone d, in market seg- ment e (6.1-5) Vkd - f2 (A,L) . model split: (6.1-6) (6.1-7) Vkdm = total volume of trips going by mode m from origin zone k to destination zone d in market segment e Vkdm - f 3 (A,L) Vkd network assignment: e Vkdmr Vkdmv total volume of trips going by route r of mode- m from origin zone k to destination zone d in mar- ket segment e f4 (A,L) ? Vkdm Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 In equations (6.1-5, 6.1-7), the functions f2, f3, and f4 re- present "share" functions--they serve to split a larger trip total into a number of components: In equation 6.1-6, for example, f3 is applied to the. total trips from k to d by segment e to obtain the share of these trips which will go by each of the available modes, m. It is instructive to examine each of these submodels in detail. 6.1.1 Trip Generation Trip generation is the first sequential step, involving the prediction of total trips from an origin or to a destination by trip purpose (7). The functional form is usually linear. Symbolic- ally, e e e Vk - a + ibiAki + iCifi(Lk.) where: Vk - trips of purpose e generated in origin k ae, bi,ci empirical parameters Aki - activity system variable i for origin ki fi(Lk.) - function of level of service variables from k to all destinations Typically, activity system variables used are average annual income, average number of autos owned, number of workers per house- hold, percentage of households having an income greater than a specified value; zonal population, acres of land in various land- use categories and zonal employment. A typical level-of-service function is accessibility, defined as a function of travel times or distance; but such functions are seldom used in trip generation. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Example The two trip-generation equations which follow are typical of equations used in the traditional four-step approach: Total Home- Based Trips - 0.69 + 1.94 (cars/D.U.) Dwelling Unit Home-Based +'1.39 (residents > 5 yrs./D.U.) - 1.148 (workers) Work Trips + 0.569 (households) + 0.019 (residents > 5 years) - 0.144 (residents x distance from CBD) + 0.488 (residents) Note that neither equation includes any level-of-service variables: zonal trips will therefore be predicted to remain constant, no matter what level of transportation service is provided. 6.1.2 Trip Distribution The second sequential step in the conventional four-step ap- proach is trip distribution, the prediction of trips from origin to destination. The independent variables are the "trip ends" re- sulting from the previous step, plus level-of-service variables. Symbolically, (6.1-8) Ykd - fn(VkVd' Lkd) where Vkd . trips of purpose e from origin k to destination d - results of the trip-generation step Vk, Vd e Lkd level-of-service variables between k and d Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The two most common functional forms are the gravity model and the opportunity model. Typical versions of each of these follows: 1. Gravity Model (6.1-9) Vkd efe Vd kd e e dVdfkd where fkde is an arbitrary function of travel time. Example The following table shows typical values of fed for a range of travel time, and for three trip purposes: home-based work, home- based nonwork and nonhome-based. Note that the units of fed need not be defined, since the quantities appear in both the numerator and denominator of the gravity model equation. For the same reason, the values can all be scaled up or down by the same constant without affecting the model's results. 2. Opportunity Model (6.1-10.) V e - V exp(-LeSd) I1-exp -LeVd] where: Sd - E Vi - "subtended volume" j - all destinations for which tkj < tkd Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For'Reiedse 2001/11/19: CIA-RDP79 00798A000200020005-9 Typical Gravity Model .5. (Source: Federal Highway Administration) Table 5.1.1 Travel'Time Factors e.. fkd :..Work Non-Work ..Non-Nome-Based .79 67 . 61 57 50 14 .48. 15 45. 16 10, 17 18 220 210 160 120 130 100 90 80 ' 85 70 70. 60 60 55 50 44 39' , ? 38 35 32 27 30 25 ?. 26 21 23 ?16 14 Approved For Release; 2001/1.1/19 : CIA-RDP79.p 007.98AO00200020005-9 5  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Example: In the Chicago Area Transportation Study, three market seg- ments were used: e - 1: trips from home to work and all trips to the central business district (long residential) e - 2: trips from work to home and all trips from the central business district (long residential) e - 3: all other trips (short) Long residential trips have only nonresidential trip ends as their subtended volumes, and vice versa. Short trips have only short trip ends as their subtended volumes. The model parameter for all trips (e - 1 and 2) is 2.5 X 10-6, that for short trips (e - 3) is 20 X 10-6. The model can therefore be stated mathematically as follows: Vkd - Vk exp [-2.5 X 10-6Sa] {1 - exp [-2.5 X 10-6Va]} Vkd - Vk exp [-2.5 X?10-6Sa] {1 - exp [-2.5 X 10-6Va]} Vkd Vk exp [-20 X 10-6 Sa] {1 - exp [-20 X 10-6Vd3]} Each of these distribution models are "share" models; they divide the total trips from k,Ve, among all distributions using a fraction which, when summed over all destinations, equals one. Travel time by a single mode, usually highway, is typically the only level-of-service variable used, although in some applications, a "generalized cost" has been used which is a linear combination of travel time, distance, and out-of-pocket costs. The level-of- service variable enters the Opportunity Model in an indirect way Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 only. It affects the ranking.of destinations from each origin, which in turn affects the subtended volumes which enter the model directly. In some applications of both the gravity and opportunity models, adjustments of the Va's are made after initial application of Equation 6.1-9 or 6.1-10 in an attempt to force the total trips to each destination (Ve - E Ve ) to equal the original V a's. This i id constraint is not guaranteed by the functional form of either dis- tribution model. Following adjustments of the original VV' s., the equations are applied again. Iteration through application of the equations and adjustment of the original values continues until a desired level of correspondence between each Ve and Va is reached. 6.1.3 Modal Split The third sequential step in the conventional approach is modal split, the prediction of trips by mode from origin to desti- nation. The independent variables are the trip interchanges re- sulting from the previous step, plus modal level-of-service variables. Symbolically, (6.1-11) e f e Vkdm em(Vkd'Lkdq'SkAd) where Vkdm - trips of purpose e from origin k to desti- nation d by mode m Ved - results of the trip distribution step Lkdq - level-of-service variables for all modes q between k and d Sk - socialeconomic variables of travellers in k Ad - activity system variables in d Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Many approaches have been used to develop functional forms, fam, for modal split models. The most commonly used prior to the, last three or four years were regression or table look-up models based on the relative levels of service offered by each mode (e.g., reference [4]). Typically, origin zones have been classified by income level and auto ownership, and for each subgroup linear equa- tions or tables are developed which relate fraction of trips by auto and transit to time and cost ratios or differences. Example Figure 6.1-2 shows a set of graphs of modal split relationships for work trips based on relative levels of service and on cross-classifications based on the economic status of the traveller and the relative levels of excess travel time. The specific variables used in the figure are: Vertical axis - trips by transit trips by all modes TTR - total travel time by transit total travel time by auto L - excess travel time bytransit excess travel time by auto Ll - 0 to 1.5 L2 1.5 to 3.5 L3 3.5 to 5.5 L4 - 5.5 and over CR - out-of-pocket cost by transit out-of-pocket cost by auto CR1 0.0 to 0.5 CR2 - 0.5 to 1.0 CR3 - 1.0 to 1.5 CR4 - 1.5 and over Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 EC - economic status (median worker income, 1963 dollars) EC1 . $0 to $3,100 per-year EC2 - $3,100 to $4,700 per year EC3 - $4,700 to $6,200 per year EC4 - $6,200 to $7,500 per year EC5 - $7,500 per year and over More recently, the following functional form (termed the binary choice logit form) has been used for fem, applied to modal split between auto (a) and transit (t). e e 1 (6.1-12) P kdm 1 + exp [hm(Lkdg)] and hm C - Cm + Eat" (tz - ti ) + Eb-' (cz - ci ) I m kdt kda i m kdt kda Again, times and costs have been divided into various variables. The constant, Cm, as well as parameters aM and bm, allow the relative characteristics of modes not measured by times and costs (such as comfort and convenience and modal "image") to be represented in the model. The function hm can be interpreted as a difference in consumer utility between travel by transit and travel by auto. 6.1,4 Route Choice The final step in the conventional approach is traffic assign- ment, the prediction of trips by route and thus by link. Symbolically, (6.5-13) Vma m f(Ve kdm , ma) where V - volume of traffic of mode m on link a ma L - level of service on link a for-.mode in ma Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 This equation is deceptively simple; actually, bridging the gap between predictions of 0-D volumes.(Vkdm) to link volumes (Vms) represents a significant problem. This is especially true if an attempt is made to take into account the variation of link levels of service (usually simply travel time) with link volumes. When this is not done, the assignment is termed an all-or-nothing assignment without capacity restraint. Various methods of adjusting travel times (alternatively, applying capacity restraint) have been developed. Each one involves either adjusting travel times after a portion of trips are assigned, and then continuing assignment; or averaging a number of complete assignments, each one based on the travel times corresponding to the previous assignment. In present assignment methods, one of the following assumptions is made about how travellers chose a path from origin to destination: 1. Each traveller chooses the minimum path. This assumption leads to a situation where each path used between an 0-D pair has equal travel time and all paths not used have a higher travel time. 2. Travellers distribute themselves in such a way that the time and volume on each path between an 0-D pair are re- lated as follows: 1 (6.1-14) Vkdr - !kdr ? Vkd Ef kdr) r Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Vkdr - volume of flow for 0-D pair k-d on route r tkdr " travel time on route r f(tkdr) a decreasing function of route travel time. 6.1.5 Critical Appraisal of the Traditional Four-Step Models The approach described above is the most widely used transpor- tation systems analysis approach--the Urban Transportation Model System (UTMS). It has been applied in over 200 cities in the United States and in many other cities around the world. The de- velopment and institutionalization of this approach over the last fifteen years is a major accomplishment; it is the first large-scale application of modern systems analysis techniques to problems of the civil sector. It is useful to examine this approach critically, from the per- spective of the equilibrium theory presented in section 3 and the challenge of today's urban transportation problems. As we have seen in this traditional approach, the travel demand models are structured into a sequence of four submodels called: trip generation, distribution, modal. split, and assignment. Essen- tially, this amounts to estimating Vkdmr in a series of "successive approximations": first, Vk, then Vkd, then Vkdm, and finally Vkdmr' It seems obvious that the following conditions should be met by any such set of demand models and submodels and the corresponding equilibrium calculating procedure: Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 1. Level of service, L, should enter into every step, in- cluding trip generation (unless an analysis of the data indicates in a specific situation that trip generation is, in fact, independent of level of service for all market segments over the full range of levels of service to be studied). 2. The level-of-service attributes used should be as complete as necessary to predict adequately traveller behavior. For example, time reliability, number of transfers, privacy, etc., should be included if empirical evidence indicates these are important. 3. The same attributes of service level should influence each step (unless the data indicates otherwise). For example, transit fares, auto parking charges, walking distances, and service frequencies should influence not only modal split but also assignment, generation, and distribution. 4. The process should calculate a valid "equilibrium" of supply and demand; the same values of each of the level- of-service variables should influence each step. For ex- ample, the travel times that are used as inputs for modal split, distribution, and even generation, should be the same as those which are output as results from assignment. If necessary, iteration from assignment back to generation, distribution, etc., should be done to get this equilibrium. 5. The levels of service of every mode should influence demand. Congestion on highway or transit networks, limited capacity (e.g., parking lots), fares, etc., of each mode should (in Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 general) affect not only its own demand but also the demand for other modes, at all steps (generation, distribution, modal split, and assignment). That is, there should be provision for explicit cross-elasticities. 6. The estimation procedures should be statistically valid and reproducible. Careful examination of the traditional approach indicates it violates each of these conditions. As a consequence, serious ques- tions can be raised about the biases and limitations of the flow pre- dictions resulting from use of the models in their traditional forms. Nevertheless, this set of models--the UTMS--is still in widespread "production" use in almost all urban transportation planning activi- ties in the United States. 6.2 Group IV: Disaggregate Simultaneous Models Modelling at the aggregate level uses data for entire zones whose sizes range from fractions of square miles for urban applica- tions to entire metropolitan areas for intercity applications. Modelling at either of these levels of aggregation smoothes out most of the variations of the behavior of the individuals who actually make'the travel decisions being modelled. For this reason, much recent demand modelling effort has devloped disaggregate models for predict- ing travel decisions of individual travellers. Initially, these studies were concerned only with the mode choice decision. The models developed were individual traveller applications of the form shown in section 4.3. When applied to individuals, the dependent variable can only take on the values 0 or 1, requiring a different set of estimation Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 procedures to be used than with aggregate models. In the initial models of this type, only two modes were included, leading to a binary choice situation. The binary choice logit functional form has been used for these models. More recently, multiple choice models have been developed, using the multiple-choice logit func- tional form (Ben-Akiva, 1973; McFadden), or multinomial logit, as it is sometimes called. One feature of these models which is much discussed in the literature is their "independence of irrelevant alternatives" pro- perty. This property has two consequences of concern to transpor- tation analysts: 1. If a new alternative (mode, destination, etc.) is added, the percentage decreases in the usage of all existing al- ternatives will be constant. 2. If one existing alternative is improved, the percentage de- crease in the usage of the remaining alternatives will be constant. The multinomial logit model (MNL) is of this form: p(i:S) - Ui e E e U j :ES where: x - level of service attributes 0 - Parameters Ui - EOkXik k Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 In the case of travel choices: i - (f,d,m,r) and S - FDMR, the full set of all possible travel choices. Thus, the simultaneous choice MNL becomes: Uf dmr p(f,d,m,r: FDMR) - e to Ufdmr F,D,M,R We can relate this to the sequential disaggregate form by basic probability theory: p(f,d,m,r) - p(f) p(djf) p(mld,f) p(rlm,d,f) - pf(X,O) ? pd(X'p) . pm(X'O) . pr(X,g) the specific choice functions (pf' Pd' Pm' Pr) can be shown to be also multinomial logic in form [Ben-Akiva, 1973] p(f:F) - p(d:D) - p (m: M) ~ - p(r:R) - Uf e Ee Uf feF Udf e E deb Udf mdf e U mdf meM U rmdf e rle U rmdf Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The first estimation of a simultaneous disaggregate model was by Ben-Akiva (1973). The functional form of this multiple-choice logit model is as follows: (6.8-1) Pkdm - exp[Ea (A - A , ) + Eb (M1 - M1, ) Pkd'm' q . dq d q q q mq m q + EcYk(M2 - M2,q) + Ehq(L 11 dmqL1 ' ) + E 2 2 q g q Lid m q q Y k (L kdmq - L kd'm,q)) P , P , ' - fraction of total trips from household k going to kdm kd m destinations d and d' by modes m and m'. (Either d abd d' or m and m' may be the same, but not both.) Adq, Ad,q Mmq, m q i . i Lkdmq' Lkd' m' q Yk - activity system variables - modal variables - level of service variables - household income code 9 As estimated by Ben Akiva, the following variables were used: 1. Activity system variables (Adq): Adl - number of jobs in wholesale and retail establishments in the zone of destination d Ad2 indicator for DBD destinations. (1 if d - CBD, 0 otherwise) 2. Modal variable in separate term (M1 ): Mm1 1 - indicator for auto usage. (1 if in - auto, 0 otherwise) 3. Modal variable in interaction term with income (Mmq): M221 - indicator for auto usage. (same as M' ) M ml Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 4. Level of service variables. in separate terms (Lk1 dmq Lkdml = out-of-vehicle travel time Lkdm2 ? in-vehicle travel time. 5. Level of service variable in interaction term (Lkdmq 2 Lkdml - out-of-pocket cost. This model was estimated for auto and transit trips for the shopping purpose only, and does not deal with trip-making frequen- cies or time of day choices. It therefore represents a model which can be used to divide total shopping trips from a household among the variable modes and destinations. The parameters obtained are the following: Associated Variable Parameter Lavel Parameter Value (Adl - Ad,l) a1 .000171 (Ad2 - Ad,2) a2 .316 1 1 - ml Mm'l bl -1.36 2 - Yk(Mml M 2 21) Cl .114 1 1 ~Lkdml - Lkd'm'1) h1 -.0633 2 2 Lkdm2 - Lkd'm'2) h2 -.0164 2 2 Lkdml - Lkd'm'1)/Y fl -.0757 In additional work since that time, Ben-Akiva and his associates have developed additional simultaneous choice disaggregate models. Some of these models will be summarized briefly here and are described in detail in the appendix. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 158 The three models described below are: 1. A work mode choice model with an explicit carpool mode 2. A simultaneous choice model for shopping trips including the choices of travel frequency, trip destination,'and mode of travel 3. A household auto ownership model All these models were estimated using the multinomial logit model with data sets derived from the 1968 Washington, D.C. Home Interview Travel Survey, conducted by the Metropolitan Washington Council of Governments. In addition, in recent work, a model of simultaneous choice of residential location, auto ownership, and mode to work has been developed (Lerman). 1. Work Choice Model 10 A work mode choice model has been produced as a multinomial- logit three-mode (auto driver alone, carpool, transit) model, esti- mated using the Washington, D.C. data base. The model specification recommended is shown in Appendix A. This model contains all the normally expected variables--in-vehicle travel time, out-of-vehicle travel time, out-of-pocket costs, income, and auto availability--plus some special variables to pick up some of the factors influencing carpooling. Further description of this model and a discussion of the variables can be found in Appendix A. It should be noted that, since the models produce choice prob- abilities; they do not assume that a traveller will use the same mode every day. This is particularly important for carpool users in view of the fact that many existing carpools have been observed Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 not to be an everyday arrangement and carpools are frequently organized for less than five trips per week. Thus, if a traveller carpools twice a week, for example, his carpool choice probability on any given day is 0.4. 2. Non-Work Trip Frequency, Destination, and Mode Choice Models Two nonwork (shopping) simultaneous disaggregate travel demand models have been developed on the 1968 Washington, D.C. data base. The first was the estimation of a joint destination and mode choice shopping model by Ben-Akiva (1973), described above. The second was the subsequent estimation of a joint frequency, destination, and mode choice nonwork model by Adler and Ben-Akiva (1974). Both are logit models calibrated by maximum likelihood estimation and both forecast the frequency, destination, and mode choice of a household's shopping trip as a function of automobiles available, among other factors. The second model was estimated on a larger number of observations than the first, has reasonable coefficients in terms of both sign and relative magnitude, and all the important coefficients are statistically significant. The variables used in this second model and the estimation re- sults are shown in tables B.l.and'?B.2 in Appendix B. The model con- tains transportation level-of-service variables, socioeconomic char- acteristics and shopping attraction variables. Particularly noteworthy in the specification of this model are its relationships with work trips. The auto availability variable is formulated as the auto available to the household minus those used for work trips by household member. This specification assumes Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 that the choice of mode with respect to work trips is of higher im- portance to the household than the shopping travel choices. This specification allows for an explicit evaluation of a policy that the availability of auto for off-peak nonwork trips. This model would be used after the work mode split model when auto availability was determined so that it could be input to this shopping model. Further description of this model and a discussion of the variables can be found in Appendix B. 3. Auto Ownership Model Recently, a simultaneous disaggregate auto ownership and work mode choice model has been developed. This model addresses the classic "chicken and egg" dilemma of the close interdependency between auto ownership and mode-to-work choice by developing and estimating a disaggregate choice. model which assumes these two de- cisions are made simultaneously. Each combination of auto ownership level and usual mode to work is a distinct "bundle" or alternative, one and only one of which is assumed to be selected by each house- hold. The model describes the joint probability of a household se- lecting a given auto ownership level and a given mode to work for the breadwinner. (The worker with the highest occupation status code has termed the "breadwinner"; it was felt that his transpor- tation to work would dominate in terms of demand for the family auto.) Hence, the choice set for a household consists of the cross- product of the entire set of modes and the entire set of possible Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 auto ownership levels. However, this can be reasonably simplified without any major loss in the model's usefulness by assuming that a maximum of eight choices forms the set of alternatives which is assumed to be available to any household. These are as follows: 1. Own zero autos and carpool to work 2. Own zero autos and use transit to work 3. Own one auto and drive alone to work 4. Own one auto and carpool to work S. Own one auto and use transit to work 6. Own two or more autos and drive alone to work 7. Own two or more autos and use transit to work Note, however, that there is no requirement in the logit model that every household have all eight alternatives. For some work trips, transit service is simply not likely to be perceived as available; these households choose among only five alternatives. Other households have an income which is simply too low for them to consider realistically multiple car ownership as an alternative; these households have only the first five alternatives. A variety of other combinations is also feasible. For example, in the model calibration it was assumed that a household will not own more cars than the number of licensed drivers who might use those cars. These rules for determining which alternatives pertain to each household were verified by performing extensive cross-tabulations on the data set and examining whether any substantial portion of the sample made a choice assumed to be unavailable. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 162 A broad range of variables was considered for providing possible candidates in the model specification. An attempt was made to re- strict the model to variables which are behaviorally related to the household decision process rather than simply correlated with actual causal variables. The model specification recommended is discussed in Appendix C. The important variables contained in the model include the transport level-of-service characteristics (in-vehicle travel time, out-of- vehicle travel time, and travel cost) for both peak and off-peak travel. In addition, the model includes other factors that in- fluence carpooling, and variables that determine auto ownership and mode choice such as housing and socioeconomic characteristics of the household. One of the most important aspects of the auto ownership model development was the determination of significantly, yet logically different, behavioral responses from different market segments (groups with homogeneous socioeconomic characteristics). The above model was estimated for a pooled sample of households but, in addi- tion, separate models were estimated for each of several different market segments. This same stratification by market segment could be applied to all three models (work mode split, shopping direct demand, and auto ownership) to yield more specific information on response to the various policies. Further description of the joint auto ownership/work mode choice models and a discussion of the variables can be found in Appendix C. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Note that, while the model is formulated here as a joint (auto ownership and work mode choice simultaneously) model, separate marginal (auto ownership alone or work model choice alone) or condi- tional (auto ownership, given work mode choice; or work mode choice, given auto ownership) models are directly and easily derivable. Moreover, the work mode choice portion of this joint model refers only to the mode choice decision of the breadwinner, not of all household workers. This is in contrast to the work mode choice model for all household workers. This gives rise to two alternative ways of utilizing these three available models for immediate planning analyses: 1. Use the marginal auto ownership form of the joint model to yield auto ownership; then use the section l.?.wojrk mode split model for all workers, yielding complete information on work trip mode splits and auto availability for other trips; then run the nonwork demand model to capture changes in nonwork travel due to increased auto availability. 2. Use the joint auto ownership/breadwinner work mode choice model for breadwinner work mode split; use the section 1. work mode split model for all other workers (since there is a breadwinner variable in that model, there is no bias in using it for nonbreadwinners only): then, taking the composite results of those models in terms of remaining auto availability, run the nonwork demand model. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 4. Features of These Models It is useful to summarize the major advantages of these models over other travel demand models that have been developed: 1. Car Pooling The work mode choice model includes a car pool mode in addition to drivers driving alone and transit. Other existing work mode choice models consider auto drivers and auto passengers as two separate modes. Therefore, one cannot isolate persons in multiple occupancy vehicles from those with a driver only. Analysis of special in- centives to multiple occupancy vehicles can only be per- formed using a model with an explicit "car pool" mode. 2. Auto Ownership These models include an auto ownership model sensi- tive to the important transportation policy variables, while auto ownership is assumed as an exogenous (independent) variable in other travel demand models. The importance of this model for the analysis of today's policy thrusts is obvious: auto ownership can be influenced by transportation policies, and these models include this effect. 3. Sample Size In a recent project to estimate disaggregate travel de- mand models in the Netherlands, an analysis of the effect of sample size on the reliability of the estimated coeffi- cients was performed (Ben-Akiva and Richards, 1975). It was found that, for a multiple logit mode choice model with ten Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 coefficients, samples of less than 250 observations result in very unstable coefficients. The standard errors of the estimated coefficients decreased sharply by increasing the sample size gradually from 100-150 to 250-300 observa- tions. Beyond 300, the incremental reductions in the standard errors with increasing sample size were much smaller and gradually diminishing. Disaggregate models are clearly very attractive from the perspective of data collec- tion economics. 4. Explanatory Power These models are specified using a greater variety of explanatory behavioral variables than other available models. The improved specifications result in increased explanatory power and reduced uncertainty for forecasting. 5. Theoretical Validity The assumption of a joint (or simultaneous) decision process, made in the shopping and auto ownership models, is more realistic than the sequential decision process implied by the structure of other available models, both aggregate and disaggregate. 6. Market Segments The auto ownership model was estimated using nine mar- ket segments. The other models also use a richer set of socioeconomic variables than other existing models in the field. This allows for a better understanding of how Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 various population groups will respond differently to a given policy option. 7. Transferability Because the coefficients of a disaggregate model are free from aggregation bias, a disaggregate model can po- tentially be applied to situations (i.e., geographical areas) which are different from those on which it was calibrated. However, even a disaggregate model can be transferred only if it is not seriously misspecified. These disaggregate travel demand models are based on the most complete specifications among all similar models that are known at this time. Therefore, we would expect these models to produce reliable forecasts for other urban areas in addition to Washington, D.C. for which the models were estimated. Some tests that were carried out with these models on data from New Bedford, Mass., Milwaukee, Portland, and Los Angeles show that these models can be used satisfactorily as estimated, or with minor adjustments. 11 8. Trip Frequency For the shopping trips, the frequency of travel is not assumed constant as in the UTMS trip generation models. 7. Conclusions This paper has presented an overview of the major choices for development of travel forecasting methods: Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 1. In the past, the basic approach used for urban travel fore- casting has been that of sequential, aggregate, determinis- tic demand models with an indirect approach to calculating equilibrium flows. This approach now is seen to have serious deficiencies, especially when confronted with today's emphasis on a broad range of transportation options. 2. Recent research indicates that there are at least eight alternative ways to develop demand models and use them for equilibrium prediction. 3. From the point of view of equilibration, a simple-step direct approach is likely to be most valid and most effi- cient in all except special situations. 4. From the point of view of demand model development, estima- tion of models using disaggregate methods is much more economical in terms of data requirements than aggregate methods, and provides the opportunity for formulation models soundly based on behavioral theory and estimated using valid statistical approaches. 5. Numerous practical approaches to aggregation of disaggre- gate models to produce an aggregated model for forecasting are available. 6. It is feasible to estimate simultaneous choice disaggre- gate models, and the results are different from the re- sults of separately estimated sequential models. The assump- tion of simultaneous choice is the soundest behavioral assump- tion except when there are specific behavioral reasons for Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 hypothesizing a particular sequence of choices. For ex- ample, in current work, one hypothesis being used is of a simultaneous-block-sequential form: A. simultaneous choice of residential location, em- ployment location, and housing type B. simultaneous choice of automobile ownership level and mode to work, sequential to (conditional on) the choices in (A) C. simultaneous choice of non-work travel, including frequency, destination, mode, time of day, and route of nonwork trips, sequential to (conditional on) the prior choices in (A) and (B). Alternative behavioral hypotheses might be appropriate in dif- ferent contexts. As a consequence of the above, the author's conclusion is: The preferred approach, in general is to: 1. Formulate a simultaneous or simultaneous-block-sequen- tial form based upon behavioral reasoning in a parti- cular context 2. Estimate the corresponding models in disaggregate si- multaneous (and sequential, where appropriate) forms 3. Construct models for prediction by aggregating ex- plicitly the estimated disaggregated models 4. Predict flow impacts of alternative transportation options by equilibrating the resulting aggregate si- multaneous models in a single-step direct approach. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Where specific situations suggest that short cuts may be accept- able, use appropriate approximation methods. For example, proposed changes in transit service frequency in a particular corridor may be hypothesized as unlikely to affect choices of destination or auto ownership level; therefore, a conditional mode choice model could be derived from the simultaneous models and used in a sequen- tial approach to equilibrium with trip generation and distribution held fixed. However, for other changes, this hypothesis might be considered unacceptable, and so the more general approach should be followed. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Work Mode Split Model Tables A.1 and A.2 contain the model specification (variables in- cluded) and estimation results. Interesting results were obtained for the implied impact of changing auto availability and also for the importance of the "govern- ment employee" variable. Both show considerable influence on the modal split forecast by the model, and both have strong (significant) coefficients. GW is a dummy variable in the car pool utility function which is unity if the traveller is a civilian employee of the federal government. Its positive sign indicates that, all else constant, federal employees are more likely to choose carpooling than nonfederal employees, which may be due to more potential for matching (i.e., more opportunities to choose from and less search time), more active en- couragement of carpooling by the employer, or more consistent start- work and end-work times. An important implication of the strength of this variable is that concerted efforts by large employers to en- courage and facilitate carpooling can have a significant impact on the proportion of work trips made by that mode. This variable, in effect,'is a proxy reflecting the existence of some employer-based carpool incentive programs. Therefore, in forecasting, this variable can be used as a policy variable to indicate those employers who in- stituted such programs by setting its value equal to one (or, if sufficient empirical data exists, to some other value reflecting the level of the employer's incentive program relative to the federal government's). Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Variable Code 3.. OPTC/INC 6. ` AALD Approved For Rel 2S0AP1'KM9 IA 9-00798A000200020005-9 DEFINITION OF VARIABLES Definition time (in minutes)/one way'distance ?or shared rids.. 1, if -worker is the breadwinner, for. drive 'alone 0, otherwise 1,'if work place is in the CAD, for drive alone Al.. DCITYa !2. DINCc o 13 a INOM8 E4. )TECA8 Alternative: 1 1, for shared ride 0,. -otherwise. cost (in cents)/household annual round trip out-of-pocket travel . income (in dollars) round trip in-vehicle travel time (in minutes) round trip out-of-vehicle travel (in miles) Q of autos/licensed drivers,` 0, otherwise u of autos/ licennaed drivers, 0,Xtherwise 0, otherwise 1,' if work place 0, otherwise: is in' the CBD, for shared ride household annual income - 800 A 0 of pcrsona in (in $), for drive alone and nhared ride 00 .otherwise 0 of 'workers 0, otherwise in the household, for shared rido the household employment density'at the work. zone'(cmployeca per commercial acre) * one way distance (in miles), for shared ride 0, otherwise . . . drive alone shared ride (car pool) transit Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2bd14/1JQ 2 CIA-RDP79-00798A000200020005-9 WORK MODE CHOICE MODEL THE MODEL COEFFICIENTS Drive alone constant Shared ride constant ?.3. Out-of--pocket travel cost divided by income 4. In-vehicle travel time Out-of-vehicle travel time .divided by distance. '.Auto.availability (drive alone only) Auto availability (shared r.id1n only) OPTC/INC 1VTT AALDa 17Z Coefficient t-statistic ..3.24 Breadwinner (drive alone only) B '.890 11. CBD work place (shared ride only) ? 12. Disposable income (drive alone. and shared ride only) 13. Number of Workera (shared ride only) 14. lniployment density (shared ride only) of observations a 1114 0 of alternatives w 2924 GWa'.? DCITYC DCITY s DINC cos NWORY.B DTECAo -6.86 -5.60 10.08 -.404 -1.36 .0000706 3.46 .0983 1.03' .000653 1.34. Approved For Release, 2001/11/19 : CIA-RDP79-00798A000200020005=9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The auto availability variable occurs twice (with different co- efficients) because of its mode specific character, once in the drive- alone utility function, and once in the carpool utility function. Both coefficients have positive signs and, therefore, indicate that an increase in the ratio of autos to drivers in a household will in- crease the likelihood of both driving alone and in a carpool, rela- tive to using public transit. However, because the difference between the coefficients for driving alone and for carpooling is also positive, an increase in auto availability (all else equal) will raise the probability of driving alone relative to that of participating in a carpool. The level of service variables: out-of-pocket travel cost (OPTC), in-vehicle travel time (IVTT), and out-of-vehicle travel time (OVTT) have significant coefficients with the expected negative signs and relative magnitudes. For a typical five-mile commuting trip, the ratio of the out-of-vehicle travel time coefficient to that of in- vehicle time is approximately 2. This implies that a minute of out- of-vehicle travel time is twice as onerous as a minute of in-vehicle time. This result is similar to results obtained in previous studies. The implied value of time for a five-mile commuting trip by an indi- vidual whose annual household income is $8000 (in 1968 dollars) is approximately $2.50/hr. for in vehicle time (and, of course, twice that for out-of-vehicle time). Again, these figures correspond to logic and the results of previous mode choice models. The breadwinning variable is included for drive alone with a positive coefficient, which represents the higher priority of the primary worker for the use of any car that is available. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The CBD variable captures the added disutility of driving to the CAD which is quite likely to differ between the two auto modes, but nevertheless captures the disutility of driving in the CBD. As expected, the coefficient of the variable for drive alone is more negative than that for carpool. Disposable income is included with one coefficient because when separate coefficients were tried they were very similar. The number of workers has been included to capture the effects of intrafamily carpools. The final variable is an interaction variable that combines the added convenience of finding a carpool partner if one works in dense employment areas with the added incentive to carpool over longer distances. This variable could be improved by collecting more data on employer characteristics which were not available in the existing data set. The two modal constants, for drive alone (Dc) and for shared ride (Ds) are negative. The larger absolute value of the drive alone pure (dis)preference indicates it is relatively less desirable than car- pooling, given that all other variables are constant across all modes. Both drive alone and carpool are less desirable than transit (implied zero constant) as far as the constant term alone goes, but the auto availability variables pick up enough positive value when an auto is available to reverse this relative effect for drive alone and render carpool only slightly less desirable than transit. 174 Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 APPENDIX B Shopping Trip Frequency, Destination, and Mode Choice Model The model specification and the estimation results are shown in Tables B.1 and B.2. As can be seen, all the important variables are significant at the 99% confidence interval (t-statistic greater than 2.3). The co- efficients of the level-of-service variables (time, cost) have the expected negative signs and result in reasonable values of time. For a shopping trip of 2.5 miles and a total round trip travel time of 40 minutes, a minute of out-of-vehicle time is somewhat less than twice as onerous as a minute of in-vehicle time. The attraction variable, In (REMP), has the correct sign (the higher the retail employment at a given shopping center, the more attractive it is). The car constant, DC, has a negative coefficient, reflecting that when the auto is used for a shopping trip it is not available for other purposes. The CBD constant is positive, indi- cating that the CBD is a more attractive shopping area generally. The AAC variable coefficient is positive, meaning that the greater the number of autos available, the more likely the traveller is to make?a shopping trip and make it by auto. The positive sign on the zero-frequency income variable INCF, is consistent with other results and states that higher income households make fewer shopping trips (i.e., they are able to maintain larger stocks of goods). Of the other frequency variables, household size (HHSF) enters with a negative sign indicating (as expected) that, for a larger household, the probability of not making a shopping trip on a given day is less. The density variable DENF is an attempt to account for Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001ABh19 :P3i -RDP79-00798A000200020005-9 SHOPPING JOINT TRAVEL DEMAND MODEL DEFINITION OF VARIABLES Variable Code Definition 1. DC 176 2. OVTT/DIST round trip out-?of.Vehicle travel time (in minutes)/one way distance (in wile-.) 3. 1VTT+OVTT round trip. ia-vehicle travel time -h round trip out-of-vehicle travel time (in minutes) ?? - 4. OPTC/INC round trip out--of-pocket travel cost (in cents)/household annual income kin code*) 0 of autos available to household - 0 of autos used for work 1, for car 0, otherwise trips by workers in the household, for car 0, otherwise ? . 1/one way distance (in miles). 7. RE MP retail emn1nvment- at chnnn4nr. rinn4'--lead-4,.r. id.. /E ..o 8. DCBD 1, for CBD shopping destination 0, otherwise' 4 for zero frequency 0, otherwise 10. I1IISF 11. DENT 12. XNCF f 0 of persons in the household,.for zero frequency 0, otherwise retail employment density in residence zone (employees per acre), for zero frequency 0, otherwise household annual income (in c(?de*), for zero frequency 0, otherwise 41 ternala No trip (zero frequency), variables (].) - (8) are equal to zero. Trip to shopping destination d and by node m, for all relevant shopping :sestina- Lions (including the CBD), and for car and transit modes. Xncomc code (in 1968 $) x 0 ?- 2,999 6 10,000 -- x1,999 2 - 3,000 - 3,999 7 a 12,000 - 14,999 3 4,000A: r pp lip`s ~ or Release 2001/11/19 :8CFA-IkbF 0O079 00020005-9 4 6,000 V,, 9 - 20,000 - 24,959 5 8,000 -- 99999 . 10 - 25,000 +  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Table 'B.2 S1lbPI'r.NG JOINT THAVET. DEMAND 11OI)1:T. - 177 THE MODEL COEFFICIENTS Variable .Coefficient t-statistic 1. Car constant DC - .555 - 2.13 2. Out--of-vehicle. travel timel' ?'"' divided by distance OVTT/DIST _ - .100 - 3.38 3. Total travel time in (IVTT-l?OVTT) -2.24 --11.85 4. Out-of-pocket travel cost divided by income OPTC/ I nC - .0242 - 4.20 5. Autos available for non work trips (car only) AAC .557 5.61 6. Inverse of distance to .destination 1/DIST 6.86 ]..66 7. Retail employe:: nt at ? dcstina t i on In (REM?) .161 3.29 8. CBD destination constant DCBD .562 2.07 -3.78 - ?4.51 9. Frequency zero constant 10. Household size (frequency zero only) - .186 - 4.57. 11. Retail. employment density at the origin (frequency zero only) .000598 1.38 12. Household income (frequency .0414 1.18 zero only) of observations n 1313 {- of alternative? ?~ 44718 Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 walk trips to shopping, which are not recorded in the Home Interview Survey. This variable measures the density of retail employment in the home zone, and thus is a proxy for the availability of suitable shopping destinations within walking distance of the home. The posi- tive sign of the DENF coefficient means that a household living in a zone with dense retail employment is less likely to embark on a vehicular shop trip (i.e., is more likely to choose a walk shop trip instead). 178 Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 APPENDIX C Auto Ownership Model Table C.1 lists the variables included in the model. The sub- scripts for each variable indicate the alternatives for which the variable enters into the utility function. Variables with no sub- scripts enter into every utility. Seven constants (one for each alternative except the zero autos-transit to work alternative) measure a constant relative effect which the remaining variables do not pick up. These variables represent what might be termed a 'pure alternative effect." The variables AALDc and AALDs measure the number of autos per licensed driver, thereby modeling the auto availability in the mode choice decision. The more autos per driver a household has, the greater the probability the primary worker will use a car to go to work; hence, a positive sign would be anticipated. The variable denoted as Z requires some explanation. It repre- sents the discretionary income left to a household after transporta- tion and fixed household expenditures. The rationale underlying the use of this variable is quite simple. The total utility a household derives from any auto ownership-mode choice selection depends on the attributes of the alternative, one of which is the resources remaining to the household for other uses, if that alternative is selected. The use of the Z variable is based on the theory that the marginal utility of money at a given point on the income curve is the same for all cate- gories of household expenditures. While it is theoretically possible to incorporate a fuller set of alternatives and thereby eliminate Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  iariable Code 'L Dot AALDc '0.. AALDa 11T2 .IVTT .3. OVTT/DIST .4 . "LD .5. fil Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Table C.1 AUTO OWNERSHIP MODEL DEFINITION OF VARIABLES Definition 1, for zero autos; shared ride 0,' otherwise It for one auto; drive alone; 0,.otherwise 1, for one auto; shared ride'' 0, otherwise it .0, otherwise 1, for two autos; 0, otherwise ( 1, for two autos; shared ride L 0, cthcr::ioc 1,' for two autos;. transit .0, otherwise R # of autos/licensed drivers, for drive alone 0, otherwise # of auto's/licensed drivers, for shared ride 0,' otherwise household annual income - 800 * # of peroons.in the household 1000 * # of autos - 250 * daily round trip travel cost (in '$.) 5 1, if household liven in a c'inglo family house, for two autos 0, otherwise daily round trip in-vehicle travel time (in mir&uLes) daily round trip out--ofwehitlc travel time '(in minutes)/one way uiuGance kin m].J.cs) #- of autos/licensed drivers.' car f;cneralizcd, chopping travel cot-t/transit generalized chopping travel cost, for 'one auto 0, othcrwise Approved For Release 2001/11.11'9.:'CIA RRDP79-00798A00020.0020005-9 for one'auto; transit  Variable Code .7. DCITYo .8. DCITYa Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Table C.l(continued) 1, if worker is a civilian employee of the federal government car generalized chopping travel cost/transit gencralized chopping' travel cost, for two autos 0, otherwise 1, if work place is in the CDD, for. drive alone 1 0, otherwise 1, if work plat-'is in the CBD, for shared ride 0, otherwise 250 * daily round trip out-of--pocket travel 'cost. or shared ride.' for shared ride 0, otherwise D of workers in the household, 0. otherwise employment density at the work zone -(employees per commercial Alternative acre) * one way distance (in tiles), for shared ride fl_ nthprwiap zero autos; shared ride to work zero autos; transit to.work one auto; drive alone to work one auto; shared ride to work one auto; transit to work two + autos; drive alone to work two h autos; shared ride to work two + autos; transit to work Approved For Release 200.1/11/19: CIA-RDP79?-00798A000200.020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 possible expenditures on commodities not explicitly modelled, it is undesirable to do so in a practical model.12 Hence, some relatively simple means of collapsing the entire set of ignored consumption choices is required. This is precisely what the Z variable does. It incorporates other choices into a term which represents the income remaining to a ,household after certain fixed household and transportation expendi- tures. It thus provides a way of including transportation costs versus capital and operating--directly in the model. An alternative with zero auto ownership results in a high value of Z, reflecting the availability of income the household would have to allocate to the purchase, maintenance, and operation of a car if it had chosen to do so. Thus, the coefficient of the Z variable in the utility function should have a positive sign. The value of the Z variable was also used to evaluate whether or not a household had sufficient income to preceive an alternative as being available. Any alternative for which Z was less than zero was. excluded from the household's choice set. HT2 is a 0,1 dummy variable representing single family residence. It was hypothesized that single family residence reduces parking diffi- culties and increases the need for multiple automobile ownership for social and recreational trips. The dummy variable only applied for multiple car alternatives. In-vehicle travel time, out-of-vehicle travel time, and out-of- pocket travel cost are self-explanatory. These variables enter the model with the same coefficients for the two modes. This is based on the results obtained by ORA (1972) and Ben-Akiva and Richards (1975). Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The variable AALD is the number of autos divided by the number of licensed drivers in the household and measures the need for addi- tional autos in the household. As the number of autos per driver decreases, the need for multiple car ownership should increase. The difference between AALD and the mode specific AALDc and AALDs variables is that they appear in different equations as measures of different effects, the former an incentive for owning more cars and the latter an auto availability effect for mode choice. One would anticipate that these variables are highly colinear in the data set and that the estimates of their coefficients would have high standard errors. ever, this did not turn out to be the case. The reason for this is that the variables are defined to be zero for different alternatives. AALD is set at zero for alternatives (1) and (2) only. The modal c choice effect AALDc and AALD8 indicated increased car mode preference when autos per licensed driver increased, while the auto ownership effect (AALD) indicated increased auto ownership preference when number of licensed drivers increased. The estimates of the coeffi- cients of AALD and AALDC were highly significant. The next two variables, R1 and R2, incorporate the effects of shopping trip accessibility and thus represent nonwork travel oppor- tunities. These variables were developed by forecasting the attri- butes of expected (or average) shopping trip for each household by both car and transit. This was done using a previously estimated simultaneous shopping destination and mode choice model estimated by Ben-Akiva (1973). The attributes of these expected trips (travel time, cost, etc.) were then weighted using the coefficients of the previously estimated model. Hence, the ratio of car cost to transit Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 cost was taken in order to measure the relative accessibility of car shopping travel to that of transit. Note that when transit is not available to a household for shopping travel, the ratio is zero (i.e., infinite transit cost). Expressed mathematically, the expected value of attribute i for a given mode in, Xim, is as follows: E[Xim] - E P(dlm) Xidm' deD where D is the set of shopping destinations which can be reached by mode m and P(dlm) is the probability of making a shopping trip to destination d given that mode m is used. The generalized price by mode m, GPm, is therefore the following: GPm - al E[IVTTgI + a2 E[OVTTa] + a3 E[OPTCmI where E[IVTT m ] is the expected shopping in-vehicle travel time by mode m; E[OVTTm] is the expected shopping out-of-vehicle travel time by mode m; E[OPTCm] is the expected shopping out-of-pocket travel cost by mode m; and al,a2,a3 are the parameters of IVTT4, OVTTm and OPTC., respec- tively, from a previously estimated shopping travel demand model. Finally, the ratio, R, is simply defined as GP car GP transit The concept of generalized prices was used by both CRA (1972) and Ben-Akiva (1973). Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The.CBD dummy variables are used to reflect the disutility typically associated with downtown car usage which is not entirely. measured by travel times and cost. Effects such as high travel time variance, the frustration drivers experience in congestion, and the unreliability of on-street parking are all incorporated into these variables. . Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 .  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 186 1. M. Beckman, C. B. McGuire, and C. B. Winston, Studies in the Economics of Transportation, New Haven: Yale University Press (1956); G. Kraft and M. Wohl, "New Direction for Passenger Demand Analysis and Forecasting," Transportation Research Vol. 1 (1967), pp. 205-230; M. Wohl and B. V. Martin, Traffic Systems Analysis, New York: McGraw-Hill (1967), Chapter 5; M. L. Manheim, "Search and Choice in Transport Systems Planning," Highway Research Record 293, Washington, D.C.: Highway Research Board (1969). 2. Manheim, op. cit. 3. We deal here with only one of "Wardrop's Principles"; we will not discuss the other, concerned with global optimization of the flow pattern, as this is inapplicable to urban transporta- tion flow prediction. Cf. J. G. Wardrop, "Some Theoretical Aspects of Road Traffic Research," Institute of Civil Engineers, Road Paper No. 36, London (1952); M. Beckmann, "On the Theory of Traffic Flow in Networks," Traffic Quarterly (January, 1967); W. S. Jewell, "Models for Traffic Assignment," Transportation Research Vol. 1, No. 1 (May, 1967). 4. B. V. Martin, F. W. Memmott and A. J. Bone, Principles and Techniques of Predicting Future Urban Area Transportation, Cambridge, Mass.: M.I.T. Press (1965); various publications of the U.S. Federal Highway Administration on Urban Transpor- tation Planning. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Notes (continued) 5. In the equations which follow, standard conventions of prob- ability theory are used. The relevant concepts, explained briefly here, are described in any standard text on probability. P(A) is the probability that a random event, A, occurs. The joint probability P(A,B) is the probability that two random events, A and B, both occur. The conditional probability P(AIB) is the probability of event A occuring when it is known that event B occurs. 6. The conditions are that f 1,f2,f 3, and f4 in (4.5-3) be "internally consistent" as defined by Manheim (1973). 7. Adapted from Earl R. Ruiter (1973), HRB Special Report 143; Cambridge Systematics, UMTA Travel Forecasting Manual; and Marvin L. Manheim, Fundamentals of Transportation Systems Analysis. 8. Usually per day. following code was used: Household Income (in $1,000/year) Code 0 - 3 1 3 - 4 2 4 - 6 3 6 - 8 4 8 - 10 5 10 - 12 6 12 - 15 7 15-20 8 20 - 25 9 greater than 25 10 Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Notes (continued) 10. Binary work mode choice models have been developed by many re- searchers; this model is described here because of its relation- ship to the simultaneous models described following, and be- cause it is the first disaggregate model to treat carpools as an explicit mode. 11. A variety of procedures to adjust a model to a different area are developed and evaluated in Atherton (1974). 12. A more formal case for the use of the Z variable can be made by utilizing the concept of a utility "tree," in which a household's utility function is considered to be additively separable. See Strotz (1957) and Cambridge Systematics (1974). Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 REFERENCES Adler, T. and M. Ben-Akiva. 1974. "A Joint Frequency, Destination and Mode Choice Model for Shopping Trips," paper submitted to the Transportation Research Board. Aldana, E., Richard deNeufville, and Joseph Stafford. 1973. "Micro- analysis of Urban Transportation Demand." Highway Research Board 1973. Atherton, Terry. 1974. "A Bayesian Approach to Transferring Stochastic Disaggregate Travel Demand models," unpublished S.M. thesis, M.I.T. Beckmann, M.J., C. B. McGuire, C. B. Winston. 1956. Studies in the Economics of Transportation. Yale University Press. Beckmann, M. J. 1967. "On the Theory of Traffic Flow in Networks." Traffic Quarterll. January. Ben-Akiva, Moshe E. 1973. "Structure of Passenger Travel Demand Models." Ph.D. dissertation, M.I.T. Ben-Akiva, Moshe E. and M. G. Richard. 1975. "A Disaggregate Multi- Modal Model for Work Trips in The Netherlands." Transportation Research Board. .Buro Coudappel en Coffeng and Cambridge Systematics, Inc. 1974. Disaggregate and Simultaneous Travel Demand Models: A Dutch Case Stu y. Cambridge, Mass. Cambridge Systematics, Inc. 1974. Introduction to Urban Travel Demand Forecasting, a tutorial manual prepared for UMTA by Cambridge Systema- tics, Inc., March. Cambridge Systematics, Inc. 1974. Multinomial Logit Estimation Package: Program Documentation. Version 2, Mod 1. Cambridge, Mass. Cambridge Systematics, Inc. 1974. Series of auto ownership technical memoranda. Charles River Associates, Inc. (CRA). 1972. A Disaggregated Behavioral Model of Urban Travel Demand. Federal Highway Administration, U.S. Department of Transportation, Washington, D.C. Charles River Associates, Inc. 1967. A Model of.Urban Passenger Travel Demand in the San Francisco Metropolitan Area. Report Number 117-1. Prepared for Peat, Marwick, Livington & Co., December. Dafermos, S. C. 1972. "The Traffic Assignment Problem for Multi-class User Transportation Networks," Transportation Science. vol. 6, No. 1, F!pproved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 190 . 1971. "An Extended Traffic Assignment Model with Appli- cation to Two-Way Traffic.." Transportation Science. vol. 5, No. 4. November. ? 1969. "Network Models for Traffic Assignment." Cornell University Department of Operations Research, Technical Report No. 90. Ithaca, New York, October Dafermos, S. C. and F. T. Sparrow. 1969. "The Traffic Assignment. Problem for a General Network." Journal of Research National Bureau of Standards-B, vol. 73B. No:_2. Dial, R. B. 1971. "A Probabilistic Multipath Traffic Assignment Model which Obviates Path Enumeration." Transportation Research, vol. 5. Domencick, T. A., et. al. 1968. "Estimation of Urban Passenger Travel Behavior: An Economic Demand Hodel." Highway Research Record 238. Washington, D.C. Highway Research Board. Dunphy, Robert T. and George V. Wickstrom. 1972. "Accessibility: A Tool for Spatial Analysis." Presented at the 1972 Annual Conference of the Urban and Regional Information Systems Association. San Francisco. Ellis, Raymond H. 1966. A Behavioral Residential Location Model (1966) MS thesis, Northwestern University, June. "Functional and Detailed Specifications for a Highway Network Equilibrium Program." Prepared for UNTA Planning Methodology and Technical Support Division by Cambridge Systematics, Inc., Cambridge, Massachusetts (forthcoming). Hudson, James and Steven Lerman. 1974. "Sensitivity Analysis of Equilibrium Flows in Congested Transportation Networks. Paper pre- sented at O.R.S.A/T.I.M.S. meeting, Boston Jewell, W. S. 1967. "Models for Traffic Assignment." Transportation Research vol. 1, No. 1, May. Koppelman, Frank. 1974. "Prediction with Disaggregate Models: The Aggregation Issue." Paper in Highway Research Record. 1975. Ph.D. dissertation, M.I.T. Kraft, G. 1963. "Demand for Intercity Passenger Travel" in the Washington-Boston Corridor. Systems Analysis and Research Corporation. Kraft, G. and M. Wohl. 1967. "New Direction for Passenger Demand Analysis and Forecasting." Transportation Research vol. 1. Landau, Uzi. 1975. "Strategic Analysis Models in Transportation Systems Planning." Ph.D. dissertation in progress, M.I.T. Lerman, Steven and Nigel Wilson. "An Analytic Model for Predicting Dial-A-~oJSe~' 'F~ a~ M1/1~ ~4( 20( 9 ation Researc oar as ngton, D.C.  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Lisco, Thomas E. 1967. "The Value of Commuters' Travel Time: A Study in Urban Transportation." Ph.D. dissertation, University of Chicago. , Manheim, M. L. 1975. Fundamentals of Transportation Systems Analysis. Preliminary Edition, Third Revision. 1973. "Practical Implications of Some Fundamental Properties of Travel Demand Models." Highway Research Record 422. Washington, D.C. "Search and Choice in Transport Systems Planning." Highw Research Record 293, Washington, D.C. Manheim, M. L. and E. R. Ruiter. 1970. "Dodotrans I: A Decision- Oriented Computer Language for Analysis of Multimode Transportation Systems." Highway Research Record 314. Martin, B. V. and M. L. Manheim. 1965. "A Research Program for Comparison of Traffic Assignment Techniques." Highway Research Record 88. Martin, B. V., F. W. Memmott, and A. J. Bone. Principles and Techniques of Predicting Future Demand for Urban Area Transportation. M.I.T. Report No. 3. McFadden, Daniel. 1974. "The Measurement of Urban Travel Demand." Journal of Public Economics, No. 3. McGillvray, Robert G. 1972. "Binary Choice of Urban Transportation Mode in San Francisco." Econometrics. vol. 40. McLynn, J. M. and T. Woronka. 1969. "Passenger Demand and Modal Split Models." Northeast Corridor Transportation Project, Report 230, U.S. Department of Transportation. Murchland, J. D. 1969. "Road Network Traffic Distribution in Equilibrium." Paper for the Tagungueber "Mathematische Methoden in den Wirtschaftswissenschaften." Mathematisches Forschungsinstitut. Oberwolfach, October . Nestle and Young. 1974. "Short-term Modifications to the Existing CALTRANS Model System to Accept Supply-Sensitive Assignment Techniques and Policy-Sensitives/Demand Models." Working discussion paper, M.I.T., January. Putnam, Stephen H. 1973. The Interrelationships of Transportation Development and Land Development. Volumes I and II, Report prepared for the U.S. Department of Transportation, June. Quandt, R. E. and W. J. Baumol. 1968. "The Demand for Abstract Transport Modes: Theory and Measurement." Journal of Regional Sciences. vol. 6, No. 2. Quarmby, D. A. 1967. "Choice of Travel Mode for the Journey to Work: Some Findings." Journal of Transport Economics and Policy. vol. 1, No. 3, pp. 1-42 Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Reichman, S. and P. R. Stopher. 1973. "Disaggregate Stochastic Models of Travel Mode Choice." Highway Research Record 369. Washington, D.C. Ruiter, E. R. 1973. "Analytical Structures" in Highway Research Board Special Report 143 . Washington, D.C. . 1973. "The Prediction of Network Equilibrium: The State of the Art," in Proceedings of the International Conference on Trans- portation Research. Held in Bruges, Belgium: Transportation Research Forum, June. Ruiter, E. R. and J. Murchland. 1974. Report to UMTA on equilibration efficiencies, in progress. Cambridge Systematics, Cambridge, Mass. Stopher, Peter. 1969. "A Probability Model of Travel Mode Choice for the Work Journey." Highway Research Record No. 283. Washington, D.C. Stopher and T. Lisco. 1970. "Modelling Travel Demand: A Disaggregate Behavioral Approach, Issues and Applications. Transportation Research Form Proceedings. Strotz, R. H. "The Empirical Implications of a Utility Tree." Econometrica, vol. 25, No. 2, April. Systems Analysis and Research Corporation. 1963. "Demand for Intercity Passenger Travel in the Washington-Boston Corridor," Report to U.S. Department of Commerce. Talvitie, Antti and Tom Leung. 1974. "A Parametric Access Network Model." Paper in draft, Oklahoma. Turnquist, Mark. 1972. A Cost Model for Incremental Traffic Assignment. M. S. thesis, M.I.T. UMTA Transportation Planning System Reference Manual. 1973. Urban Mass Transportation Administration. UMTA Transportation Planning System (UTPS) Reference Manual. 1974. UMTA Planning Methodology and Technical Support Division. Washington, D.C., August. Wardrop, J. G. 1952. "Some Theoretical Aspects of Road Traffic Research." Proc. Institute Civil Engineers. Part II, Road Paper #36. London, pp. 325-378. Wilson, Nigel, Wayne Pecknold, and Brian Kullman. 1972. "Service Modification Procedures for Local Bus Operations of the Massachusetts Bay Transportation Authority." The Boston Urban Observatory. Wohl, M. and B. V. Martin. 1967. Traffic Systems Analysis. New York: McGraw-Hill. Yamamoto, Warren. 1973. A Comparative Analysis of Transit Alternative for Non-Work Tri s. M. S. thesis. M.I.T. prov or Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 EXAMPLES OF COMPUTER APPLICATIONS IN THE TRANSPORTATION FIELD Faye C. Johnson The transportation sector of our economy has integrated the computer into their operations so profoundly that today we find this sector to be one of the most sophisticated and advanced users of computers in the United States. For years American businesses have used the computer in their accounting and administrative func- tions but only in the last two decades have they put the computer to use in the very heart of their business, i.e., operations. We find in airlines that they now keep all of their passenger reser- vations on a computer with remote terminals at airports and ticket agencies throughout the United States. They also make extensive use of computers in their maintenance, crew scheduling, and airline ticketing. Railroads, we will see, control their entire car fleets with the use of computers as well as performing very sophisticated analytical simulations to run their operations more efficiently. In motor freight we find their entire rolling stock being tracked by computers as well as their on-line billing and rating. This paper will address some of the more advanced computer applications in only two modes of our transportation sector and, more specifically, to the hauling of freight in these two modes. These modes are railroads and motor freight companies. The inter- dependence of our nation's economy on the transportation sector is apparent to everyone associated with transportation. Overall, transportation expenditures, including material inputs to the production of transportation and services, represent about 18% *Corp.  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 of the United States gross national product and we find these two sectors hauling over 60% of the total freight ton miles by our intercity freight carriers. These figures include both for hire or common carriers and private traffic. Even more significant, we find that railroads and motor freight generate over 94% of all the gross operating revenues from the transportation of goods among the regulated freight carriers. The fastest growing of these two segments is the motor freight common carrier. With the invention of the internal combustion engine at the dawn of this century, the truck transportation industry has grown in the last thirty years from a very minor entity, in terms of revenue, to the largest single sector of all regulated freight carriers. Several factors can be cited as having contributed to the rapid growth of the trucking industry. These are: 1. The suburbanization of many of the nation's population .and employment centers 2. Construction of the interstate highway system 3. The inherent flexibility and convenience of trucks as opposed to other transportation modes When one looks at the application of computers in these two industries one needs only to look at how these companies spend their available money in the operations of their businesses. Listed below are the percent of expenditures on operating expense of all the motor freight companies in the United States as of 1973. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 o Transportation--46% o Terminal operations-22% o Equipment maintenance--9% o Traffic--3% o other expenses--10% o Insurance and safety--4% o Administration and general--6% In railroads as of the end of 1973 we find the following breakdown: o Transportation--50% o Maintenance of equipment--21% o Maintenance of way--18% o General expense--7% o Traffic--3% o Miscellaneous--l% There is no wonder that both the railroads and motor freight use the computer more extensively to control their transportation expenses than in any other function of their business. The major difference between the two charts is that while rail- roads include their yard operations as a part of their total trans- portation expense, motor freight separates their terminal expense from their transportation expense. I would now like to address the use of computers in some leading edge applications for the railroad industry. As mentioned previously, the railroad industry has attained in the last twenty years the status of being one of the most sophisti- cated users of complex data processing equipment for operational Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 real-time applications. This position has evolved over several decades whereby they, like many other industries, mechanized many of their batch-related applications through the use of data processing. Examples of these batch applications presently installed by most of the major U.S. railroads are: o Waybilling o Revenue accounting o Centralized payroll o Car accounting o Disbursements accounting o Freight claims o Material management o Stockholders records o Reports to shippers on car status and location These early batch applications, at the time of their development and implementation, were pressing the state of the art in computer technology and capabilities. A gating factor was computer capability and not railroad requirements. Early data processing, utilizing unit record equipment, had no teleprocessing capabilities and some of the very early computers also lacked this functional capability. When teleprocessing equipment became available, the railroads were among its very first users exchanging information among railroad yards, agencies, and their home office. It wasn't until the third generation of computers became available in the 1960s that the rail- roads were able to apply these management tools to the very heart of their business, i.e., operations. Approved For Release 2001/11/19 : CIA-RDP79-00798A0002000.20005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 We have seen the railroads increase their operating efficiencies over the last thirty years by many means. Some of the more important' are: o Dieselization o Installation of automatic classification yards o Installation of microwave communication systems o Extensive applications of computers It is considered by many that the latter may have more impact on greater efficiencies in operations than any of the other develop- ments in the last three decades. It is apparent, with over 1,700,000 freight cars in the U.S., travelling over many thousands of miles of track, the utilization of this valuable asset becomes a major challenge of railroad management. Today we find that a loaded car is moving only 11% of the time towards its destination. The rest of the time it is empty or sitting in a railroad yard, a repair shop, or at a customer siding being loaded or unloaded. Obviously, improving this 11% payload utilization can mean significant returns to the industry. To be more specific, assuming an average railroad car costs $25,000 each and with 1,700,000 cars in our national inventory, for every 1% increase in the utilization, this industry can have capital expen- diture avoidance of $425,000,000. Another way of expressing it-- it is equivalent to adding 17,000 additional freight cars to its inventory. Improving this utilization is the central objective of.the use of computers in the railroad industry today. These computer mechanization activities include such applications as: Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 1. Car Movement Reporting--Keeping the exact status and loca- tion of all railroad cars and power on its system and re- porting any change of this status to the appropriate points within the railroad that has need of this.infor- mation 2. Scheduling of--Cars--The allocation of available empty cars to shippers, the disposition of empties, and the determina- tion of an appropriate sequence of trains for transporting each loaded and unloaded car from origin to destination 3. Scheduling of Locomotives--The allocation of power in accordance with train schedules, tonnage, and maintenance requirements 4. Scheduling of Trains--Determination of departure and arrival times for each scheduled train; determination of when to operate "extra" trains and to cancel scheduled trains 5. Emergency Responder -Response to systems outages, e.g., derailments, locomotive breakdowns, electrical power and signal failures, bridge washouts, etc. 6. Scheduling of Track (Dispatching),--Control of train movement on all main and branch lines 7. Scheduling of Roadway Maintenance--Allocation of personnel and equipment for inspection, maintenance, and repair of system track and related facilities 8. Scheduling of Car Maintenance--Determination of time and place for inspection, maintenance and repair of freight cars 9. Scheduling of Crews--Selection of trained operating crews in accordance with work contracts, availability, train schedules, and assignment Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 While this is a very ambitious. application list for individual rail- roads, we find that many of them today are well on their way in their development and implementation. To begin this scenario of applications, a railroad must start with the very complex real- time application--car movement reporting. The objectives of this application are: 1. Reduce clerical burden in yards, agencies and, in some cases, the general office 2. Provide management at all operating levels with complete, accurate, and timely information for improved control and utilization of cars, locomotives, and terminal facilities 3. Establish an historic data base for the eight future real- time applications noted previously The first phase of car movement reporting can be categorized as the data collection phase. Through the use of lease lines or micro- wave with data'processing terminals installed at several hundred strategic locations throughout the railroad network, many events are reported to a central processing unit as they occur. Some ex- amples of these events are: . Cars interchanged . Cars to and from industry tracks Cars assigned to arriving and departing trains Cars loaded and emptied . Cars bad-ordered Locomotive assignments and status . Crew assignments Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 After a network is established tto gather this data, then reports are transmitted to appropriate terminals. Most of these reports serve the operating department. Reports generally give status of a car, a group of cars, a train, a yard, etc., or performance of a yard, group of trains, etc. Examples of these reports are as follows: . Detailed and blocked train consist ? Cars which have high, wide, or heavy loads Car inquiries for location and status for manifest information and for advanced car tracing Speed-restricted cars ? Car listing by location List of trains by route . Power and caboose reports--on hand and arriving in yards Locomotive maintenance due Cars delayed in a yard Terminal performance reports . Yesterday's train performance Current situation of yard's train and power After these types of reports are generated, management can issue the following instructions. Phase I Train schedules Policy governing blocking rules Movement of power from one location to another Instructions to hold a car or divert a car Special and standing instructions ApproV?{- eReW*ME06fl/tkjt9; (eU P#9e0019S @ P006,46005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 After the data collection. phase is established, other phases can take place such as: Phase II Traffic functions Reports for shippers Advance car tracing Phase III . Pool inquiries . Monitor train blocking and train reports Phase IV Dispatcher inputs Initial car distribution functions Yard summary reports . Revenue data input . Additional train reports Phase VI . Power, caboose, and crew functions Car orders and complete car distribution functions and reports Phase VII Phase VIII Other off-line applications Car, locomotive, and caboose statistics Demurrage accounting Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 202 The car reporting application establishes the data base which is necessary for the railroads to commence the development and im- plementation of some very exciting additional applications which will further increase the efficiency of their rolling stock. I am categorizing these additional applications under the generic term; railroad operations control. There is widespread agreement that there are two solutions associated with railway freight ship- ments that can go a long way towards increasing the efficiency of their operations. 1. The ability for the railroads to provide shippers with empty cars for loading of the proper type and grade when they are required and in sufficient quantity. 2. The establishment of dependable and consistent shipper to consignee transit time. It is clear that the optimum utilization of freight cars requires the solution of extremely complex mathematical scheduling problems. It is equally clear that concepts of mathematical optimization need to be adopted in a systematic manner by the railroad industry in its attempts to solve the varied and interrelated functions of freight operations. Until quite recently the technology required to formulate, solve, and implement the solutions to the highly complex problems associated with freight operations has not been available. The necessary ingredients of this technology include telecommuni- cations, on-line high speed data processors having suitable large memory capacity, remote terminals for entry and receipt of control information, as well as efficient algorithms for solving mathematical models in a quasi real-time environment. Much of this technology is Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 203 now available. Accordingly, railroads are now taking a fresh look at the railroad operation control system in an effort to achieve maximum benefit for both the railroad industry and its users. I previously mentioned eight scheduling functions associated with railway operation control and, to repeat, these are: ? Scheduling of cars . Scheduling of yard operations ? Scheduling of locomotives ? Scheduling of trains . Scheduling of track ? Scheduling of roadway maintenance ? Scheduling of car maintenance ? Scheduling of crews While all aspects of freight operations contribute to the quality of service railroads may provide, significant relief of the primary chronic problems may be expected to result in the application of modern technology initially to the scheduling func- tion associated with cars and yard operations. Car scheduling, of course, embraces the movement of both loaded and empty cars. Clearly, these two subproblems are highly interrelated in that typically train traffic is a combination of loads and empties. To facilitate understanding of the special problems of handling of empty cars, it will be helpful to describe briefly the essential scheme for moving cars across a railroad way network. Freight cars must be moved from their known origin to a prescribed or computed destination (it may be assumed herein that origin and destination are contained within the same railway network). Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 To accommodate the multiplicity of diverse origin/destination pairs, an operating plan has evolved over the years based upon a hierarchy of trains and strategically situated classifying yards. Cars are switched in the classifying yards into blocks having a common inter- mediate or final destination in accordance with a railroad blocking policy. These blocks are placed on scheduled trains and transported toward their ultimate destination. The classification policy of a railroad specifies which blocks of cars may be carried on each scheduled train, the order of the blocks, and the handling of the blocks en route. Frequently, the railroad is forced to deviate from its operating plan because of surges in traffic, mechanical failure of equipment, or temporary loss of supporting facilities, i.e., main line, bridges, electrical power, etc. Normal operation is further confounded by system limitations on basic resources such as power, train length and tonnage, crew availability and work rules, yard switching capacity and mainline availability. Deviations from normal operation often trigger cascading effects of significant magnitude. The input to the car scheduling subsystem would be empty and loaded cars released by users within a given railway network or received at interchange. Output from the system would be car move orders which, in essence, represent trip plans for the movement of each car through the railway network. This system, as I mentioned previously, is supported by their comprehensive car movement re- porting and monitoring systems which created the required data base for car scheduling. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The car scheduling subsystem would contain three major func- tions. 1. Empty Car Disposition--Determines whether an on-line empty car may be considered a candidate for loading. In many instances, regulations prohibit or limit loading of empties and, in effect, prescribe the destination to which a re- stricted empty must be moved. 2. Empty Car Allocation--Determine the optimum destination for each loadable empty according to the overall system supply, demand, and selected decision criteria. 3. Traffic Scheduler--Determines a suitable trip plan for all necessary car movements in generating appropriate car move orders. Certain of the above types of problems cannot be resolved within an empty car allocation model or subsystem. However, these problems must be addressed within an overall freight car management system in order to provide necessary support for empty car allocation. At present, railroads allocate empty cars in a manner similar to the following: A shipper phones his order to a freight agent. If the order can be filled locally with unassigned empties, this is done. Otherwise, the order is transmitted to a division car dis- tributor. These individuals maintain, to a limited extent, a record of the required number and type of empties needed for their division, along with anticipated releases. According- ly, the division car distributor knows generally what empties are available for allocation in the shipper's vicinity. He Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 calls an appropriate yard and places a suitable order for the necessary empties. If a division car distri- butor is unable to fill an order, he passes it on to the office of the system manager of car utilization. Cer- tain individuals in this office are responsible for allo- cating specific types of cars, e.g., open top cars (plain flats, coal hoppers, gondolas and chip hoppers). Each week, the system car distributor's office issues a docu- ment which contains instructions for disposition of all system and foreign equipment. Daily modifications to this document may be transmitted by telephone. In a similar fashion, each yard creates a daily disposition sheet which is distributed to car agents, car inspectors, and yard masters. Generally, empties have a lower priority than loads in that they will be removed first from a ,train that is too long or heavy. This practice contributes to local yard congestion and may cause shortages at other yards. In order to provide an effective way to utilize a computer-based technology for the assignment and control of empty railroad freight cars, it is necessary to model the problem analytically. This can be done by applying the resource allocation methodology of operations research. Factors to be Considered There are a number of factors which should be considered in the design and development of an optimum-seeking allocation model. These include criteria relating to the accuracy and relevance of the model Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 within its functional context as well as within its operational con- Various railroad policies should be accommodated. Among these Shortage sharing Car service rules . Regulatory constraints . Per diem minimization A given customer must ultimately receive a specific car. While one can devise models to handle the assignment of individual cars, it is unclear that this is the most effective approach. It may be more appropriate to group cars into specific "classes" based on car type, condition, special equipment, etc., and assign them to yards based on this classification. The specific assignment of individual cars to nearby customers may be resolved at the yard level, either automatically (by use of a more detailed optimization model), or manually (perhaps with the aid of visual displays), or a combina- tion of both. Overall control of cars would still be maintained on a systemwide basis by use of the allocation model on a "global" scale, with the specific cars assigned to customers selected from those cars globally allocated to a yard in the customer's vicinity. It would appear that such a two-level approach (aggregating at the higher level and "exploding" the aggregated solution at the lower level) is more reasonable. This last point relates as well to the operational use of the model. To be effective, the model must be used regularly on a semi- reaAMM"After R ns~eE2 1kflUl tcf ilpei~[ d~~-(}~ ,-gin part,  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 upon the dynamic character of the problem data. This may be several times a day or as infrequently as once a day. While empty cars must be allocated throughout a railway system, there is a natural division of this problem into two parts. One deals with the global aspects of empty car allocation--the systemwide distribution of cars between major yards. The other part of the problem deals with the local aspects, i.e., ensuring that individual shipper's requests for empties are satisfied, as well as determining where released empties must be sent. In terms of actual railroad practice, the differentiation between these two problems (global and local) is important. Consideration of the global problem leads to simplifications since one need not consider all the detailed differences between car types and can aggre- gate similar types for routing between major yards. Nevertheless, at the local level it may become necessary to distinguish between cars. However, local problems are separable, i.e., are independent of each other; thus, the local car distributor's knowledge can be utilized to facilitate solution of the problem. It will often be possible to take advantage of the distributor's familiarity with the.shippers in his area regarding such questions as the condition of a released car, or whether substitution of one type of car for another is accept- able. To formalize the distinction between the global and the local problem, the concept of a car service area will be introduced. A car service area is that "territory" serviced by a single major yard; while there may be secondary supply points within the car service Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 area from which cars may be"supplied to customers in the area, any car which comes from outside the car service area must enter the area through the major yard. Major yards are linked by through trains, while individual shippers are served by local trains or yard engines which typically run between two supply points, or out and back from a single supply point. Car service areas may be considered as a mechanism whereby local information. can be aggregated for systemwide use. That is, the net supply or demand in the service area can be determined and associated with that area's major yard. Thus, in terms of the global model, systemwide empty car allocation may be based on the net supply or demand at each of the major yards. Having solved the allocation problem at the global level, solution of the associated local problems can be obtained by "exploding" the global solutions. In the event that there are alternative ways of supplying or receiving cars within a car service area (for example, when there are secondary supply points), an additional optimization will be required. Because of the way in which car service areas are defined, treating the problem in this two-level fashion (global-local) and optimizing individually, one can achieve the same overall optimal solution as if all the problem aspects (both global and local) were combined into one large problem. In many cases, the local problem need not be solved by an optimi- zation technique for there may be no alternatives to choose between. For example, this occurs when a customer on one branch in the car service area must receive his cars from a single supply point and, when cars are released, must return to the supply point. In these Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 210 instances, it is sufficient to'keep a detailed list at the supply point of requirements and releases; these cars will be moved on the first available train consistent with the release/requirement time. If there are insufficient cars available to satisfy require- ments within a car service area, the global problem solution will provide for empties to move to the appropriate major yard. Similarly, if surplus cars are available, the global solution may specify they be sent to other major yards. The Allocation Model The allocation model utilizes a two-level scheme, with one level treating the global or systemwide aspects of the problem, and the other dealing with its local aspects. For the global problem, cars in a class would be aggregated into groups by type, location, and time of availability such that it would not be necessary to distin- guish between cars within a group. For the local problems, specific cars in a class may be considered directly in the model. Thus, a specific car, if not needed locally, would be grouped and allocated in a global problem, and then assigned specifically in a subsequent local problem run. The determination of the final destinations for empty cars is possible through the use of simulation techniques. Dynamic scheduling of cars and trains would be the end result whereby railroads could meet their overall objectives of railroad operating control systems. The most important aspect of a viable operating control system is to provide better controls over the railroads' assets. It will provide: Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 1. Better control of trains because advanced information would be available on the exact volume of traffic to be moved 2. Better control of empty and loaded cars--a determination will be made as to which cars will be moved in what se- quence along what route and on what train 3. Better control of car distribution--disposition instruc- tions are part of the computer programs and would direct the movement of empty cars. The computer would signal any failure of an empty to move as planned The development of an intraline operating system is required before a nationwide interline system can be developed. Railroads are moving soundly towards their achievement of the first phase. The Association of American Railroads with their TRAIN II system is providing the basic framework for a national car interline control system. When this event occurs, it is the writer's feeling that the occurrence will be recognized as the single most significant happening in the railroad industry during its entire history. Motor Freight Industry Now, let's turn our attention to the motor freight industry. This sector is the lifeline of goods for our country. It's a business that never closes its doors without affecting every industry and every con- sumer--a business that's built on giving a mobile society the freedom it needs to prosper. The ever-rising cost of labor and equipment, competition, and unexpected events like our recent energy crisis, present constant and changing challenges. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 212 For carriers, external, uncontrollable factors such as fuel prices, labor contracts, financing, and interest rates create prob- lems in many of their operational areas. But carriers do prosper in spite of these external factors when management improves its handling of its own internal operations. Probably the most important areas that carrier management is addressing are its freight terminal and linehaul operations. By im= proving its impact on these areas, management is accomplishing three basic objectives: service, productivity and control. Service is the carrier's competitive edge. Providing better shipment status information and insuring accurate billing and in- voicing on a timely, consistent basis are the keys to improved cus- tomer satisfaction. Productivity for motor carriers is coming from the increased productivity of people and equipment. The areas which are being addressed include linehaul equipment availability and utilization, dock worker productivity, reduction of empty movements, and improved load factors. Control of operations means control of equipment in the areas of balance, interchange, maintenance, and licensing. It means con- trol of revenue by eliminating lost bills and transcription errors, and providing positive delivery verification. It means control of freight to reduce over, short, and damage; reduce inactive freight; and facilitate tracing. In view of the demands placed on management today, new tools and techniques have been developed to sustain the profit and growth rates of the 1960s. One of the tools that many carriers have looked to is the computer. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 It has been used in the motor freight industry for some time. Today it is possible to interface a computer to a communications network and capture information as events occur. As a result, information is being retrieved on demand, information that's timely and accurate, that allows decisions on service and productivity to be made on a real-time basis. Implementation of computer-based teleprocessing systems has typically been an expensive and time-consuming proposition when undertaken by an individual carrier. In working with the motor freight industry, IBM has developed a system of application programs to answer the operational needs of service and productivity, while avoiding the duplication of substantial dollar expenditures and effort. Other similar systems are available; however, because of my familiarity with the system we developed, I will confine my remarks to our system as illustrative of what carriers are doing in these advanced application areas. We call our system FERST/VS--Freight and Equipment Reporting System for Transportation/Virtual Storage. FERST/VS is a tele- processing system designed to provide the management of a motor freight company with timely and accurate information on the move- ment of freight and linehaul equipment throughout their system. FERST/VS offers four application programs to assist operations management: message switching, equipment control (including a ship- ment tracing function), freight billing, and rating rate audit. These programs help improve customer service, increase the productivity of equipment and personnel, and give motor carriers better control of operations. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Let's now discuss each of-these areas in detail. Morning re- ports, terminal performance and statistical reports, hot shipment advice, or over, short, and damage reports are entered and transmitted effectively between terminal locations and the central office. This is called the message switching application. The motor freight industry has recognized that the key to success lies in the control of terminal and linehaul operations. Efficient scheduling of linehaul and city equipment and planning of terminal resources are critical if the use of manpower and equipment resources is to be maximized. If the dispatcher wants a list of all tractors or trailers at a given location, he can enter an equipment inventory inquiry. He is presented with a list and status of that equipment. Changes to equipment status are reflected in the report generated from the equipment inventory request. This information is as current as the entries made through the communications devices. One of the high points of equipment control is the information it supplies to terminal management on schedules which are currently en route to their location. Terminal personnel retrieve information on schedules destined for them within a specified number of hours (e.g., next sixteen hours) or on total schedules moving in the system with freight destined for their terminal. The report generated as a result of this inquiry gives the ter- minal personnel estimated time of arrival by schedule, weight/cube/ number of bills, and any specific load information entered at dis- patch, trailer close, or billing time. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The schedules en route report has many potential uses in- cluding: Preplanning dock and city equipment requirements Preplanning trailer spotting at the dock based on large mark information . Anticipating equipment availability at a given location Providing accurate information on inbound tonnage and shipments Projecting dock crew workloads Once a shipment has been recorded in the system's data base, the current status and location of that shipment is retrieved by entering an inquiry. The operator receives an immediate response from the computer showing the location and status of the shipment. Revenue, shipments, and equipment must all be considered in the control system for the operation of a motor carrier. Efficient uti- lization of equipment control system which is integrated into the freight billing system. Let's now look at the freight billing application and see how it interfaces to the equipment control facility in order to provide a full-function motor freight operations control system. Equipment control is a computerized system designed to assist dispatching, keep real-time equipment inventories, and provide ship- ment tracing and advance schedule and load information. Equipment control application functions are broken into the follow- ing three areas: 1. Equipment movement reporting, which consists of simple input messages used to report changes in status and loca- tion of linehaul equipment. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 216 2. Inquiry and tracing, which allows the carrier to inquire as to the current location of equipment, equipment inven- tories at any terminal location, schedules en route between locations, and the last reported status of a particular shipment. 3. Shipment control which gives the carrier the ability to report changes in status and final disposition of individual shipments. Now, let's take a more detailed look at some of the features of equipment movement reporting and how they are helping the motor carrier's operation. For example ... When a schedule (that is, tractor, trailer combination) is ready to move,.a dispatch message is entered. The message reports the movement of that schedule to the computer and updates the equipment files to show those pieces of equipment in transit between terminals. In order to report trailer interchange between carriers, the program provides a trailer rental and interchange message. Once the information regarding the interchange is entered into the com- puter, the carrier keeps track of the time when the trailer was taken on-line or put off-line and the return point. This informa- tion facilitates tracking interchange activity and calculating accurate per diem charges. The equipment movement reporting facility also allows the carrier to report on changes in equipment status. Examples would be a tractor placed in the shop for maintenance or a trailer spotted at a customer location for loading or unloading. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Let's now look at the inquiry and tracing facility. Here are some of the facilities it provides that are helping carriers improve their linehaul and terminal operations. Freight billing is divided into these functional areas: Bill entry Manifesting ? Delivery reporting ? Management reports Many edits are performed on the bill before it enters a system. For instance, pro numbers are checked for validity, destination codes are checked to be sure they are valid, extensions and totals are checked for accuracy. Conversational editing of the bills at this stage helps insure accuracy because the person creating the bill can make corrections while the original bill of lading is at hand. This type of bill entry eliminates the need to keypunch bills for entry into a revenue account system, avoiding a step where transcription errors can occur. Since all of the information from the freight bill is available from the data base, it is possible to do manifesting and to produce more detailed reports to be used as advanced planning by terminal management. The two primary documents produced by the manifesting section of the freight billing are the tracing manifests and the trailer summary manifests. Tracing manifests are available to terminal locations on re- quest for both inbound and outbound shipments. Inbound manifests are sorted into alphabetical sequence by consignee; outbound Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 manifests are sorted into alphabetical sequence by shipper. Terminal personnel uses the tracing manifests in conjunction with the trace inquiry to answer all shipment inquiries submitted by either shipper or consignee on a particular pro number. The trailer summary manifest is an extension of the schedules en route report which is produced in the equipment control program. As a result of the freight billing operation, weight, destination, and additional comments are available. The trailer summary mani- fest is of particular significance to break bulk operations because it summarizes shipments, pieces, and weight by ultimate destination. Terminal management uses the trailer summary manifest in planning its city pickup and delivery requirements. Prior to the arrival of freight at destination, full freight bill delivery sets are printed on request at the terminal. The delivery sets are used for the delivery of the freight. They may also be the documents used to control stripping of the linehaul trailer and pickup and delivery loading. The freight billing system allows the carrier to report the final disposition of a shipment via a delivery message. If the carrier chooses, this message will trigger automatic invoicing. It may also be used to record over and short information. Once a system has been implemented to do overhead freight bill transmission, the centralization of the rating and rate audit func- tions is a logical next step. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The rating rate audit application package provides the three functions required of such a system: 1. Rating--separated from bill creation and supported at one or more central facilities. 2. Rate audit--where the billing system selects those bills to be audited automatically based on user-defined para- meters. 3. Rate quote--which allows terminal personnel at remote locations to submit requests for rate quotations through their communications devices. With rating rate audit installed, the billing clerks enter skeleton bills at the origin terminal. Eating personnel at a central facility are presented sequentially with the unrated bills grouped by tariff bureaus. The rate clerk then enters the appropriate rate. The rating program will then perform the extensions and total the charges. The rate audit automatically selects those bills which are to be audited. The invoicing of bills queued for auditing is prevented until the audit procedure is completed. Many carriers select the weight and charge parameters that determine which bills are selected for auditing. The rate quote facility allows terminal personnel to enter re- quests for rate quotations on their communications devices. The re- quests are presented to rating personnel at the central facility. They enter the appropriate response, and the request is sent back to the origin r Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Among the potential benefits to be realized through the use of the rating/rate audit programs are: Reducing the wait time for shipments Alleviating pressure on rate clerks--reducing their errors Allowing a greater degree of rate specialization through centralization of personnel . Reducing the number of rate clerks In addition to the on-line capabilities we have discussed, these programs generate a number of summary and statistical reports that help a carrier measure performance and more effectively control his operation. Inactive freight reports help terminal management control over, short, and damage, and improve customer service. To summarize the potential benefits of these on-line applications, let's recap the areas of service, productivity, and control. Under service, the shipment tracing inquiries and reports help to answer customer requests more quickly. The equipment control por- tion helps to balance equipment, keep track of special equipment, and make it available where it is needed, when it is needed. Freight bill transmission helps move the freight faster, reduces over-and- without bill situations and the on-line editing of bills reduces biller errors. Delivery times recorded provide a record for manage- ment of how schedules are being met. The inactive freight reporting helps terminal management control over and shorts. Under productivity terminal managers can anticipate manpower and city equipment needs with the schedules enroute and trailer summary reports. Central dispatch and terminal managers can improve load fac- tors, increase utilization, and reduce inactive equipment with the Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 accurate, up-to-date equipment inventory. Biller production can be improved. Rating/rate audit further improves biller production, be- cause billers no longer have to enter rates and charges on each bill. Centralized rating also helps clerks become more productive. In the area of control these applications offer better control by providing a data base of information on the carrier's operations when and where needed. That can mean better decisions made, poten- tial problems anticipated, and action taken before potential problems become real ones. Information is provided to: . Terminal management with-- Schedules en route reports Empty movement reports Inactive freight reports Biller production reports . To linehaul operations with-- Equipment inventories Tractor cycle and relay reports Inactive equipment reports . To accounting with-- Master bill file verify and balance reports Delivery verification . To data processing management with-- Terminal usage reports Communication circuit analysis System error incidences Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 And it also provides information to executive management who can review the same information to measure relative terminal per- formance, fleet utilization, biller and dock productivity, and many other facets of his business. I hope the preceding computer application examples have given you some feeling for the considerable extent to which our transpor- tation industry has applied the computer in their day-to-day opera- tions. While most of the uses have been in the inteamodel area only, it will not be too many years away before intermodel exchange of information and control becomes commonplace. Perhaps some time in the future we can have a worldwide transportation control system. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 COMPUTER APPLICATION IN THE ALLOCATION OF AIRLINE RESOURCES Morton Ehrlich * Airlines today, at least in the United States, operate in an environment characterized by: - Limited resources - Rising costs - Restrictive labor contracts - Government regulatory policies - Increased competition - Economic sluggishness, depressing traffic growth Within this environment, the challenge is not necessarily one of viability, but one of survival. Classical solution systems are no longer applicable to today's problems. New and advanced methodologies and techniques must be developed to respond to current competitive and market pressures. This paper addresses the major problem area of the practical allocation of aircraft resources as a function of market demand and fleet mix, and discusses the development of new systems designed to respond to the problem. There are three key phases which dictate, to a large extent, the allocation of airline resources: - market planning, which defines market strategies and revenue generation - schedule planning, which converts market strategies to specific flights, and coordinates implementation - flight crew pairing and allocation, which attempts to optimize the use of the human resource Appf elease iced For R President of 2001/11/19 ng,CFas Dtrn79AggJJ?J200 P020005-9 V  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 All these phases converge into schedule development, the master control of the consolidated allocation process. Within each phase, computer systems provide support: - A marketing information system using data base management software supports the market planning function. The data base contains several years of proprietary eastern, compe- titive, and industry traffic and operational statistics. - A frequency planning model is used to conduct preliminary evaluations of future schedules. Results recommend the optimal sizing and frequency of utilization of aircraft, by fleet type. - An online flight crew pairing system provides crew manage- ment with the capability to interact with computer-stored files, and update the crew schedule with evolving changes to the general flight schedule. - An online schedules development system provides the cap- ability for online updates to the master flight schedule. This system provides overnight turnaround of schedule listings reflecting the latest resource allocation judge- ments. Before discussing the resource allocation function, let me give you an overview of the facilities and hardware used to perform the allocation process. EASTERN'S COMPUTER COMPLEXES Eastern has three major computer centers: Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 At Charlotte, North Carolina, the approximate geographical center of the domestic route structure, are three UNIVAC 494 computers with supportive peripheral hardware and soft- ware. This center monitors and supports the day-to-day operation of the airline, through an extensive, high-speed communication network operating in a real time, online en- vironment. Statistics collected throughout the day are trans- mitted between 2:00 A.M. and 4:00 A.M. over a high speed data link to the administrative center in Miami for report produc- tion within a batch environment. In Miami, there are two other major complexes: one, supporting the systemwide reservations network; the other, providing re- quisite processing for the administrative, financial, and engineering and maintenance requirements. Two IBM 370-195s and two IBM 360-65s configure the reservations complex. In addition, they - Support the automated passenger processing systems at our major airports and ticket offices. This system makes avail- able to the counter agent within a real time framework: ? Reservations status for all flights ? The capability to offer seat selection within an automated environment . The capability to generate automatically tickets from the reservations record ? Flight operational statistics ? Provides total processing support for several regional airlines' reservations requirements Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The system also communicates with the administrative computer complex via a high-speed data link. The administrative complex is comprised of four IBM 360-65s, one IBM 360-30, and several smaller computers used either as front ends for high-speed communication networks or support for interactive systems oriented to a single function (Exhibit I).. Systems discussed in support of the resource allocation process all reside within the administrative complex. Now let me start developing the application framework. MARKET PLANNING The market planning function has the primary responsibility for revenue generation. Activity groups comprising the function are responsible for developing market strategies, monitoring and analyzing market traffic performance, and coordinating product-related input to Sales, and Advertising programs. Market Strategy Development On a monthly basis, market strategy development monitors (Exhibit II): - Industry traffic and operational statistics - Competitive actions - Eastern's performance for each market on the eastern system From three to six months prior to the schedule-planning process, the top 400 markets are subjected to analysis. At this point in the process a demand forecast of industry traffic is made for each market. The results are then used in a forecast algorithm to allocate industry Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Ap+ot jF _LJ 71 ~ 1:r P'? ~i r.J ~ ~L?;I 1 ~ ( ~M Ir ~ I _i jl ) ~ ~ , \' t` // ( ,a c; 1 ~+~' ({ I III :1 -71 .~; r .. 4-- - ? - V) Z2) T1 Vii App I I ,I, = 1 i; t I 1: - 0 -RDP79-00798A00031 00, IFel,sg. 9.6CIA-RDP 9:,~1~$i4000200 12ES~0~=9 . ~?f ~J ~l m 2'27  Approved For Release 2001/11/19 : CIA-RDP7,9-09798A000200020005-9 I' :r. r. f? N v N' to N ' .c c, v. ro ~, V W. N U. a?A? A A U 4 ? + + f 0..4 ' v w .?? N ?r -! N W N w? W W WS 4 N .L' (p h r . ' ?4 OC 0 r . 1. L) ltd. N N N N N h h M h' r ? P, IL LC W ,- ' fr ?. ?r t + t t a tv + . + i + u. V, I- I.) 0) oC N 0 af' 'C G 4 0' ;~ V? 'j co 0 kA Lp to ." f- p. '. I- h N h h h N h 'v M 4. 4 1.4 M' I. a a U 0 0 C) a a 0 0 1 0' 0' 0 0 x r C) O O 0 0 O O 0 c) t7 0 0 0 U) di: x a ~+ O N r- N N IA 0 0 o 0 0 Vt W o 0 V' 0 u C) a l 3 ILI )v+ ? a ? 1 ? ? a ? ? In M .t N IA to 1n 4t an Y\ li ? Z.; I.- N N N LIN v Ai 'C 'T 0 W 0 w -- d U n :.l ? a N N r + ? -+ 'O M .r .?1 I -?' L[ '- N of N .?? a .?1 W t .+? + t + + 1 4 .? i r~. 'r a.1-. a, v v v o 0 o a o v o C) N G ?R . ; I U w . t7 Y 'n R) S W - LIN to in W ap .D W f0 :.1 N H .r ID '.. N W. W N w tti w w ,u W at W W N L? :L W Q? 01 rI , 0 Q "1 ?0 h .r :r. -+ vt ?G IA a a ? ? a ? ;d 4 V L 'J W C)? NI .r f.' -, W 4t x U .J J R .) Z I1' W Ut + t w t J + A t U. t ut + ?tl + 4) ILI + C W C 4 Y U: N I-. U .C O 4' r l .1 C' cr N tV Sll .,; .' U l (y Cl n: Ut O L .I? 4 0 J~ V) _j C' r.. S W 4 ? ? a I ? ? ? ? IA N -?I u) M ) N h + -4 + t + I-?Z 1- ?t CL ,.J W W L t W U X N C ?LL U CL LJ a' C) 2 U z :U 4 -r N N -?I N In - -?. rl r? - N P J , N N .11 f?1 N N I'i N ft7 C7 CJ 0' ?a Y1 I .. w * I- u S N M C )L ?i % ~: L V ^) .0 r4 'C co LIN ?T) N 0) W N 0 .a' . IF -' u! r, N .A C) f?t ' n'' ?T ?- M M v T 0, . N VJ O N M 0) ?U o N' ?-f N t' .. N O .t N in N 0 M ?t 4 .-I N 'r .c? U S xu M 0 0 a 0 a 0 0 0 O O tJ ~q O P4 0 to +. ~. NL:I 0 0 o O O 0 0 0 o o o 0 0 I) 4a 1 u + l) 'v 14 W Ir .?1 .t V. ?N w' .1 Y) i V1 1 ~l W -4 M ?r N N r) in I.1 I'') rt) 'I .t ?A 6 I W aJ -. M H N ??d -l -4 -?1 N -Y H ?.r H --J_tJ m n .A 1A N r) ? O !. cr. W IA N -4 N N 11 W U.) v v1-- I I'I u1 I? ??? r h 0G W 0) f?) U.) It fU OF. LA ?t. + ?'' t + + to v t + I... u LIN ?u V 0 U 0 0 tJ O O U a v ar tr N U U U If C) C.) C.) 0 I.) a c.) IN ?' I ? I ? ? a a ? ? a v1-?L, LIP v U' a1' V' u '3 U U v 0 v V u U v C? V U L) V U + -. .''' ?.. -' .-4 + p. + + + + Y + + + 1?- W .r J -4 (Ij rv r- U U V% r N -4 V. III PI 1 IV cu CV) r i fn r- i -i ? ? ? ? a N h P. 9 tit ?i to N U' V. N N N s V. 1.+ V' V' V' V' +. + + + + + + + + + + + + C.) >- 0 O O C) 0 0 V 0 W L4 }. .?t ?.i 10t .!. 0 W W -% f+) 0 W I') Ut C' W ?-4 M Ir p1 N ^) M J? I' ? 4 '7 .! C) .?I -. ..' M -? -. ..y .? 0' 0 0. .?' vt CA J N A 111 tr C" - r w r i0 41 .1 . 11 V ?1' H Il U' N -+ O , V ' I r ? ? ? ? ? ? ? ? N 0 . N + ..', H N + N? + fl' + + + + + + + Approved 'For Release 2001/11/19 CIA-RDP79-00798A000200020005-9 It. I). A. 1 .1. ? 'V -? ?,/ f'? I r r t? 1 t .+ CJ 7 ? 'J V) M G Q C, U I,t 1 ?a  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 projections among Eastern and competitors. Several iterations of the statistical forecast are required to test multiple competitive assump- tions. When finalized, each of the markets will have been assigned a priority based upon its revenue-generating potential. The priority is later used to determine alternative tactical plans when recommended priorities cannot be accommodated because of resource or utilization constraints. Traffic Performance Analysis In depth analysis of Eastern's top 400 markets include enplane- ments, onboard traffic, 0&D traffic, seats, departures, load factor, seat share, and trip share. Two reports serve as the basis for the analysis: - A market traffic performance analysis (Exhibit III) reports traffic at the non-directional market level with summaries of sixty economic and market group entities. This report is oriented to sales and advertising functions, and provides the option of adjusting strategies and programs to conform with market performance. A directional traffic performance analysis (Exhibit IV) re- ports the same data elements as the market level report; however, it reflects traffic performance at the directional station pair level, with summaries at the station and regional levels. This report is used during the schedule development cycle to fine-tune strategic and tactical plans scheduled for future implementation. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  ., j1 F .4 ..1 I``r N < I I. IL v ?r )f ' I .!1 J 'K ? n J ?~ M1 .T -M Approved For Release 2001/11/19 CIA-RDP79-00798A00020002000p-ig3O' . 1 I? 1 1 1 1 1? 1 t I I t ') { 1 1 1 1 1 1 1 1, I t' 1 1 1 1, { I i . [ : 1f1 ^J .,J rv ,T..~ rr < .?~ ../ '1 r f.) h i S! ??+ '?\ c, < .J 'A u , N 41 1 ?:J rJ .? 'V .?l ao 'v w. r? .t zJ -+ :J a '? ? ^ ? u, rt < ,) ..\ ?) r a ~..., n :~ r . ? .~ Ul u. , .f,? [A N F .J v1 ~. r M J .) Pl :V ?1 7 y ti ~. ?, ,r, ??? Q? N -' `J ! V\ ~! .Q ~. ?1 ? ?"'?.fV +. M .J N 4' M ??\ ??? .J fl J iJ , 1,1 y IV f.) ?n 1V N .'1.?? ?J ;?\ 1+1 .4 ~ 1 , N 'a 1 1 1 I{ ( 1 1 1 1 1 1 1 1. 1 1 1 1 f L. 1 1 1 ( 1~ 1 1 1 t[~ 11 1 .. ~... rl .?\ ~r, 7- r?..?~ ?.: J..v. .+ ?r ... ,. ;, ~?\ .A rJ t ~. v ~. ...7 .,) .t ..?. 4Y } 7) D -+ J J. _ .? ?'J w\ R ,? ... M1 I;. w +\ ?- ,. ^1 J -J ?G J h ~?_ "V " ..:I '. -? .V V I sv Q' ) < r, . J rJ J, .f?1 C? < J'. -? h -~ < s1 w ?') ?J . 1 .4 N N h ??? < < rJ N M .-1 .f1 ??I ?.f\ ??+ < r N H N ?V V `+,^! "'?. ???;. , ^\ < . r- , YI r..-, 6- r, 4 ?: ?7 -'+ .a ?Y t ?" I.. ?? . t.' .- ;+ ~ti ') a? 6- ?1 q ~?? 'I): C r .^ sJ :? :7 ~? ?:. y T) rl ?- ~) J ?? J 1'\ J ?? ?:\ ~T D ? ry T :V d ?- 'J\ J? ;. .} .-? n. J M ?41 4, h .: J -.. < .r 9 N h e1 .,~ .. ,., < S .'?' .~ rJ ..\ .? t ?'. t @? 7 n t- V 1.1 N. j Z> j ? ? ? ? . . ? ? ? ? ? ? ? ' ? J 1 S 1 I _ 1 1 . 1. y' . '' 1 t ?.) 1 JJ N n 1 N V~ ?t ?'5 1-? , 1 1 1 1 1 I. 1 1 1 1 1 ~7 J I , .t t:1 N I i 1: .r .?. . : V I h! V ?? .n ?S?I .f) } I 11 .r ^ V -J f1 J .-\ . u . -1 : V ? ' J ?1 .Il 4? ?\ l s V .t r U h .J N ?? -.? .\ ? V J% 4! Q. r- .?1 r1 :) J ?V ? I ? ? ? ? ? ? ? r?Ir a '1?t, iV 1 1 of ??, N ? ??1 r V' .- _ r1 J< . ?' ;. rl ?Y ? N .J + 11 I I 1 1 1 1 ;V J M. wS .J 14' V ??. ? V ^1 IJ 1 1 1 1 1 1 1 1 Ir~~ ?Y y J [ '? t t) .'V J -'\ 1 ? 1 1 I s r? r1 ' 4 ???I , v ? ? ^? " x1 V '. J N J ) N J J t I M1 M ?,. r' `1 .? 'J 1J P1 'J ', J . ? J h ^'1 : ,1J w ~r 6- ') J' _I r ?+1 ..I .-? ??I .~: ? V ?!\ ,'1. J. i1'J ~? Y1'7 .V ?J "3 -) 1 I -4 r ) )S CL' N'J rr -, J ? I C., 4% J, IIJ i ? wl .- T. ??1 1 1: I ? . ? ? . ? ? ?? ? ? ?'. .7 ?\h?J?. "I r. .i\ J?'\ .-?.l -f??.4 N??1 N , rJ 1' 1 1 1 I I 1 fI ..1 ?V J? J ?-? ?'J r: `\ 4 ??J ?, J ?- r J h-., 1)~ .~ .) 11 ..) ?r J\ 1 ?J to .?\ h 'lJ ^'\ N ?lJ M1 .^ 'y 4 ?V M1 '1) .T rJ {.~ 1 'n n .y .\ .J. I'1 M < 1.1 M1 .?1 iI 1V 'r .11 IV < N .r J J .??? Jr J\. } y) ? I ? . 1 I r- JJ 1.? r^ .3' v J l? lV .J 1 ?1 4 r1 J .1 ,V ??? .V '.. IV .V ? ?V .?1 ..? ?V 'r) .w ... r V I?. -? .r N 1 ?? . .J r 1 I , I Approved For Release 2001/11/19: CIA-RDP79-00798A000200020005-9 `1 I- 1.. .1 A I. 1-'?? '\ '1 1- -- t I: . ) 1- ?.) .1 r 1 ~I ?1 1 .J , ?~ J. -. 1.. 1? -- .. ?I X . ? .S .J . J . . r . , ' 1 .1 r _J _r .J' J V A. ?1. .'I . .l. J?' w ? -?. ? K K {  Approved For Release 2001/11/19 : CIA_RDP79_00798AO00200020005-9 I .... I ?; I" 1 1.1 of I, 1 4 -1 17? 4 + ;V It it I. f1 I ?; ..R S t', 0 ff ri' !t S' I ? ? ! ? ? y ? ? ?? (~ I . ?O C.1 ; ??t t'. U 1r' I N 0' fn '4 I 0, tut , w , Y . C,)c) ciC'r C O It ` 1 ?' u 1 . I T'. ,l t). Ltt'.l u r u IL1 N ! N a' Clb'J 470 00'^rJOi1tO CJn n'rn C' - n 0 00r)171 0f)0 0mC'nn ?, C)r, C.Or_'ry O0 e- r,,n p,") ?, .?' '1.'I 4 ! OC:OVtr' . ? , . .nO . .L. . . . . 7U , act ?:1000)G (,,, Jl J C)n C?0:)OCJ 37U OG ID OU V tl C` .? ! ? .-?.: ! W 0 rtC)0ell !hh00.?t)0P-0.0 "^or)C"ooo"nr-e.) C) 0 Cr?r-r7r3 nlr,ryC)N.pCMCr'J.trl:~ ?-' I %A L0 I I O?-tOOUIOONO.IO 'r c' co CJ L'?rJ OCC: O.-1 C1 ?'+C. G-?G 1?, 00%r .:l r)rf.C?,I V?GG t7GG tl u a:, 1, ? I 1 I.? r .?? W 4 N. .?? .r' ?+ . 1 . 1 ! 1 V U. -4 z t-of I 4J ~) I { ( ! i r CCX r- r-: I 1 I CILt01' O.' ( GO0 C)ti0 0 m0 'CM^r1h00 m0 mm0 C)OCmrCrlnCC?rl ltipOmhrJr)r.nnti 0 fO '+) G .LL ' w Ga:K 0 r1 GSOO V 5_I I I ? ? .. SU'' C?G P? Q,. CIO!) CPO7r?tOL IC'O!l t 1: O! 7r^ 5 4("0 ~ W 7` t 4J t>L. I d M .?? , N N .. m rl .t r f+ .-..+ N .-? L .o. p. , O , ( i 1 ,I { 1 i ?^? lJ Nit Cu ?N M 0'! t` d co ?... O' ..A .~ A If w 01 . 1n tl i rn ti ? ?L J /^ ?-1 v) '.? v J .3 ! N' N .T c. J r C' ?-I Y a 0. %n.10 .a d m :C ?l, .. , 4 ! O .? 1 11 1 1 1 ..1 1 j .-? 1 .-?' N .+ .'. .+ 1 1 .C4O'I I.?.C?.t . ? 1 ! ; I I .J-I C.? N U i I 1 I 0.:.C ?2 I1 I h 6I ( N N1 ?b to 'D JM'C''J. 01 -4 .4..1 J)J? J M U'O d.+ Al F I , V A'6' N -t ,'t .J; N. M.:' 0.O C d . C1'I 0 6, o NJl l> ?r. '.-t ..r rJ ?.. r J' N N I N j 1 N 'r -A.-. N ..r 1- O J ! St r?, N 4? t?r r { , I , 4 IU >? ~ ! ? r T I O I I { I ' ? , 1 ~, 1 ? K ! +T ?J) 0 4 .-, M s O ?? ..r ? ... M h 0 O ? N n' of r? N # ? J K !Ul '7'# .4 us 5 ??O { N: O ,r ? ..r r.J :J Ina CO. ?.G fI U dl' .J N, ?V1 I N, M J F; N i) . I O] ?- : 1 ? 1 ? 1 ! n: .4 t) i 1 II I 1 1; ! I I 4. . I 1 1 tf # .-? ?+ M4# Ut , ('I C' J m t''? C It b I t 121 m' t>6 61% C' nl U. I*, # Lj u M tl 1 Ua I ' I ~- N +?? ..? i,? ? 4. 1~ ~". ? ? ti. J 1 t'. .j r.a ... d , ? ., . ? -, J .? ?L v' .- t? Y . '~ L:. )..1 .J - L) N V,  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 pproved For Release 2001/11/19 : CIA-RDP79-00798A000200020005; 9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 - Competitor actual operational statistics and onboard traffic for the period January, 1972-December, 1973. These data be- come available from twelve to twenty-three months after the fact, and are used to develop passenger departure time pre- ferences. - Competitor and industry traffic statistics from January, 1968 to December, 1974. These data are the true and online 0&D traffic in each market. Market share for each competitor is available for online traffic. True origin and destination traffic is available for all domestic markets, and U.S. flag- carriers' traffic to international destinations. These data are added to the data base quarterly, but are six to nine months after the fact. All data are maintained at the source level (flight or city pair). Additionally, a consolidated record containing frequently assessed statistics is maintained at the directional station pair level. Data base management software establishes linkages among related data at each level and across multiple levels. A general purpose report generator provides the capability for generation: - In variable formats - With multiple data sets - Up to five levels of summarization Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  ' Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Structured data files containing unique traffic statistics, in- cluding 0&D passengers, onboard passengers, and enplanements are maintained as a subset to the data base. Interactive software com- ponents of the data base management system permits a library of statistical subroutines, including Regression analysis General purpose simulation system Time series analysis Trend analysis Variance analysis These operate on this minidata base. FORECASTING SYSTEMS Two fundamental techniques are used to forecast traffic. One method uses: - Stepwise regression with - The Durbin Watson statistics to eliminate auto-correllated variables to develop the forecast algorithm The other method uses: - Time series analysis with - Fourier analysis to overlay seasonality components Economic indices used in the regression equation to forecast industry traffic include civilian employment, disposable personal income, government expenditure, corporate profits, and average air fare. Forecasted industry data from each method are loaded into files, and an analysis of variance performed. Resolution of variances intro- duces the human factor into the forecast algorithm, which, functioning within arhintb My_e RM1600M 1fRT. G tR f~ d $ 2 '2( 1p3  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 files), can manually override the statistical projection with a judg- mental forecast. Once the industry traffic has been forecast, re- gression analysis allocates the industry among all competitors by seat share, trip share, and market share. After the regression has been completed, a test for reasonableness is run to measure forecasted growth rates (Exhibit VII). SIMULATION SYSTEMS Although the simulation model was designed for use at the market and market group levels, it may also be used at the system level. Its primary function is to permit the analyst: - To vary competitive assumptions and reforecast Eastern's position in the market - To vary industry forecasts and recalculate Eastern's O&D traffic - To vary both competitive assumptions and industry fore- casts, and determine the impact on Eastern's O&D traffic The analyst may elect to use either of two subsystems comprising the model. The first subsystem permits altering the independent variables in the algorithm by ?1, forecast error value. The second subsystem requires that the analyst specify a numeric range for the variables. The model then uses a random number generator to vary the dependent variable over the specified range. Another simulation tool is a general purpose simulator. The system was designed by IBM and is in general use by many airlines. This model is used primarily to compute a "risk factor" for each to  1 ? C Approved For Release 2001/11/19 CIA-RDP79-00798A000200020005; 9 238 .. ~~ h to ./ ?-I .' . ?\ 4 ??? ? ?' 4 v 4 + m T f.f .ti N ? ? ? r ? ? ? r ? - ? ? ? ? ? ? f+'?J V? ? / 1 4 _ 1 , t w ? 1 - 4 ' 1 f 1 1 C3J ?C?4 C) '?J J . w N Y 4' ?t ? N N h '1 '-f ( N N M M W ?) 1 tr ? .4 N 4 ry n . ? "4 ;r .? r 1 ep ?y f- ' .1 :) 41 M J ?t ?~ '1 4 VI V1 .l Yt ) ?' ~~ ? r I" ? b C .- 1:r ?> J? '2 .J r ') La ?J 7 a ... W .l J t?1 '?1 ? 5 -" w 4 C) .? '1 Yr w :C !7C l'` w 4 . .1 \1v.J? 4 r . v ... ?.) i ?h ?.1 :f \ J ? . e. IY A .n y I:- r .1? i5tl 4.. .) ?., a ..e ,y .1 43 A .. ? N )- J) t' '7 " ?l u) 1 t,Apitroveb .J? X Iv s .n -?t: f?? ?f '.f ?? ?i I.1 N Y' .?/ .tf ?.? N ry Ir n vl .f :1 .4 u. W = r. % .4 + t ' ? ?. ? r ? 1 ' ? ? 19 ? .!1 ? ??) ? vt ? ?r? ? .1 ? .Ae ? .7 ? 1.7 ? 'e1 ? a1 V.4 .?.: '. 4 .??~ 3?t ..: .y.l ' 4 ; 4 44 .1 '.' .1 .7 ' L' .1 V ." 44 /1 745.7 ??1 .1 ..r V1 A ?/) ?r? A ....n ?a? N L- .1. ?U s' e.:.' r? .n tl .re ?? ?/1 r.) ?q ' V .) 4) .' .r q .?? ?). i. .t V. ? \L IL B. .\. + 1:. ? 't ILT .r 4 1'1' .r ?? ?! )? ??? M Ir .4 '. ? t ?.4. r'1 ?C ? T ?r ?4' ?"'1 ?R ? ) ??' ?T nr -? j J J 'v S ^ ?T 'J ??~ ~?' : J 3 7 f -1 r^ 1 ' l '1 4%a Ala r a r-? f11 t-tl t-t in a of 0? I'D It C)4 'r I .r 1' r7 -t -? ?7? ?11 ;) -/?rl .V ?n r- Z .' ^t J'S r' p .:? ?.1 U ~l J1 n .r ''~ 'l Itl ,. C' J1 a .1 - N f. .S r 1' 7' J .r ? U' 4 'I T .? .. d' 1.7 -a . S ;? .4 C? .. ?'t 5- d T M N ?} ..? h '?1 4- .y 1?f w ..t ??? tr 41 ..e .0 N 'C tl? C J .) l: v7 r- O If C) :J .t r't '1 .?1 ?ry N.. .'t 4' ?' 't ? ? ? a ? ? . ? 4 ?' a ' ? of ? i t ^ f ? ? t ? tt + It + a t1 .A 1.1 ?.l .1 Irl A ?A N .1 \I) .A -.A S i?' G7i r t SJC Ma. ^L V .Y i .1R 4)# .7 3' S.4 at A. I- ?~ ?7.4 r-?7 C1 -1 R 1 1-. 1+ r. -. , -r i 1 Z H O 1 ? {I j C)' I N1 O? r1 M1 In 1 U7 N V) N co w c) d h J IA -?? N N N .CI C !? '.1 L' P CJ ~?- C Y. N- h J - N J ru 0 G O C7 0 0 V% M1 -+ -?r J -+ G u1 N 1- 1 fY a rl a r1 U. th C' I Y. sl an b VP m K. n. I N N 611 C. P.- .) ^ J IA n '- f r) a1 N N N .r N N J I- 1 . :u 1 C) 1 !- I I 1:1 O C. N P_+ O rA U., ~? M C) M -+ Y. 4 CI U: \ 1 w !I 1 h 1 r w -+ u 1 N ? ~. 1 \ 1 U rn O? rl u; VIa ll. .0 N LL W r J Vt N :l h r7 'a '0 .t ? N O d' N O N h .{ N ? h .} P W O 1 C.N?+ 1 >?rr -1 .1 ti O C. a 1 .~ A -1Jr1JJ F J J. J J J L' N U U C. 11 ?. 1 1 1 1 1 t N n O? 1 "t 7 'C .C C NI U. W U. Approved For FReI c X2001/11/19;: CIA-RbP79-00798A0b02Q00i00g5-9 Y V'1 ll. . ~ . 1 i  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9. 1:)+111111'1' X tlAi n..t I;t''I/.ICI 11 t~~nl,r LT SC14C~+1L~ Ntn:~lM1N( X FALL. 75 - VEr? S /18 - M:0N ****/' D1.3 ***v: ' ft:;T rt. T F.?I1 I C. 111F C' CI1r11! MAI'ICI:T DIPCTN SVA Tl7IP1t STA NI-R STS Fkt 0. 04T1 pATL ARVL A7(.()411 4TI.I)i R A T 1 8014 .IAX (s;'' 1)?.(t (1/. 111 IUt, M1611 S /' 0'10 1 751;'11 f1+1t)+) A I 1 I 1111 I .'111 IIAI% 0.' /'~ i t/, 01X111 ', S /',0')111 1 /'~ I 'tiI +11111111 A I I I t',r, I'.()1 IiAIt U'. 11 r' I 1/1 t?I 1111 t /". 1 .'101 UP C) Ail. 16', U 11I.'> UAIt U! /r '/ 0)I') NIVi 1fSS 1!;0'11)33 751:.'01 0 ()()f) A T L 2010 2113 DAB 0131 105 MTt,TFSS 750903 751201 0000 ATL 2235 JAX 0024 C:,6 0578 089 NTWTFSS 750903 751201 0000 DA CA TL 11,8 0725 0837 tTL 0632 089 MI b1TFSS 750803 751201 0000 11 AI: 100At 1!23 AI 1. 0?8/t I?4 "1 WTI SS 750')():1 751031 0000 DA t; 13Ct'? 1A~D0~2~t1~608r~hlems.  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 ACI:N0T,LFDGFMLNTS The design and development of UTPS is the product of individuals too numerous to list. Among the institutions they represent are: Barton-Aschman Associates; Cambridge Systematics; Coronet Corporation; Consad Research Corporation; Creighton-Famburg, Incorporated: Deleuw, Cattier and Company; DTM Incorporated; First Data Corporation; Mass- achusetts Institute of Technology; Metropolitan Uashington Council of Governments; National Bureau of Standards; the MITF;F. Corporation: Peat, Marwick, Mitchell and Company: Planninc Research Corporation: II. Pratt Associates: Wilbur Smith and Associates: TRW Systems Group; Alan M. Voorhees and Associates: and the Urban Mass Transpor- tation Administration, which Provided financial support for the opera- tion of the above institutions as iYell as the preparation of this paper and disclaims any Federal policy which might be read into it. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 AN EVALUATION OF THE AIR nUALITY TPTPACTS OF TRANSPORTATION CONTROL POLICIES IN U.S. U?IRAN AREAS Gregory K. Ingram 1. INTRODUCTION Over the past two decades in the United States concern about the quality of the environment increased dramatically. Concurrently, the air quality in many urban areas deteriorated, and scientists demon- strated direct linkages between pollutants such as photochemical oxidants and the exhaust emissions of motor vehicles. These scientific findings and the worsening urban air quality led to the 1970 amendments to the Clean Air Act which set ambient air quality standards and em- powered the U.S. federal government to require new motor vehicles to reduce their emissions of certain pollutants by approximately ninety percent. Although the phased reduction of motor vehicle emission rates was the major policy proposed to meet the ambient air quality standards, the 1970 legislation also allowed urban areas to limit the extent of pollutant generating activit~y if the reduction in emission rates proved insufficient. In many urban areas of the U.S., it appears that transport activity will have to be curtailed sonewhat if the ambient standards are to be achieved on schedule. A variety of tr.ansnortation control policies including improvements in public transit, better traffic controls, and restrictions on automobile use have been proposed to curtail transport activity in U.S. urban areas. This paper analyzes a number of these transportation control policies in two U. S. cities using a computer-based simulation model. The objective of the analysis is to clarify the potential role of transportation control policies in improving ai.r quality and to rank. *Warvard University & National Bureau of Economic Research Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 alternative policies in terms of their cost and effectiveness. The computer model that is used also could be applied to other urban transportation policy problems, and the structiire of the model. Is briefly summarized before the transnortation control policies are presented. 2. TIT TASSTt! MODEL The analysis of transportation control policies Is based on the Transportation and Air Shed Simulation Model (TASSIM) developed with funds from the U.G. National Science Foundation and the U.!. Depnrtment of Transportation.1 This model forecasts levels of travel. activity, pollutant emissions, and pollutant concentrations for distinct zones within an urbanized region. The overall model, as illustrated in figure 1, consists of three major components: a transportation submodel. an emission submodel, and an air diffusion submodel.. Each of these sub- models incorporates existing modelin' techniques. The transportation submodel is based upon the urban transportation planning, model used extensively in transnortation studies. The emissions submodel emnlovs emission factors published by the U.S. Environmental Protection Agency to calculate mobile emissions. The diffusion submodel was developed by meteorologists. The transnortation component of the TASSTM model is an adaptation of the standard urban transportation planning (UTP) approach. 2 pproach. The transportation submodel is composed of the usual steps of trip genera- tion, trip distribution, modal split, and network assignment. Tn the trip generation step, the total number of daily person trips which originate in, or are destined to, each zone is forecast as a function of the household, land use, and employment characteristics of the zone. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-2, 290 . FIGURE J. MAJOR COMPONEU'TS OF THE TJiANSPORT AND AIR STIED S114UL LTIOrl MODEL TRANSPORTATION SUBMOD:L Forecast distributions of transportation activity (trips and speeds) in each zone by mode and purpose Lof trip. EMISSION SUBMODEL Derive area source emissions from automobile travel using speed/emission factors. Input stationary area source emissions by zone and large point source emissions by location. DIMSION SUBMODEL Generate pollution concentrations in each zone based on emissions and meteorological factors. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 These trip forecasts can be envisioned as the row and column totals from a matrix that displays trips by origin-destination pair. In the trip distribution step, a matrix of trips by origin and distribu- tion is created that is consistent with the trip generation totals. The trip matrix is produced by employing a distribution rule such as a gravity model or an intervening opportunities model. In the mode split step the trip matrix is subdivided into two or more trip matrices indexed by mode (automobile, transit, etc.). Mode split predictions are typically based on the socioeconomic characteristics of the popula- tion and the relative cost and performance characteristics of the modes. Finally, in the network assignment step, the trips from each origin zone to each destination zone are loaded on a spatially detailed repre- sentation of the transportation system. The network assignment typically assigns trips to the shortest path in the network. Three major changes distinguish TASSTN's transportation submodel from the standard UTP anproach. First, the transport submodel has been calibrated at a level of detail which is more aggregate than is usual for such models. The Roston version of TASSI;', for example, considers 122 zones and 582 interzonal transport links for both auto and transit. The TA.SSUN links comprise a spider network whose links represent either all of the streets and highways or all of the transit routes that connect zone nodes. Thus, the model produces link loadings on aggre- gates of highways and arterials rather than flows on individual trans- portation facilities. The more aggregate nature of the TASSIM model produces enormous computational savings. Moreover, the spatial, de- tail retained is sufficient to represent the distribution of transport activity among zones and the changes in that distribution caused by transporApprove or Hell ease '>t/~f~/19 : CIA-RDP79-00798A000200020005-9 Approve ~'  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The second change in the transportation submodel involves the prediction of transit ridership which is shared by the modal split and network assignment steps of the model. In the standard UTP model, auto trips and transit trips are assigned separately to their respec- tive networks. TASSIM employs a more flexible representation of net- work assignment and mode choice. The two c.ateeori.es of trips repre- sented are transit trips that are made completely on the transit mode, and other trips that begin as auto trips. These latter trips can either switch to the transit mode at some point or'else continue to to their destination on the auto mode. The use of a composite network (containing. highway links, transit links, and interinodal links) for trip assignment enables the TASSTMM model. to simulate the effect of parking charges and other vehicle restraint schemes on auto trips in. a more realistic manner than wonnl.d be possible with the standard UT?' model. The auto networks used in standard models are often so large (containing 10,000 to 30,000 links) that it would be prohibitively expensive to expand them to composite networks, whereas the composite network for the TASSIM model is still of a reasonable size. Finally, the third change incorporated in the transport submodel is its use of a diversional routing or multipath assignment procedure in the network assignment step instead of the all-or-nothing or capa- city-constrained assignment procedures. The probabilistic multipath assignment procedure used in the network assignment step selects a set of feasible paths from each origin node to each destination node and distributes the trips to these paths by means of a weighting scheme. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The spatial traffic patterns forecast by the transport submodel permit the calculation of auto vehicle miles travelled per zone as well as auto vehicle cold starts per zone.3 Average vehicle emission rates for a given fleet are multiplied by the estimates of vehicle miles travelled and cold starts to yield emissions by zone from mobile sources. Emissions from small stationary sources, such as home heating units, are added to mobile emissions to give average area-wide emissions for each zone. An area source diffusion model then predicts the zonal concentrations of each pollutant which result from the emission patterns and the meterological characteristics of the urban area.4 Emissions from large stationary sources, such as electric generating plants, are treated as individual point sources, and a second diffusion model is used to forecast the pollutant concentrations in each zone that stem from these large individual emitters.5 These diffusion models both assume that the relation between emissions and concentrations is linear and additive, and that the pollutants represented are nonreactive. That is, the models assume that emissions can be related to concentrations by an equation of the form: C(I) - A(I,J) * E(J), where C(I) is the n-dimensional row vector of the concentrations in zone I(1 < I < n), E(.T) is the n-dimensional column vector of emissions from zone J(1 < J < n) and A(I,J) is the n x n transformation matrix. Two automotive pollutants, HC (hydrocarbons) and NOX (oxides of nitrogen) combine in the presence of sunlight to form photochemical oxidants, which are important secondary pollutants in many metropolitan areas. The reaction processes that produce photochemical oxidants are not well known, and at this time there are no simple diffusion models Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 that can predict spatial concentrations of oxidants with an acceptable degree of accuracy. Therefore, photo-chemical oxidant concentrations are not forecast in this analysis, and results are obtained only for the oxidant precursors, 11C and t10X. The diffusion models used in this analysis are elementary, even primative by some standards; but, unlike proportional rollback models, they represent the effects on air quality of redistributing emissions over space. If transport controls are applied to selected portions of an urban area such as the central business district, existing patterns of transportation activity and mobile emissions will be altered. Thus the evaluation of transpor- tation controls requires a diffusion model. A major reason for using a model to analyze air quality is the consistent framework it provides for systematically evaluating poli- cies that reduce or redistribute emissions in urban areas. 1?hen the TASSTM model is calibrated to a particular city, a wide range of transport control strategies can be considered within the same land use and transportation environment. The choice of the study site is of crucial importance: analyzing, an atypical city may result in unwarranted conclusions about policy impacts. rather than searching for the "average" urban area, this study has selected two cities, Boston and Los Angeles, which represent quite different types of urban development in the United States. Table 1 presents several socioeconomic and transport statistics that summarize the characteristics of these two cities. Figures 2 and 3 display the analysis zones used in each city. Los Angeles has three times as many people, but four times as much area and four times as many automobiles as Boston. ?Moreover, in a typical weekday, residents Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005 Table 1 SUMMARY STATISTICS FOR BOSTON AND LOS ANGELES FOR 1970 Los Angeles Population 3,023,000 9,008,400 Automobiles Owned 1,096,000 3,930,200 Area (sq. mile) 1,400 5,285 Daily Person Round Trips 3,125,038 12,243,975 Trips to Central Business District 384,774 416,281 Transit Originating Round Trips 348,252 .190,'052 Transit Originating Share of Trips 11.1% 1.6% Daily Vehicle Miles Travelled 21,960,336 165,936,096 Average Auto Round Trip Length (Miles) Average Transit Round Trip Length (Miles) Average Auto Speed (mph) Hours of Travel [h.verage Daily Hours of Travel per-Person 9.91 8.54 2,040,852 19.13 14.17 6,450,413 Emissions by Pollutant in Grams/Second 19,090 2,839 1,057 64,215 17,601 9,541 Source of transportation and emission statistics: TASSIM simulations and I..AR'TS Base Year Report. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 296 Figure 2 BOSTON ZONAL SYSTEM! "r PO-LE I_r p121 ~~- -4 \>--- 10. Cell tr.11i::c A)Sprb Wff61 Release 2001111/19: CIA-RDP7 167 0200020005-9"">">  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 in future years will also depend upon the nature of metropolitan nrowth which actually occurs. These policy simulations both in Los Angeles and in Boston indicate that the predicted impact on air quality of reducing automotive emis- sions Is dramatic. Aggregate mobile emission rates and pollutant con- centrations of CO, TIC, and NOX in the air quality control regions fall substantially. For the 1976 fleet aggregate mobile emissions fall by fifty-two percent for CO, by sixty--two percent for IT, and by twenty- two percent for ;[OX; for the 1980 fleet aggregate mobile omissions are down eighty-one percent for CO, eighty-five percent for TIC, and sixty percent for ITT?X. Carbon monoxide is emitted primarily by motor vehicles, so the forecast reduction in zonal CO concentrations closely parallels the forecast reduction in automotive emissions both in Los k.ns*.eles and in .)oston. For CO the decline in concentrations is not exactly propor- tionate to the decline in aggregate emissions because the standards are projected to have a greater effect on running than on cold start emis- sions. Since emissions of hydrocarbons and oxides of nitrogen are produced by both stationary and mobile sources, the forecast reduction in concentrations for these pollutants shows considerably more varia- tion. Because of differences in the composition of stationary source emissions in the two cities, reducing mobile emissions of hydrocarbons ,tenerally produced a greater reduction in zonal concentrations of hy- drocarbons in Boston than in Los Angeles. A comparison of NOX concen- trations in the two cities revealed that the opposite is true for NOX emission reductions. Nevertheless, in Los Angeles, the zones with the Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 highest concentrations of stationary source hydrocarbons had their hydrocarbon concentrations reduced thirty-five percent by the 1980 fleet emission rates. In the Boston zones with high concentrations of NOX from stationary sources, a twenty-five percent reduction in 14Oy concentrations was achieved by the 1980 fleet emission rates. h. Discouraainh Automobile Trips to the Central. Area Three types of local vehicle restraint schemes were simulated: parking charges, local licenses, and automobile prohibition. The restraint areas were defined as zone 1 in Los Angeles and zones 1, 2 3, and 6 in Boston. These zones constitute a generous definition of the central. business districts (CBDs) in the two cities. The parking charge simulation raised the average cost of parking by fifty percent. The area license scheme placed a 254 toll. on all trips which originate outside and enter the restraint area. Trips which originate within the area are exempt from the local license toll. Outright prohibition is similar to licensing except entry cannot he purchased at any price. Although traffic flow changes do not endogenously change speeds on the transport network in TAgSIM, speed changes can be introduced exogenously if there is reason to believe such changes will actually occur. For these simulations it was assumed that the reduced traffic increased auto speeds by ten percent in the restraint area for all policies except the parking charge, which does not reduce through trips. In addition, a second prohibition simulation slowed auto speeds by 10 percent in zones adjacent to the restraint area to repre- sent the congestion caused by traffic diverted from the restraint area. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The results of the simulations were generally similar for the two cities. On an aggregate level, all policies increased transit use and reduced auto vehicle miles traveled. All. simulations except the Los Angeles prohibition-with-congestion run reduced aggregate mobile emissions. This exception occurred because the congested adjacent area modeled in Los Angeles was large, and lower speeds in that area caused an increase in CO large enough to offset the savines from the reduction in vehicle miles traveled. The aggregate improvements from the restraint policies are not large, however; the really substantial concentration decreases occur only in the zones directly affected by the policies. The licensing and prohibition schemes induce auto tripmab.ers destined for the CBT) to switch to transit outside the restraint area and to complete their trips on the public mode. In addition, they divert through trips into adjacent zones to transit, but they do not divert through trips from the restraint area. `3 As a result, while all three traffic re- straint policies significantly improve air quality in the restraint area, licensing, and prohibition produce greater improvements than parking charges. It should he noted, however, that the auto trips redirected to transit, the diverted through trips, and, if it should arise, the in- creased congestion in neighboring zones caused by traffic-restraint policies, all can have detrimental effects on the air quality in these adjoining zones. Through these effects were often not large, they are a reminder that central area restraints can have certain undesirable air quality impacts. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 c. Ilakinj Transit Alternatives btore. Attractive A variety of transit improvements are often proposed as techniques, for improving air quality in central sections of metropolitan areas. It is argued that making the transit system more attractive will divert drivers from their vehicles, reduce vehicle miles travelled (WIT), de- crease auto emissions, and improve air quality. The TASSIM model has simulated in Boston and in Los Angeles the eFfects on air quality of transit fare reductions and performance increases. Fare reductions of ten percent in Boston-and twenty percent in Los Angeles were tested. In addition, twenty-percent reductions in total time required for transit trips were examined. A central area bus lane scheme was tested in Los Angeles. Finally, the impact of ex- tending the rapid rail system in Boston was considered. The results conformed to results of other studies of transit rider- ship. Responses to fare reductions were less than responses to propor- tionate travel time reductions. Price elasticities for transit are low--about -.4 for Boston and -.2 for Los Angeles. In other words, a twenty-percent fare reduction increases transit ridership by about four percent in Los Angeles and eight percent in Boston. Transit level time elasticities are typically larger--about -1.0.9 Because the percent of trips on transit is not large, the fare re- duction and performance improvement produced barely perceptible reduc- tions In the total number of auto trips made in the two analysis areas. The rapid rail extension in Boston did increase the share of transit trips, but was unsuccessful at improving regional air quality. The Los Angeles bus lanes improved air quality in the CBI), but resulted in imperceptible changes for the rest of the region. Since the transit systems in both cities provide more complete service in the central Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 areas, fare reductions and improved transit travel. times die generate some noticeable improvements in central area air quality. For example, in some zones concentrations of. CO were reduced as much as thirty per- cent by the overall transit travel. time reductions. Although there is no persuasive evidence that aggregate emissions are reduced by transit enhancement policies, substantial air quality improvements can be generated in specified areas. Reductions in . transit travel times have somewhat greater effects than fare decreases or extensions of transit service in producing these local improvements. d. Tiegulating Traffic Flow The emission rate of automobiles net vehicle mile is a function of vehicle speed: emissions of CO and 11C decrease sharply with speed, whereas emissions of VOX increase slightly as vehicle speed increases. Thus, policies that increase vehicle speeds have often been proposed to improve air quality. Although increasing vehicle speeds could be envisioned as a region-wide policy, it is most frequently advocated for centrall.v located, highly congested zones where average speeds are quite low, ranging from ten to fifteen miles an hour. TncreasinF, speeds from such low levels can significantly reduce emissions of f'O and 11C per vehicle mile. Conversely, policies that may reduce auto speeds could he expected to degrade air quality. Four simulations that investigated alterations in vehicle speeds were carried out for both Boston and Los Angeles. The first policy simulation increased automobile networl: speeds by ten percent in a small. central area, and the second policy simulation applied a speed Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 decrease in the same central. area. The third and fourth policy siruula- ti ons respectively increased and decreased automobile network speeds in the entire re-ion. The aggregate statistics from the region-wide speed chances are consistent with expectations. Faster auto speeds reduce total emissions of CO and ITC and increase slightly those of NOX.1< Slower regional auto speeds have the opposite effect. however, changes in the spatial pattern of pollutant concentrations in Boston differ from those in Los Angeles. "hen auto speeds fall in Poston, the transit system attracts enough triprinkers to reduce concentrations of all pollutants in the central zones. Conversely, faster auto specOs lure away enough transit riders to increase concentrations of all pollutants in the central. Zones. in Los Angeles, the transit svatem carries proportionately fever riders. Therefore, very little slii.ftinr occurs, and changes in central area concentrations are similar to regional changes. The small area speed changes reveal another difference between Boston and Los Angeles. In both cities, local auto speed improvements discourage transfers from automobiles to transit. Auto speed reduc- tions have the reverse effect. However, central area speeds are sub- stantially slower in Boston than In Los Angeles. liven the relationship between speeds and emissions, a ten percent speed change in Boston produces a smaller percentage change in individual. vehicular emissions than a ten percent speed change in Los Angeles. Therefore, changes in through trips and switching behavior offset changes in individual ve- hicular emissions in Boston but not in Los Angeles. The small area speed change simulations suggest that in Boston speed improvement stra- tegies that are not implemented with vehicle restraint systems that re- strict auto access to th area will have a hi ph robability of failure. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 309 Tn Los Angeles, they will generate slight changes in the expected direc- tion, i.e. speed increases will improve air quality. However, it is clear that in Los Angeles, as well as in Boston, adding vehicle re- straints when auto speeds are increased would generate greater gains. e. Increasing Au-to- r,obile Occupancy It is well known that the average auto vehicle occupancy rate is quite low relative to vehicle capacity. This knowledge generates enthusiasm for policies to promote more car pooling for. work. trips. However, because data on accepted and rejected car pooling opportunities are virtually nonexistent, few effective policies have been devised to promote higher vehicle occupancies. Although the TASSIM model yields few insights about the determinants of car pool.ing, it can be used to examine the air quality impacts of achieving specified higher levels of auto occupancy. !,?hen this policy is simulated by the model in the two cities, substantial and proportionate reductions in auto emissions and improvements in air duality are obtained. Of course, car pooling can have effects on transportation demand that ro beyond simply increasing the average number of persons per vehicle. If car pooling occurs mainly on work trips, some workers will leave their automobiles at home several days during the week. These automobiles will then be available to other household members who may use them for shopping, school, or personal business trips. This greater availability of automobiles caused by car pooling might increase the total number of trips made, thereby offsetting some of the pains from car pooling;. A partial test of this phenomenon, using the Boston version of TASSIM, indicated about a third of the expected air quality improvements are eliminated if car pooling increases auto Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 availability and more trips are made. The number of trips may remain the same, however, if the primary effect of car pools is to reduce the number of second and third cars owned. If the increases in auto- mobile occupancy are achieved primarily through car pooling for work tripe in central zones, and if the additional trips generated are primarily suburban shopping trips, then significant central area air quality improvements may be generated which are greater than the reduc- tions in aggregate emissions. These considerations suggest that in- creased car pooling will not reduce automobile emissions uniformly over an air quality control region. F. Contra l l in-Urban Devel onnent Patterns Some analysts, recognizing the interrelrntionship among land use patterns, travel activity, and stationary emission source locAtions,' have proposed that land use regulations and controls be used as policy variables to improve urban air quality. Implementing land use plans to improve air quality is difficult, however, because little systematic knowledge is available about the exact relations between land use and air quality. Therefore, there is little basis in terms of air quality effects for accepting or rejecting alternative land use plans. The TASSIM model was used to investigate one particular hypothesis about the impact of land use on air quality in Boston. This hypothesis states that higher density development of central portions of metropo- litan areas improves air quality by reducing the demand for transporta- tion and particularly automobile travel and, conversely, that existing patterns of low density, dispersed development degrade metropolitan air quality by encouraging the use of autos and requiring longer trips. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Two scenarios of altered land use patterns were simulated with the Boston model. The first increases centralization in the air auality control region by moving twenty percent of the residences and employment located in the outlying ring to the central core. The second scenario increased the extent of decentralization by moving twenty percent of the core's population and employment to the ring. Most of the transport statistics produced by these simulated land use changes conform to the expectations which suggested the policies. Centralization reduces the aggregate number of trips, trip lengths, and the aggregate levels of emissions of auto vehicles. Decentraliza- tion has the opposite effect on all of these variables. The simulations predict certain other changes which have opposite air quality implications, however. Centralization causes average auto speed to decrease. In addition, auto trips to and through the downtown area increase. The net impact of these forecast changes from centralization is to increase concentrations of auto pollutants in the central zones by as much as 10 percent, and to decrease concen- trations in the ring zones by as much as seven percent. Decentraliza- tion causes opposite, but more dramatic concentration changes, since the movement of jobs and people is absolutely greater. Reducing low density peripheral development and increasing central densities may not be an effective policy for solving urban air quality problems unless it is combined with other policies that fundamentally change patterns of transportation usage. If altering patterns of travel usage is difficult, then the process of dispersal and decentralization underway in most metropolitan areas may actually help to reduce the concentrations of primary pollutants in the centers of those areas. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Since decentralization increases total emissions of TIC and NUX, however, it might increase concentrations of secondary pollutants such as photochemical oxidants in some cities. r;. Summary of Polite Tff.ectiveness The preceding sections have provider.] a descriptive overview of the predicted effects that several control policies have on the trans- portation system and on air quality in two cities. This section summarizes the results of these policies with a region-wide and local '' effectiveness' measure to quantify the impact of the policies on air quality. The first measure of effectiveness, the regional effectiveness index described in the first section, measures region-wide violations of the ambient air quality standards in terms of person-times of ex- posure to pollutant concentrations that exceed the standards.11 The second measure of effectiveness focuses on the local or target area improvement in air quality; it is the percent change in the concentra- tion of carbon monoxide in the central. business districts of Los Angeles and Boston. Many of the transportation control policies that were simulated were applied only to the two cities' central areas, so this latter measure indicates how much locally applied policies can improve local air quality. The regional effectiveness index, on the other hand, better summarizes the impact of policies on the entire air quality region. The local regional effectiveness of the policies are compared in figure 4 for Boston and in figure 5 for Los Angeles. The origins of these figures represent the benchmark run. Not easily read from the Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 313 FIGURE 4 LOCAL AND REGIONAL EFF1 CTIVETNESS OF POLICIES FOR BOSTON ? '6 56 118 44 36 28 211 Transit Improvemcl t L 16 Transit Vxtension -Boo -6o0 -400 -200 Increase Auto Speeds 0 -1+ Increase Central 0 Auto Speeds UCentra.l.i ze -8 1980 Emissions 0 Q)1976 Emissions 0Prohibition & Congestion OProhibition QLocal License Raise Parking Charge r?e rni Decentralize O Decrease Central Auto Speeds C )Decrease Auto Speeds OBaisc Auto Occupancy IR diic=T ansi.t ]tr rc ~__~ 200 1oo 600 800 Regional Effectiveness (Reduction of Peron-Times of Exposure in Thousands) Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 FIGURE 5 314 LOCAL AIZD REGIONAL EITECTIVEN1:,~Sa OV POLICIES FOR LOS ANGELES 80.1- 1980 Emissionsi 55+ 154- 0 Increase Central -~ - _ - ` Auto Speeds lp0 yTransi Rma 'sociuot0ccupancy Reduce Transit Fares 5r.~ ve.L Times xeaucc Transittrra { -800 -400 h Jo 8ob 1200 1600 _5 : Reduce Central Auto Speeds Regional Effectiveness (Reduction of Person-Times of Exposure in Thousands) 0 Prohibition 50 1976 Emissions Prohibition & Congestion 0 h5 0 Local license 40 (Raise Auto Speeds 35 75 70 65 - ; 60 30.t- 25-F- 0 Reduce -zU 7 Appru" Fa A*ase 2001/11/19: CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 diagrams themselves is the observation that local rather than regionally directed policies have the greater relative impact., with the exception of the emission rate reductions. These diagrams highlight the differ- ences between the policies in Los Angeles and Boston. Although many of the policies differ in their relative effectiveness, the only policies that act in opposite directions in the two cities are the speed increase and the speed decrease policies, as described under heading d. above. The only other policy that degrades air quality is the centralization policy simulated for Boston. Extending the transit system produces a negligible local improvement, but some regional air quality degradation in Boston. All other policies to discourage auto use and to increase transit ridership have positive regional and local effectiveness. As expected, policies applied only to the central business districts have greater local than regional effectiveness. Finally, figures 4 and 5 illustrate how the effectiveness of' emission reduction compares with the transportation control policies. The 1976 fleet emission factors are more effective locally and region- wide than any of the transportation policies simulated with 1970 fleet emission factors except for the regional improvement from decentrali- zation simulated for Boston. The 1980 fleet emission factors produce substantial improvement in air quality relative to 1976. Because fleet emission factors will decline so markedly during the late seven- ties and early eighties, it is probable that vehicle control strategies will be required to meet air quality standards in most metropolitan areas for an interim period of only a few years. Of course, in the longer run, increases in automotive usage could mean that localized control ~ ~~o~~Cell @ 260M 1'15 Jkr- 79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 4. COST EFFECTIVENESS OF POLICIES IN BOSTON AND LOS ANGELES Transportation control policies that have similar impacts may have widely different costs. It is necessary to determine costs for each policy to make judgments about their relative efficiency. Many simplifying assumptions must be made to evaluate each policy, but even crude estimates of the cost and effectiveness of various policies allow choices to be made among them. In this section re- source costs for several of the policies simulated for Boston and Los Angeles are roughly estimated and compared with the two effective- ness measures used in the previous section. Many components of the costs of the simulated policies can be derived from the model itself. For example, when transportation poli- cies'are applied, the model estimates changes in the use of automobiles, in transit ridership, and in the amount of time devoted to travel, which then have to be valued. The model provides no insights about the capital or operating costs required to implement a policy. These figures must be estimated separately, but estimating these cities costs for some policies is difficult because there are few examples of their use. 12 For each policy the model forecasts total vehicle miles travelled (VMT) the number of , round trips that originate on transit, the number of passenger miles travelled (PMT) on transit by persons who transfer from auto to transit for a portion of their trip, and the number of hours per weekday that people spend travelling. Table 3 displays these four quantities from the benchmark runs for Boston and Los Angeles. Since policy costs are derived from changes in each of these four measures, the absolute levels displayed in table 3 provide a bas&pooevedaHdpget setb#ttflqhaCg&,IRDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 317 BENCHMARK TRAVEL MEASURES FOR BOSTON AR D LOS ANGELES Transit Originating Round Trips Transit l'NP From Auto Hours of Travel 21,960,36 165,936,000 348,252 2,040,852 -6,450,413 Source: TASSIM simulations Boston Los Angeles Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 446,367 ? 326,321  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The changes relative to the benchmark run in each of the four transportation measures for each policy simulation are displayed in tables 4 and 5 for Boston and Los Angeles respectively. For example, the first entry in the VMT column in table 4 indicates that vehicle miles travelled relative to the benchmark declined by 71,000 in the parking-charge simulation for Boston. For the same policy relative to the benchmark run, transit originating trips increased by 9,008, transit passenger miles travelled (PTIT) from auto originating trips increased by 379,167, and total person hours spent travelling rose by 8,835. The pattern of changes in the travel measures displayed in tables 4 and 5 is similar. If a policy increased a particular travel measure in Boston, it usually increased the travel measure in Los Angeles. The absolute changes in the travel measures are typically larger in Los Angeles than in Boston but, when scaled by the size differences of the two cities, they are generally similar. The most significant differences between the two cities involve the changes in transit originating trips. These differences are attributable to structural differences between the alternative modes of travel in the two cities: Boston has a much more highly developed transit system than Los Angeles. The travel measure changes displayed in tables 4 and 5 were multi- plied by costs or by prices to value them in dollar terms. VMT are valued at six cents a mile, an amount that approximates incremental operating costs for autos. Transit trips are valued at sixty cents each, which approximates the average cost per passenger trip in the Boston and the Los Angeles areas. Finally, hours of travel time have been valued at $1.75, which is one-third of the median wage rate in Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 319 Table 4 CHANCES IN TRAVEL MT:ASU1 ES RELATIVE TO 13ENC1D1AILK 'OR SEVERAL POLICIES APPLIED TO BOSTON VMT Transit Originating Trips (PMT) Transit PMT from Auto Hours of Travel Parking Charge -71,000 9,008 379,167 8,835 Local License -220,000 -1,297 330,685 17,362 Prohibition -265,000 592 375,968 21,177 Prohibition & -444,000 62 403,721 15,795 Congestion Fare Reduction -247,000 9,035 72 19,018 .Improved 403,000 21,632 683,345 25,046 Transit Performance Transit 22,000 40,905 44,203 17,513 Extension Raise CED Auto 166,000 1,309 -88,342 -3,247 Speeds Lower CBD Auto -166,000 -1,276 105,348 1,003 Speeds Raise All Auto 659,000 --5,060 -96,110 -110,434 Speeds ? Lower All Auto -613,000 4,307 134,601 106,211 Speeds Increased Auto -1,975,000 0 0 Occupancy -1,111,000 36,628 40,598 -13,420 1,.1020,000 -57,606 -83,330 -15,575 Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Source: TASSTl1 -,i 1.atic-nr  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 CHARGES XN Ti{AV`,.::L 1?M"ZURES REL!!TIVE TO I3E:ICI"J RK FOR SF,'VER:'J, POLICIES APPLIED TO LOS A::GEL:r.'S Transit Originating Trips (PMT) Transit F?.2 frc~ Auto Hours of Travel Par}in6 Charge -2,198,000 4,380 3,].27,652 100,417 Local License -1,595,000 436 3,017,695 60,070 Prohibition -2,108,000 ? -864 3,901,766 72,350 Prohibition & -2,080,000 2,679 4,118,656 201,292 Congestion Fare -258,000 17,974 --1,541 3,106 Reduction Central. Bus -2,546,000 21,000 2,600,000 -2,332 Lanes improved -3,302,000 58,703 ..3,49(i,156 -16,007 ..Transit Performance Raise CBD 260,000 -491 -326,231 -23,792 Auto Speeds Lower CBD -211,000 210 364,386 16,808 Auto Speeds Raise All 468,000 -6,640 326,231 -1,172,193 Auto Speeds Lower All -478,000 3,876. 509,599 629,898 Auto Speeds Increased 15,184,000 0 0 Auto Occupancy Source: "RTediFR17,RtWse 2001/11/19: CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 the two cities. 13 Si.nce the travel measures are for weekdays, the weekday valuations have been multiplied by 300 to transform them into annual values. 14 The results of these calculations are dis- played in tables 6 and 7. For exariple, the first nonzero entry in the W7 column in table 6 is -,",1,27,),000. This is obtai.ned by multiplyinc; -71,000, the charge in V'"IT from parking charges in Boston, by $.06 and then by 300. Tables 6 and 7 also display estimates of the capital and adminis- trative costs of implementing most of the policies. The costs shown for emission reduction assumes that the aver;w a i.ncremental cost per car (relative to 1970) of reducing emissions in Boston is $40 in 1976 and $65 in 1930, while in Los Angeles the figures are fi50 in 1976 and $85 in 1980. Capital and administrative costs are not displayed for some of the nolicies because of uncertainties about policy imple- mentation. For example, increasing the averace occupancy of automo- biles by ten percent above their current levels would reduce V"T pro- portionately, but estimating the cost of obtaining such an increase is difficult because the determinants of car pooling are not well understood. Similarly, it would be very diffi.cult to estimate the costs of centralization for Boston or for Los Angeles. The costs in tables 6 and 7 are plotted against the effectiveness of the various policies in figures 6 through 9. For most of the poli- cies the local effectiveness diagram resembles the regional effective- ness diagram, and the Boston diagrams resemble the Los Angeles di.a- grams. For example, in both cities all effectiveness measures increase steadily from fare reductions to parking charges, to improvements in transi.t performance, to local licensing, and finally to prohibition. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19.: CIA-RDP79-00798AO00200020005-9 322. sJ cccc u .1 ?ri 43 ri Si to a. C ?rt to 14 U a.? o~ a to N 0 to i+ 14' O O 0 O O M O N N C. ~. N C r O rt t'. N tr1 ap C- , o' O N ' co r4 0 r4 r?i w . f- w u. 1 aw w q% 1 tit in O O cl co 0 to 0 N Ln %01 co N M S tl %D w r1 N1 w co w 0 w r'?t O ; 1 1 N r-I M O v O N co 0 LM to 0 O Co w 1 r~ -I-I 1 i O (J% co OD Co r* r1 h 'T 0 O 0 M ON C% Co 0 0 0 N N !V ~, 1 w .-l w N N N O 0 O M C- M 'N O 0 O O O O rt Approved For Release 2001/11/19 : CIA-RDP79-00798A00'0200020005-9 O 0 N at . 9-1 . F 0% a CQ O C) O ?.7 t1 rIj C7 O F? Oh r4 fN Co r' H r1 %D 0 co f'1 .y n ra H N ri '9 -( H r O r q f-1 N On r-1 w w w 4 w w rl cr O 0 P% N Co w w A w cj% t-i.?1 r r, l r-t .4 t7 r-i N ; N N ?? 0 co O O N tD t f`. %0 h. 0% -r In N On F'- Or - tV rd M ??7 N -' I'- 1 1 1 1 '1 0 0 O O O O 0 t9 r) M M rj N  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 323' o 0 CMr) O co ^ - r1 0 C3 %0 Co .` ) c w o w c. w O w n w r?? w -1 w r-{ w C. w CO w 0 L?+ n - M tD M Co N h M 00 N M .4 -4 CO ; O O r-1 N. ^ It 0 co M co e N a O n tr) CT d w w w %0 w %D w N w .7 w .7 td? O r" 1 CO w E-4 L-c N M M C? 1 H y 1 H V b0 H O O O. 1\ r-I N O 0 Co 0) ra 1J ?r{ 0) M 00 Co .7 N - O. r- 0 4J c rj to f: Cl) w Ln w N w co w 1 CO w 1C0 w M w O ?rl c3 b 1? C) . c~+ < ?rt1 H CO n . .O O. C9 co I 0 to 11 ?r{ A) ? O O n 1` r-I .7 r-1 O M 1- V) cJ U) CC r co U') a H r-1 % a) ^ w co N' Co H r. i 0 sa ra P H? f-c %0 OP H L-: , ~ 1 -t W to 0 & O O -- O - C- IT CO %n 0 r I N .D r-I IT .7 ti N M G7 O O it w O. w .~' w .7 w OD w IT w .D w to H to O 0 O v U W CA ci co 1 f~ 1 f- I ce) i I W &5 4 1 U 4.1 O O 0 0 b O C) 0 0 O C- a CD CO v') tr) to ,n O 0 o O f"- n N- N- C) 0 C) O ?r{ u w w w w w tr. 1-3 Cn O ?r{ J U) C ~ ? 1-. (7% ~' cn N n N w N w 0 -T CV r2 1~ V C- ?r4 a -a r-1 cn 0 7 00 i., tr n 0 M Co H w' w w O. 00 ' M I ra .D 0 to f`- O. 0. I M M ; i r.. j to .7 - N O. C11 C> r-1 f~ -7 '.D Cr) w w w ,? h 00 co 01 N 0 ? c-- C- U) to 0 Cl) cJ 10 10 .0 10 N C4 E Q. O 0 0 iJ JJ A C] r-1 H b V Co C 6 ) N a $ 1 ?~{ o rr~? o C) Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release, 2001/11/19 : CIA-RDP79-00798A000200020005=9 324 FIGURE 6 COST J WD LOCAL EFFECTIVEUESS FOR } OSTON y Transit Extension 9O- 0 A 1 1980 Emissions 0 Transit Improvement 1976 Emissions Q $4 2 0 Prohibition 51 Local License Parking C, )Ch arge O Prohibition & Congestion cn. 14 ,.~ ODecentralize V 4 Reduce Transit Fares ~QDecrease Central A to Speed:: '0 2b 50 Local Effectiveness ? (Percent CO Reduction in. CTBD) Approved For Release '2001/11/19: CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 FICU1tE 7 COST AND REGIOIIAL EF17ECTIVENES S FOR BOSTON loot .Transit Extenyion Transit Improvement 0 1976 Emissions 325 c'rohibition 0. Local License C) Prohibition & Congestion 0 Raise Pa1?kj.nG Charge Increase Central UReduce Transit () Decentralize -1160 -"-00 0~ 660 8i 0 Auto Speed.,, Decrease Central Auto Speeds Regional Effectiveness (1eduction of Person-Times of Approved For Release 2001/11/19 };Q QIF 7a-ROTOFAOQQ C)020005-9  Approved For Release 2001/11/19,: CIA-RDP79-00798A000200020005-9 FIGURE 8 COST AND LOCAL EFFECTIVENESS FOR LOS ANGELES 390 360 330 -r 0 Txansit Improvement 0 Raise Parking Charge 1980 Emissions 1976 Emissions 0 0 Prohibition E Congestion 0 Prohibition 0 Local License 30- Decrease Central Auto Speeds ( (ILICC '_1't_T1S~l.t F Ires 6 6 o 18 24 30 36 4~ .4 54 60 66 7 7~8 ?.30 T Inci'ease Local Effectiveness Central (Percent CO Reduction in CUD) Auto Speeds Approved For Release 2001/11/19 : CIA-RDP79-00798A00.0200020005-9  Approved For Release 2001/11/19: CIA-IRDP79-00798A0002000200050 PICURE 9 COST AND REGIONAL EFFECTIVENESS FOR LOS ANGELES 1980 Emissions ?1976 Emissions -200 . 0 Prohibition o Local License O Transit Improvement Q Raise Parking Charge Decrease Central Auto Speeds Reduce Trhnsit 17ares Increase Regional Effectiveness Central (Reduction of Person-Times of Auto Speeds Exposure in Thousands) c) 200 400 60b 800 1600 12260 1 Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Prohibition and congestion are similar to prohibition in. Boston, but are less effective than prohibition in Los Angeles. The major differences between Boston and Los Angeles occur in the central area speed changes, as explained earlier. Reducing auto emissions to the legislated 1976 and 1980 levels both in Los Angeles and in Boston is cost effective relative to the transportation controls, although more clearly so in Los Angeles than in Boston. Several of the transportation controls buy small impr.ove- rients in the effectiveness measures with expenditures that are also small, but large improvements in air quality are obtained only from the significant reduction in auto emissions over time. The transit improvement policies other than reducing transit fares and implementing reserved bus lanes are not very cost effective in the two cities. In Los Angeles, similar improvements in effective- ness can be obtained at less cost from parking charges, whereas, in Boston, improving transit performance is dominated by local licensing, or Prohibition. The central bus lanes simulated in Los Angeles con- stitute one of the more cost effective transit policies. The transit extension simulated for Boston is not cost effective and actually de- creases air quality as measured by the regional effectiveness index. One final policy in the Boston simulation that deserves mention is decentralization. The implementation costs of this policy are assumed to he zero since the suhurbanization of residences and employ- ment will undoubtedly continue in the future. Decentralization per- forms very well on the measure of regional effectiveness because it reduces concentrations of primary pollutants. The model does not predict concentrations of photochemical oxidents, however, and Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 decentralization may increase levels of this pollutant by increasing aggre-ate emissions of. NOX and 11C. 5. CONCLUSION This analysis of transportation control policies in Los Angeles and Poston has evaluated the air quality impacts of several policies by combining transportation and air quality forecasts produced by a computer simulation model with economic calculations of the costs of the policies. A comparison of the costs with the air nuality impacts of the policies yields an assessment of the relative cost-effectiveness of the policies. This assessment can then be used as one means of choosing among alternative policies. Although this paper has focused on air quality impacts, It is obvious that the transportation portion of the TASSIM model could be used to carry out preliminary analyses of other issues. For example, the effect on the transportation system of various land development policies could be approximated with the model- or preliminary esti-. mates of ridership levels on extensions to transit systems could be provided. Of course, at the project level, more detailed analyses would be required, but the TASSTM model could help analysts identify those projects which merited further analysis. The model is inexpen- sive to operate and a large number of alternative policies can be com- pared fairly quickly at the regional level. Only those policies or programs which are particularly effective need be subject to project level evaluation. The use of TASSIM or other so-called "sketch planning" tools should help give analysts an overview of a wide range of policy alternative and help them to focus their project analyses more effectively. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 A_PPM1DTX: COMPUTATIONAL SUMMARY OF TITE MODEL The TASSIM model is typically executed on the computer as three separate computer programs named TASAC-D, TA`?SIM, and TASMAP. The TASAQD program of the TASSIM model supplies data on air pollutant con- centrations due to large point sources to the TASSTM program. TASAOD is a simplified version of the Martin-Tikvart Air 'ua].ity Display ?odel. It could be integrated into the same physical code as the TASSTN program. However, its isolation lowers the costs of TASSTM forecasts, since the majority of policy simulations look at strategies which have no effect on point source emissions. Therefore, the TASAnD program, under integrated operation, would simply reproduce its output over and over again. For Boston, the TASAOT) program requires slightly less than two minutes of CPU (Central Processing Unit) time and about 2.3 minutes of total job run time per simulation of the 370/165. About 115 I:-bytes of core storage are required to compile and execute the program at a cost of about twenty dollars on the TTarvard-.''.I.T. 370/165. The TASSIP" program performs virtually all of the operations de- scribed in the introductory discussion of the conceptual model. It requires .95 minutes of CPU time and about 2.7 minutes of total job run time per simulation on the 370/165. The Boston version of the TASSIN program requires about 156 P.-bytes of core at a cost of about twenty-five dollars per run. Of course, these run times and storage requirements will vary if the dimensions of the model change. Faster run times could be obtained with IT compilation and the use of object decks, and lower costs could he achieved by storing the input data. on a user disk. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 TA^NAP is a supplementary program that graphically displays pol.lu- rant concentrations on maps for the entire study area and for the cen- tral core area. The naps are visual displays of information printed out elsewhere in the simulation run. The TASINAP routines could also he intec'rated into the TASSIP4 program, but using TA!'%Ir to print out several naps at once is only sli'htl.v more expensive than printing out a sinc'le man. Therefore, it Is efficient to complete several simulation runs and then to create maps for all of the runs at once. Thus, TAVA.P, like TASAOD, is physicall,t separate from the TASST'T program. Unlike TASAOT) however, TAc*tAP is not essential to the TA^ST*'' model, since it merely provides graphic displays of outnut produced by the TASST'T program. A typical map produced for Poston is displayed in figure 10. The Poston TASNAP program requires .9 minutes of CPU time, 1.4 minutes of total job run time, and 11.8 k.-bytes core to produce twenty maps. To adapt the TASSIM model to another city requires tables of travel times and trips, inventories of stationary emissions, meteorological parameters, vehicular emission rates, and socioeconomic characteristics of the population for calibration. Our experience with the Los Angeles version. of TASSI?' suggests that transf.erring* the model to another city requires from six to eight man-months and about four hours of computer time on an T_R*t 370/1.65. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005392 nI N P P N N P N N N N N N N N N N N N N N N N N N N M N N U ^ N 1 N N N N N N N N Y N N N P N N N N N 1 N N P N N N N N N N N N N N N N^ N N N N^ N N N N N N N N N N Y N N 1 1 1 P N N N N N N N N P N N N N N N U^ ^ N N? N N N ry^ N N N^ N N N r N^ N N N N N 4^ .?. N N N r N N N Y N n .?. N N P N N N N 11 N N ?? ? N N N N N N N N N n N N N N N 1 N N N P N N P N 1 1 N N ... N N N P N N N U N II... N N 11 N 1 I' 11 ? b N N N II I 4 ^^ N N r N t' II N N P N 1 1 ^ 1 1 1 1 P P 1111 1 1 1 1 N .? .?? 1 1 Y 1 1 N 1 I N I, N 1 1 1 N 11 II 11 ?? ~? ?? N, V 1 1 1 II ? fl II . N_ Nn I I X I II ^ r. ^ t S 11.' I t ~..-.... N .. ~. .^.. C. 4l l 1 I I N N u .x>[xxx 1 I N N It .. +'N X X K K 1 1 1 { ^^ >CKr; 11 1 11. ?'. 1 1 1 1 1 1 1 N Ii VN U 10 FN aT ??11 C> C) 1 'l N N 1 N Y N I 1 1 1 1 I 1 I 1 1 1 ^ 1 1 I 1 .+ 1 1 1 1 1 1^ 1 1 1 1 1 1 1 1^ .?. N N N . I I K >S K 11 I' , I ^^^ x K X X 1 II ? x 74 >< Y. X K 11 U N -. > C K K 11 11 f1 ^ . ?+ Y, x x x c N N I P N N N P 1 N N N N N N N 1 Y M N N N N N N N N U N N U II !; N. N N N 11 N N N N N 1. N Y It N N 11 N N N N N ^ N N N N N N 11 N N N N N 11 N 11 N II N 11 N M N N Y N N N N N N N Y N 11- N N M M 11 U N N N It N N N n 11 N 'N N n ~+ 11 Y 4 N N 4 N N ^ N N ..?. N N N tI 11 N N N N N N ~. N N N it N N N N N P N 11 N N II N N N N N N ?`. .'. n N li N V. U N N N r k .?. N N N N N 1' N N 11 Y N N 7N N N N N N II N N N N /. ^ ' . N N ?1 11 U n N N I1 N N n N .~ 11 M N N N M P 11 11 11 N y N N +?. N N N N N N N N 11 N N N^ N ++ 11 N N N Y N 11 II N N 1; N N N N )11 ? ...., y 11 N N N N N N N N N N NC ^ r.. 11 ti 11 11 I. 11 N N U II M N K N -II N II 11 P ti N It 1' N N II P N N 1 K X Y. 11 1 11 91111 N 1; N 11 1; N N N 1 1 11 1< 1( >4N U N 11 I it N N N N 11 N 11 11 1 1 1 r >( >( P N 11 y 11 N I I N N N 'I N Y. , I I ? 1 1 1 1 74 4D 11 Y 11 1 1 .. S.H 11 1 1 N N 11 4; 4+ U`^ 11 YD U' 1 ? 1 1 1 1' K Ni 1 1 1 1 1 1 1 1 I I I , I I I 1 1 N Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Gregory K. Ingram, Gary R. Fauth, and Eugene Kroch, TASSIM: A Transportation and Air Shed Simulation Model, Vols. 1 and TI, Final report to U.S. Department of. Transportation under contract DOT-OS-30099, "lay 1974. 2. These procedures are described in Urban Transportation Plannin -- Central Information, U.S. Federal highway Administration, Washington, D.C., March 1972. 3. A "cold start" occurs when an engine that has cooled to the average air temperature is started. Cold start emissions differ signifi- cantly from the emissions of an engine running, at its usual opera- ting temperature. 4. The air source model is described in F. A. Gifford and S. R. Hanna, "Urban Air Pollution Modeling," presented at Second International Clean Air Congress, T'ashington, D.C., Deceriber. 1970. 5. The point source model is described in D. 0. Martin and J. A. Tikvart, "A General Atmospheric Diffusion Model for Estimating the Effects of Air Quality of One or More Sources," APCA paper No. 68-148, June 1968. 6. The diffusion models predict annual average concentrations of pol- lutants. A "Larsen transformation" is used to relate the predicted averages to the ambient standards. See ralph J. Larsen, "A Mathema- tical Model for Relating Air Quality Measurements to Air Ouality stag vtd I'8eP A$ 2&m /g1P14'.'PC1i~=Rb 60'98AUDU1~~51~71.  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 NOTES (continued) 7. The emission reductions described reflect legislation in force as of January 1974. 8. The TASSIM model's price elasticity for parking is about -.3. Parking price elasticities typically range from -.3 to -.4. See Damian Kulash, "Parking Taxes for Congestion Relief: A Survey of Related Experience," Urban Institute working raper 121.2-1, Nay 1973, processed. 9. These elasticities are similar to those estimated in other cities. see ierald Kraft, "Free Transit Revisited," Public Policy, Winter, 1973. 10. Automotive emissions reductions from speed increases may be only temporary since an improved transportation system may attract more trips. 11. Recall that the simulations do not predict concentrations of photochemical oxidants. 12. Determining the costs of regional policies such as changes in regional auto speeds, increases in automobile occupancy rates, and alterations in land use patterns is beyond the scope of this study. For this reason we do not include them fully in our cost effectiveness analysis. 13. Empirical studies of travel behavior suggest that people value time at approximately one-third of their wage. See Michael E. Beesley, "The Value of Time Spent in Travelling: Some New Appro.Hond lkiaTte /44L19'*!CIA9RbPT9a-00tbtA'dbb-200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 NOTES (concluded) 14. Veekday travel exceeds weekend travel, and the use of 300 rather than 365 provides crude compensation for this. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 336 THE INTRODUCTION OF MATHEMATICAL-ECONOMIC METHODS AND COMPUTER TECHNOLOGY IN PLANNING AND MANAGING SOVIET TRANSPORTATION R. S. Kozin The present period is characterized by an increasingly complicated over- all transport system, rising intensity in the use of transportation plant and equipment, and closer connections between transportation and other branches of the economy. Successful functioning and development of the trans- portation system under these conditions depends to a large degree on the quality of management. Planning is the foundation of management. Use of mathematical programming methods and computers have permitted the formulation and solution of a whole series of technical economic and planning problems with practical importance. This circumstance has assisted the appearance of theoretical research, in- cluding such problems as the formulation of a national economic plan considered as a type of extremal problem in mathematical programming;. Theoretical re- search has shown the possibility in principle of constructing an optimal national economic plan. Under socialist conditions the possibility of,working out an optimal plan becomes practicable. The following conditions assist this: Presence of a unified institution influencing the planning activities of all branches and enterprises: Noncontradictory goals for the functioning of different branches and groupings ; The possibility in principle of collecting and preserving all the neces- sary information on the status and functioning of the branches of the economy. Introduction of economic-mathematical methods and computer technology in planning at the present time is directed toward: *?)ire _ _ _ ~~~I~as~f2~$119~5~'7~10(05-9 3~ a Techn .c ences  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 137 Obtaining optimal plan solutions for the basic problems of operating and developing the transportation system; Achieving consistency among all decisions taken by plan organizations; Carrying out by automatized means all the formal functions, most of which at the present time are carried out by planners (acquisition, compi- lation, and systematization of information, preparation of plan decisions, definition of their possible consequences, and so on). Automatization simply of the formal procedures met within the tasks of statistical and accounting record-keeping, material-technical supply, several planning tasks, and so forth, will, to some extent, permit a reduction in the management apparatus. Computers have already been used to solve this kind of problem in transpor- tation for about twenty years. However a fundamental effect from using economic-mathematical methods and computers can be obtained in the productive sphere only through optimization of processes, more rational use of fixed and circulating capital assets. Besides, theoretical research and practical experience show that the effect of introducing economic mathematical methods and computers will be considerably greater if a system of tasks is solved, covering as a whole the defined functions of production, and not separate problems relating to certain partial aspects of these functions. In the USSR three levels of automatized management of the transportation system are being worked out. On the first level Gospian USSR is working out an automatized system for plan calculations in transportation (ASPRT) as one of the functional groupings for a subsystem in planning the national economy as a whole. The basic tasks to be solved in the system ASPRT are: Definition of the transport factor in the development of this branch of the economy (direct input coefficients in the interindustry matrix); Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Definition of the final demands for transportation on the part of the population and the economy and the breakdown of the shipments among the various carriers: Distribution of investment according to the direction of its utilization in order to attain a minimum outlay of national economic expenditure on the required shipments. Each of these enumerated problems is in itself a large problem, their solution in a mutually linked manner will permit the working out of scien- tifically substantiated plans for the functioning and development of the transportation system of the country. Each functional subsystem of ASPT, made up in accordance with general principles, and this includes the complex subsystem for transportation, is made up of several blocks. In the transportation subsystem, the following blocks are being worked out: The general block In the general block, problems are solved connected with defining the total demand for freight and passenger shipments and its subdivision among the various carriers. The production block In this block are worked out the integral indicators for the work of each means of transportation and, also, the volume of work assigned to each element for all means of transportation. The science and technology block In the science and technology block are worked out the possibilities for making use of the achievements of general scientific-technical progress Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020 3 5-9 for the technical reequipment of transport; in this block are specified also the principal scientific problems and ways of financing their study. The capital construction block Transportation is one of the relatively capital-intensive branches of the economy. Transportation plant and equipment make up a significant part of the economy's fixed assets. Moreover, in the future it is intended that rather large capital investments will be assigned to the development of the transportation system. The effectiveness of new capital investment in transportation depends on how it is allocated. Solution of this problem is basic for the capital construction block. The material technical supply block In this block, the input requirements for rolling stock and equipment for each carrier are worked out, along with the necessary supplies of fuel (electric energy) and raw materials. The block for labor and staff In the labor and staff block we estimate the labor force required to operate the transportation system and, also, make up plans for training workers with the necessary qualifications. The block for costs, profits, and profitability In this block we calculate a summary measure of the activities of transportation as a branch of the system. It is necessary to underline the fact that solutions for the problems of each block are linked together. Therefore, in order to obtain consistent answers, plan calculations cannot be carried through just once. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The plan solutions obtained through ASPRT for transportation by these methods both depend on, and have an influence on, the solutions that are reached in the other functional subsystems of ASPR. The mutual consistency of solutions is assured by the unified structure of subsystems, the general methodological foundation, and the unified technical means for processing information. The introduction of A9PR at all levels is connected with an improved methodological basis for solving plan problems through utilization of optimizing economic-mathematical models. In each of the blocks of ASPRT listed above, economic-mathematical models are worked out. Two of them--the planning of rail freight shipments and the planning of capital investments to increase rail line capacity will be described at the symposium. The second level of automated systems for management, OASU (branch automated systems for management), is put together at the ministry level. At the present time, managing the work of transportation is handled by three union ministries (railroad, maritime, and aviation) and by republic organs of management for river and automobile transportation. Roth in the union ministries and in republic GOSPLAN bodies, corresponding forms of ASU are being worked out. The planning block in'OASU is one of the main ones. In this block the planning assignments worked out at a higher level are made more detailed. This disaggregation is carried out both with numerical indi- cators and through specifying "addresses" more precisely. Along with the tasks of transport planning, in OASU we solve in the first instance the problems connected with operating management of the shipment process, the planning of freight traffic, operational management of operating work, pre- paration of documents for performance standards, material-technical supplies, and various kinds of records. Each type of transportation OASU has its own specific Approved For Release 2001/11/19 : CIA-RDP7900798A0002000200 5 9 functioning  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 and management of that kind of transportation. It must be noted that trans- port ASU differs from ASU for industrial branches of the economy. This is explained mainly by the fact that transportation is characterized by a more active role (compared with other branches) for the upper level in managing the productive processes. Such tasks as operational assignment of the freight car fleet throughout the railroad network, loadings at technical stations and alone line sections, since they have first-class significance for railroad operations, can only be decided at the ministry level. Natters are the same with other means of transportation. With the introduction of ASU for managing transportation carriers, the structural table of organization for management will also change and improve. Thus, while at the present time the railroads have a four-level system of management: ministry, railroad, division, line organization, with the intro- duction of ASU only three levels will remain: ministry-railroad-line enter- prise. With the changed structure of management, there will be a corres- ponding redistribution of management functions. A three-level system of management will come into being on the other means of transportation also with introduction of ASU. Within the limits of OASU, automated systems for reserving seats on passenger trains and aircraft are being created and developed. Special talks at the symposium will clarify these questions. A third level of automated systems of management consists of ASU for technological processes and operations. Operating management of the work of freight classification yards, seaports, airports, etc., is connected with solving numerous and reciprocally interrelated problems in ASU of technical processes--this as a rule involves systems working in real time. Along with information processing equipment, a very important question for this kind Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 of ASU involves the collection and transmission of information. In con- nection with this, technology for collection (calculating equipment, pre- paration of documents, etc.) and for transmission (communication lines, commutators, etc.) must receive the necessary development. The main goal for operating planning consists of carrying out plans made up for a more extended period. In general, the principle for tying together all types of plans, beginning with operating plans straight through to long-term plans, consists of having the plans made at a low horizon of planning "concretize" the plans made at a higher horizon of planning. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9343 OPTIMIZING MODELS FOR PLANNING THE OPERATION AND DEVELOPMENT OF A TRANSPORT NETWORK I. T. Koslov The transport network is construed as a common graph whose elements are constituted by nodes and sections. Fach element of the transport network is characterized by a range of technical and operating parameters which define, with an acceptable degree of accuracy, its carrying capacity and the cost of moving cargo (passenger) within the boundaries of the element. The performance of the transport network is determined by the load (quantity of cargo tonnage or number of passengers) on its component elements. Such a concept of the transport network is at variance with the notion of the transportation requirements of the national economy and the population. De- termination of the transportation requirements of the national economy and the population is an independent problem in its own right, which lies beyond the scope of the present paper. But if one is to analyze the degree of utili- zation of the transport network carrying capacity, the loading of its principal elements comes in as a very handy tool. Thus, in the problem under consider- ation, planning of the transport network operation boils down to determining the loads on its component elements. To outline the pattern of development of the transport network is to determine the kinds of reconstructive measures envisaged and the points in time when the network elements acquire additional capability. Problem definition The problem of determining the volume of operation and the ways of development of the transport network can be solved on the following premises: *Divisio~~.,,~~g ~n i ute of Complex Transport Problems and Doctor "art Tec nico~ g~9Q01/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 1. The transportation requirements of the national economy that the transport network is to meat are expressed as follows: The pattern of relationships of the various kinds of cargo between the network nodes The number of passenger trains running over each network section The volume of the local cargo flows over the network sections Each form of transportation requirements is liable to very in time. In fact, the transportation requirement for the future is an indefinite quantity which only lends itself to probabilistic treatment. However, for the purposes of the present paper, it is assumed that this factor is a determinate quantity. Thus, the problem solution cannot but he treated as tentative. One can assume that the indeterminacy cannot detract from the usefulness of the problem to be considered. 2. The and goal of the transport system consists in meeting transpor- tation requirements at the least cost. The transportation costs depend on numerous factors, some of which are relevant to the problem under discussion: The choice of cargo routes within the network The technical state of the main network elements The transportation pattern 3. Cargo may be carried from one nods to another by quite a few different routes. Of course, the choice of the route for each individual batch of cargo never conduces to an optimal solution of the overall problem for the simple reason that the total transportation costs by and large depend on the loading of the elements encompassed by a given route. Furthermore, transport network elements with a limited carrying capacity often have to be excluded from the haulage routes for many cargo varieties. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 345 The starting data for a model designed to determine the transportation costs consist of the loading of the network elements (nodes and, sections). For this reason, it is the loading of the network elements, and not the cargo routes, that will form the unknown variables. Obviously, the set of the chosen routes uniquely defines the loading of the network elements. 4. The network elements are technically developed through reconstructive undertakings of many kinds. It is possible to limit the number of such undertakings, but only on the basis of special research. A research program of this type has been conducted, e.g., for railway network sections. The results of the study suggest that, of all the possible measures, only the following are practically significant: Extension of departure and reception station tracks as conducive to higher weight ratings of freight trains Substitution of automatic block signalling for the electric staff system or semiautomatic block signalling Construction of additional main tracks on open lines Substitution of electric locomotives for diesel locomotives 5. The type of traffic pattern significantly affects the economics and the degree of utilization of the available carrying capacity. In its turn, the traffic pattern by and large depends on the technological state of the network elements. However, some variables also exist; such as, for instance, the type of locomotives used. Since the locomotive stock is generally limited, it is impossible to use the most effective units over each section of the network. Thus, a problem arises as to the most advantageous distribution of locomotives among the elements of the transport network, which, naturally, cannot be solved unless the state of technology and the pattern of traffic are taken into account. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Mathematical definition of the problem Let's introduce the main designations which will be used in the mathe- matical treatment of the problem. Designations s - number of the transport network sections (s - 1, 2, ..., S) i - number of the transport network nodes (i s 1, 2, ..., I) t - time (te/to, Tp/) p - type of cargo (p - l, 2, ...,P) R+(i), R 7(i) - totality of network sections going into and out of the node i xsp(t) - flow of cargo of type p over the section s yi(t) - operation of the node I -~ s(t) - vector function determining the technological state of the section s i(t) - vector function determining the technological state of the node 1 c(t) - traffic pattern A1(t) - pattern of relationships reflecting the needs of the national economy for the transportation of cargo of type p Ns(t) - volume of passenger traffic over the section s Fs(t) - flow of local cargoes over the section s K(t) - limit of investments into reconstruction Nn(t) - required carrying capacity of the transport network NH(t) - actual carrying capacity of the transport network (t) - passenger and freight transportation costs A(t) - reconstruction costs (t) - weight function to account for the time value of expenditures. The unknown variables in the problem considered are as follows: section loads x sp - X Approves For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 section development s . M node development H traffic pattern c The X and Y variables are determined by the choice of cargo routes. The section loads will be determined with a breakdown by cargo types condu- cive to more accurate technical and operating parameters of the operation. In a general case, the node load should be broken down to differentiate between the components differing in the level of reclassification. Thus, for instance, for a railway node, not only the overall car flow must be de- termined, but also the transit car flow requiring no reclassification, the transit car flow which does require reclassification, and the local car flow. Such an elaborate characteristic of node loading can no longer be de- termined merely by cargo routes, for to characterize the transit flow one should break it down into the reclassified and nonreclassified flows which calls for the knowledge of the traffic pattern. In the problem under consideration, the section and node loads are non- negative functions of time. The technical state of the sections and nodes may be characterized, with a sufficient degree of accuracy, by means of several parameters. As the latter vary with time, they indicate how the sections and nodes develop. The functions which define the development of the elements with time are charac- teristically discrete. Most elements have a limited number of states. Thus, for instance, the technical state of a railway section is characterized by hardly more than ten parameters, each of which can assume two or three values. Such a specific nature of the/I s(-f)uVi(t) function may be used to construct computational algorithms. The traffic pattern varies widely depending on the particular kind of transport. Thus, the rail traffic system is by and large determined by the Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 distribution of marshalling operations among the stations and by the loco- motive service. The unknown variables are to satisfy three groups of constraints. Group 1 includes constraints which reflect the compulsory nature of all transportation demands. Mathematically, these constraints may be represented as follows: I,+ Xap(t) SEA-iXsp (t) Aijp(t) - 1 Ajip (t) (1) p Group 2 is composed of constraints which stipulate that the needed carrying capacity of the network should not exceed the actual value: Nn(X,Y,N,F,t) < Nn(M,H,c,t) (2) Group 3 comprises constraints whereby the needed reconstruction invest- ments should not exceed the available level: A(M,H,c,t) < K(t) (3) The problem solution is evaluated on the basis of minimal reduced economic expenditures: jpC (XY,M,H,c,t) + A(M,H,c,t)j (t)dt - min. (4) t ?Equations (1) to (4), together with the description of the function classes to which the unknown variables must belong, constitute the enunciation of the problem of traffic distribution and network development. Problem analysis The mathematicaldefinition of the problem suggests that all the variables being optimized are functions of time. Assuming that time varies discretely, the unknown functions can be determined by finding the unknown values of the scalar variables. By its type, the problem in question falls in the class of mathematical programmi1%#PjF r. Recta ,s ,1di &flMIe ~A-f~? 0@R88 ~D5n$rrawly  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 with a view to using the well-developed techniques. Indeed, it is only constraints (1), which represent constraints of a linear programming problem in a network form, that have a straightforward structure, whereas the proper- ties of the space assigned by constraints (2) do not lend themselves to clear-cut analysis. The left-hand and right-hand portions of equation (2) are calculated by special and fairly complex algorithms, which is also true for the left-hand portion of constraint (3). All three groups of constraints (1) to,(3) should be satisfied at each point in time independently. This requirement is used to construct a compu- tational algorithm for solving the problem. The properties of the functional to be minimized likewise elude analyti- cal analysis. However, one can assert that the functional to be minimized cannot be construed as a sum each term of which depends on just one moment of time. It is hence impossible to represent the general problem of traffic distri- bution and network development as a series of independent problems for a series of time sections. Thus, the problem under discussion belongs to the category of mathe- matical programming problems of a general kind. The actual Soviet transport networks have several thousand nodes and sections. Since the network carries several score aggregated types of cargo and the time base runs through at least three five-year periods, hundreds of thousands of variables will have to he determined if the problem is to be solved. Undoubtedly, an extremely complex computational task. Problem solution To obtain a general solution, the problem defined above will be broken down into the following parts: Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Distribution of the required traffic about the network (R) Determination of the required reconstructive measures for the network elements (V) The solution is arrived at iteratively as follows: R1+V1+S1+R2+ ... --Sk. While solving the first part of the problem, both the technological level of all network elements and the traffic pattern are assumed to be known. As the algorithm R is being realized, equalities (1) are satisfied for all time instants of the period in question. The second part of the problem is_concerned with the measures aimed at raising the technological level of the network elements. The traffic distri- bution and the traffic pattern are considered to be known, and the algorithm must be so constructed as to provide for satisfying inequalities (2) and (3) given in the mathematical definition of the problem. The third part of the problem deals with the traffic pattern, the traffic distribution, and the technological level of the network elements being con- sidered as invariable. No proof has been offered to the effect that iteration conduces to an optimal solution. Moreover, the large dimension of the problem does not allow for too-many iterations. It follows that an approximate solution is the only one that can be obtained by the proposed method. The traffic problem algorithm can be employed as the algorithm R for determining the traffic distribution about the network. In fact, constraints (1) are exact analogs of the traffic problem constraints. The national economic expenditures on traffic, which are part of the general criterion (4), may be used as the yardstick for determining if the solution is indeed an optimal one. If the methods used to solve the traffic problem are to be Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 applicable here, the traffic expenditures must be represented as a sum of expenditures related to the network elements, and this kind of represen- tation involves a certain error. Numerous authors have demonstrated that the hypothesis which stipulates that expenditures grow linearly with the loading of the network element, is too broad, which calls for the use of more complex functional relationships between expenditures and loading. Analysis indicates that the real functions of expenditures all show an important property; viz., the curves are convex downward. This made it possible to work out a special algorithm for determining the network distribution of traffic with nonlinear characteristics. It is a final algorithm conducive to a truly optimal solution. The traffic distribution problem as stated must be solved many times for fixed moments of time within the period under consideration, so that the network element loads are actually obtained as functions of time. The optimal development of the technology of the network elements is determined on the basis of the element load values established at the previous stage. Mathematically, this part of the problem could be reduced to the task of finding a minimum of the function of many variables which represent the sum total of all expenditures over the period under consideration. Such representation of the problem is made possible by the specific functions of development of the elements as indicated in the mathematical definition of the problem. When determining the optimal pattern of development, inequality (2) is taken into account for each element separately, whereas constraint (3) must be satisfied for all elements lumped together. To satisy this latter constraint, a heuristic algorithm is suggested which sets the order in which reconstructive measures will be taken, it being understood that the order Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 thus set :takes effect only if limited investments are available for the develop- ment of the carrying capacity. The optimal traffic pattern is determined by the results of the two pre- vious solutions. Central to any traffic Rystem (at any rate for the rail- way network) is the deployment of locomotives. Analysis indicates that this problem may be solved, given some assumptions, by linear programming techni- ques. Special methods exist for scheduling and distributing marshalling jobs, but in this case approximate methods based on statistical data seem to suffice. It is thus clear that the general problem of traffic distribution and technological development is actually a set of interrelated, highly complex, and computationally labor-consuming problems. Hence, the problem can only be solved through the use of efficient computer centers. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 METHODS OF FIVE-YEAR PLANNING OF TRANSPORT-ECONOMIC CONNECTIONS: THEORETICAL DEVELOPMENTS AND EXPERIENCE WITH PRACTICAL APPLICATIONS N. I. Mokrousova and Z. I. Mozgrina * The volume of future traffic is crucial for many aspects of five-year planning. For this reason one of the first problems to be solved is one of planning the transport-economic connections, which furnishes the initial block of data on the future volumes and directions of cargo traffic. From the economic point of view, the problem in question boils down to meeting the country's freight traffic demand at minimal cost within a preset production framework. In order to accomplish this task, optimization models are employed to plan the traffic volumes of the future. Analysis indicates that for the purpose of long-term planning of trans- port-economic connections, all kinds of cargo may be classified in three broad groups : 1. Cargoes which are planned on the basis of territorial production-con- sumption balances, with the transport-economic connections of the suppliers and the consumers liable to change 2. Cargoes which are likewise planned on the basis of territorial pro- duction-consumption balances, but with the transport-economic con- nections remaining invariable 3. Cargoes which are planned without recourse to territorial production- consumption balances The first-group cargoes may be broken down into two subgroups: Cargoes assumed to be homogeneous (most types of timber, cereal, and petroleum products), which are singled out from the rough lists of bulk cargoes by virtue of their homogeneous processability as Senior Research Staff, Institute of Complex Transport Problems Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 well as consumer and other properties. For these cargoes, the transport-economic connections are determined by optimizing sup- plies by means of linear programming traffic problem for preset points of cargo departure and destination and for predetermined cargo volumes. The volumes of departing cargo are determined by balance calculations for specific products using the oblast (roughly equivalent to region) as a base territorial unit. For the purpose of this paper, this kind of model will be referred to as a one- product model; Nonhomogeneous, but interchangeable cargoes, such as, for instance, fuel coal grades varying in calorific value or chemical fertilizers containing different levels of nutrients. These cargoes are like- wise covered by oblastwise and stationwise departure and arrival schedules. The optimization aroblems involved in the planning of supplies of interchangeable problem method (A-problem). The second group includes mining products are solved by the allocation This model will be called a A-problem. and metallurgical products, construction materials, petroleum, coking coal, grinding products, and many other kinds of like cargo. Given certain established transport links, their quantitative characteristics for the long term are determined by traditional methods, and the traffic plan is evolved using an optimization model whereby cargoes (relationships) are superimposed on the transport network following the tree of the shortest (cheapest) routes. The model used for this category of cargoes will be termed a rigid-link model. The third group includes several hundred agricultural products, foodstuffs, consumer goods, some chemicals, products of the woodworking and paper-and-pulp industries, metal items, machines, equipment, transport vehicles, industrial materials, 9150r8 cFtb' AIIJIUMPT"bi/' 9"11TP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 355 The items coming under this heading are universally produced and con- sumed, so that it is impossible at present to compile territorial production- consumption balances for these lines of goods. Hence, special methods have to be devised for their planning. Let us first dwell in some detail on the planning models of transport- economic links for the first two groups. The one-problem model, which is built around a linear programming traffic problem in network terms, is defined as follows. Given is a transport network containing n vertices and N arcs, the arcs being designated as S - 1, 2, ..., N; the vertices is - 1, 2, ..., n and = 1, 2, ..., n (is abd h9 are respectively the outgoing and the incoming s vertices of the arc S). The cost of transporting a unit of cargo along the arc Cs is known. Given are points of production and consumption of a homogeneous cargo. The production volume ak is more than zero, the consumption volume ak is less than zero, and ak is equal to zero at the rest of the network points, or vertices, where the cargo is neither produced nor consumed (k - 1, 2, ..., n). It is required to devise a plan of assigning suppliers to consumers and a corresponding traffic plan (xs, S - 1, 2, ..., N) such that would involve a minimum of transportation costs Cs X s -->41""L' ~c l while satisfying the following conditions- production-consumption balance E ak ? 0, k - 1, 2, ..., n; (1) flow equilibrium at the network vertices x x - ak, k - 1, 2, ...9 n; a is k a (2) Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 nonnegativity of traffic x8 >,, 0, S - 1, 2, ...9 N. (3)' The information input for this model is constituted by an aggregated conventional transport network. At this stage, the railway network contains 550 nodes (vertices) and 850 segments (sections). Aggregation and substanti- ation of a conventional network are dealt with in numerous special investi- gations. Reduced transportation costs and distances in kilometers were used as estimates of the network sections. The reduced transportation costs include the costs of operating trains, servicing them en route and maintaining in- stallations, as well as the investments into the rolling stock and techno- logical development. The costs and investments are incorporated in the part of the model which represents the traffic volume. The sectionwise indicators were differentiated for bulk cargo and oil products. Bulk cargo was defined on the assumption that all network sections were equally loaded in all directions and that the rolling stock was utilized to an average degree (80% utilization of gondola capacity and 90% utilization of boxcar capacity). For oil products, the assumptions were that the cargo was transported over all network sections and the tank cars were utilized to an average degree (80% utilization of tank car capacity). While planning specific cargoes, the differences in the utilization of the rolling stock capacity are allowed for through the use of correction coefficients. The estimate of each arc must incorporate the correction coefficient. In the course of computerized calculations, it was found advisable to use the main starting network variants for bulk cargoes and oil products, with the corrections being incorporated in the functional. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Experience with experimental and plan problems indicates that the network form of the traffic problem is the most convenient approach for planning practice. Its advantage over the matrix format consists in that it permits obtaining all elements of the traffic plan directly on the transport network (traffic over the network sections, relationships, and routes), evaluating the plan in terms of several criteria, and dispensing with the step of preliminary computation of the shortest and cheapest routes between specific suppliers and consumers, since problems for various kinds of cargo with any set of suppliers and consumers can be solved directly on the network. The network problem makes use of two kinds of initial information, viz. constant and variable. The former includes data on the transport network which are prepared in advance and stored in the external memory of the computer. These data are used throughout the entire computation cycle, being refined and corrected from one cycle to another. The variable information, incomparably smaller in volume, includes data on the cargo itself; i.e., on the arrivals and departures of the cargo at the vertices of the transport network. For the one-product problem, there is a set of programs which, along with the transport problem program, also includes a program for planning the assign- ment'of suppliers to specific consumers, the routes of cargo movement being indicated for each supplier-consumer relationship. The set further contains a program for determining the volume of work done in ton-kilonleter8. The programs provide for producing intermediate results (punched-card arrays) for use in crossfoot models. The next model is one of planning of nonhomogeneous interchangeable cargo traffic. Here it is possible to use a linear programming allocation problem (A-problem) which is mathematically defined as follows: Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Given are the points of production i and consumption j (i - 1,2, ..., n; J - 1, 2, ..., m), as well as the volumes of resources ai and consumption b1 of interchangeable products. Also known are coeffi- cients ail which relate the value of production ai to that of consumption b1. It is required to provide a product supply plan conducive to minimized transportation costs xi1 cil -- min < ai, i - 1, 2, ..., n; xi1 ail - b1, l - 1, 2, ..., m; xi1 > 0, A i1 > 0, where xilrepresents the supply of the products manufactured by the i-th supplier to the 1-th consumer; and cif represents the cost of transporting a unit of products from the i-th supplier to the 1-th consumer. The interchangeable cargoes considered in planning practice allow using a somewhat more complicated traffic problem rather than special allocation problem algorithms. This is made possible by the fact that the coefficient A for one of several suppliers has a constant value. In such a case, the coefficient XI is constant in each line of the matrix, if the traffic problem is solved by the matrix method. Thus, it is quite sufficient to divide the coefficients of the matrix cif by Al and solve a common traffic problem in conventional product units. For obtaining network results, the relationships thus found in natural units must be superimposed on the transport network. For the network case, this problem can be solved in two stages. At the first stage, the transport problem will be considered for a multilayer network for the entire volume of products in conventional units, whereas the second Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 359 stage will deal with ordinary one-product problems for each individual product in natural units, the one-product problems being defined by the results of the general optimal solution. The network problem proved amenable to solution because a small number of heterogeneous groups of interchangeable products was considered: three kinds of fuel coal and two varieties of nitrogenous and phosphoric fertilizers. The number of identical layers for a multilaver network corresponds to the number of heterogeneous groups of cargo being considered. The estimates of the identical laverwise sections are set to he inversely pro- portional to the coefficient lei. A multilaver network with sequentially numbered layers can be produced automatically by means of a special program. The starting economic data for heterogeneous interchangeable cargoes are con- stituted by the departing and arriving cargo volumes in conventional and natural units at the vertices of the transport network. The set of programs of this model includes all programs of the one-product model and an additional accessory program of transformation of the starting network into a multilaver one by the preset values of ai. The rigid-link model essentially contains a problem of distribution of predetermined cargo loads about the transport network. It is defined as follows: Given is a transport network containing n vertices and N arcs, the arcs being-designated by S (S - 1, 2, ..., N) and the vertices by i and j (1, j - 1, 2, n). The transportation costs over each are Cs are known. The traffic pattern is formed as a network of internodal relationships a,1j. It is required to construct a traffic plan for the transport network (x , S - 1, 2, ..., N) providing for minimized transportation costs: s Cx -I. min. s s Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 This problem is built around a minimum path-length algorithm. The cargoes planned with the use of this model are characterized by the need to retain, fully or partially, the transport-economic links evolved over a long time, while permitting certain changes in the distribution of production units and in the territorial production-consumption balances for the long term. Such conditions imposed on some links stem from technological require- ments, specialization of some production units in terms of special raw materials or mixtures thereof, and from some other factors of a similar nature. While readily incorporated in traditional plans, they sometimes prove unmanageable for economic mathematical models. To ensure automatic planning of transportation of this group of cargoes, the simplest possible solution was found; viz., to combine traditional methods of computation with automatic operations. Under this system, the interoblast and then internodal relationships accounting for rigid transport-economic links are handled manually by traditional methods, but the most labor-consuming computation tasks involved in the superposition of these relationships on the transport network and determination of the principal indicators of the plan are done automatically. The set of programs in this model includes programs for planning the traffic along the preset pattern of relationships between the nodes, as well as calculating the work in ton-kilometers. Summation programs were developed to produce the final results of the traffic operations, whereby resulting volumes can be obtained for any set of cargoes. Summation is carried out on the basis of the intermediate infor- mation furnished by the optimization models. The set of summation programs provides information on the overall traffic density over the transport network sections, the general and structural tables of internodal relationships, and Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 361 similar tables for interoblast, interrayon (rayon: a territory far larger than an oblast) and interrepublican cargo exchanges. Experience with experimental and plan calculations suggests that the long-term traffic volumes are generally understated, both in terms of integral indicators and for the sectionwise flow density figures. The understatement was tentatively estimated at 1 to 10% for various kinds of cargo. The reasons for such understatement should he sought in the following factors: Overaggregated long-term economic information worked out for an enlarged cargo nomenclature and large economic regions An aggregated transport network including 550 stations instead of the 8,000 actual stations and covering a smaller area. than in reality (113,000 km instead of the actual 135,000 km of overall route length due to the skipping of all dead-end sidings, underloaded sections and intranodal tracks) The optimization models themselves which, under conditions of the above-described aggregation, provide ideal optimal plans free from all kinds, even rational, of cross-hauls of actually nonhomogeneous cargoes (in the one-product model) In order to allow for the possible understatement of the integral and sectional traffic plan indicators, use can he made of corrections whose magni- tude can be determined by comparing the actual data with the calculations and introducing an allowance for the long term. All the above-described optimization models for determining transport- economic links are being currently introduced into the medium-term traffic planning practice. The transport-economic links of the third group are planned on the basis of available statistics. The problem may be defined in the following manner. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Given are an interoblast and interrayon tables of relationships for a certain base year derived from reports, as well as an interrayon table of relationships and total freight turnover figure for a given group of cargoes for the period being now considered, the latter two parameters being found by a certain method. It is required to determine an interoblast table of relationships amounts to the corresponding interravon relationships, and the freight turnover for a given group of cargoes is equal to the assumed given value r. Mathematically, the problem is defined as follows: Given: a matrix A each element of which (aij) characterizes cargo transportation from the i-th to the 1-th oblast in the base year (i - 1, 2, ..., n; 1 - 1, 2, ..., n). a matrix L whose elements lii characterize the distances between the oblasts; a matrix C each element of which (Crs) represents the traffic from the r-th to the s-th rayon in the base year, and d - rs i 5 where Jr is the set of all is which belong to the S-th rayon (r - 1, 2, ..., Z; S - 1, 2, ..., Z) ; a matrix D each element of which (drs) represents the traffic from the r-th to the S-th rayon in the year being planned. A matrix b is to be found such that max i,j bi drs ij Crs Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 on condition that bit aij , Vii Jd-7 s - drs, V, S 191 big lij - r, where bijis the traffic from the i-th to the j-th oblast in the year being planned. The above-defined problem is solved in the following way. First of all, it is necessary to determine coefficients characterizing the increase in the volume of relationships between the rayons in the year being planned as against the base year. The coefficients thus obtained are used to determine a proportional table of interoblast relationships for the planned period, simultaneously checking whether or not the condition that a predetermined freight turnover is satisfied. If this condition is satisfied, the problem is all but solved. If not, then, maintaining the same general picture of departing and arriving cargo volumes, the relationships between the oblasts must be so changed as to arrive at the predetermined turover figure, taking pains to keep deviation from the proportional pattern of relationships within a minimum, because of the specific nature of this group of cargoes. With a constant departing volume, the turnover can be changed by varying the average length of haul. To this end, the relationships must be changed in the following way. An additional table of relationships is found which actually amounts to the difference between the proportion and base tables. As the significance of relationships within each economic rayon diminishes, they are adjusted and finally broken down into pairs. The possible variation of the ton-kilo- meter index is assessed for each pair of adding the longest or the shortest distance depending on whether the turnover as a whole increases or diminishes. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 364 The variation in the ton-kilometer index is calculated for each pair by multi- plying the cargo quantity being transported by the distance differential. Integrating these variations for all pairs of cargo relationships for all economic rayons, we will determine the maximum value by which the turnover within a given table of relationships may be changed (increased or decreased). In order to achieve the predetermined turnover value, it remains to de- termine the share of the possible maximum variation. This value is equal to the proportion of turnover deviation of the maximum value by which the turn- over within a given table of relationships can be varied. The additional and then the starting tables of relationships may he varied in proportion to this share. The cargo traffic density over the sections of the network under con- sideration cannot be determined merely on the basis of interoblast links. Investigation of the interoblast exchange table of relationships for the group of "other" cargoes for the year 1970 indicates that the intraoblast traffic accounts for thirty seven percent of all shipped goods, but in terms of turn- over this kind of traffic is insignificant due to the short distances involved. If the traffic density over the network sections is to be determined, a more detailed table of relationships is required, for, alongside oblast cities there exist other big consumers (or suppliers) of "other" cargoes. Analysis of the points of production and consumption of the group of cargoes under consideration allowed for determining several aggregated nodes for each oblast, finding their relative shares of the total turnover and, thereby, breaking up the relationships of the interoblast table into smaller units. Knowing the production and consumption points and using the minimum path-length algorithm, the table of relationships can be superimposed on the Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 network being considered to find the traffic density for the "other" cargoes by the sections of the network. The above-mentioned algorithm was used to perform experimental calcu- lations on the basis of the 1470 railway reports. Analysis suggests that the calculations are entirely satisfactory for practical purposes. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 PROBLEMS OF OPTIMAL PLANNING AND MANAGEMENT OF AUTOBUS TRANSPORT IN THE GEORGIAN SSR G . G . Tsomaja 1. Goal Description The present level of motor transport technology, the ever' increasing traffic volumes and the increasingly sophisticated technology and patterns of the transportation process, all emphasize the urgent need to improve the methods of planning and controlling the operation of the transport systems. The motor transport of the Georgian Republic is a highly complex system which will be progressively more and more difficult to plan and control un- less modern control methods and technology are used. To meet this challenge, the "Avtotranstekhnika" /Automotive Transport Technology/ Agency of the Ministry of Motor Transport of the Georgian SSR has enlisted the cooperation of the Laboratory for Problems in Automatic Control and Computer Technology of the V. I. Lenin Georgian Polytechnic Institute to develop an automatic system for planning and controlling the operation of the passenger motor transport service. The program has set the following objectives: Developing an effective network of routes Selecting optimal types of the rolling stock Compiling bus schedules Approportioning routes and buses to motor pools Planning the technical and economic parameters of the bus Service for all levels of the control hierarchy Controlling traffic on a day-to-day basis. 2. Object Description The Georgian Republic can boast a highly developed bus service: the annual volume of passenger traffic amounts to 511 million passengers and * f ~A~ F`1R3'T ~ D f 98 ~~ Pc~bO6 O%d . Dept. of'Motor Transportation  Approved For Release 2001/11/19 : CIA-RDP79-00798AO00200020005-9 4,533 million passenger-kilometers; the republic operates 565 interurban, 1,001 suburban, and 257 urban bus lines, the length of all routes adding up to 108,700 km. In view of the many random factors affecting the transportation demand, the transport process should be regarded as a probabilistic one. It has been found nevertheless that population movement, for all its probabilistic nature, follows certain laws which shape passenger flows in space and time--and fairly strictly at that. Hence, a possibility arises to work out a network of routes with a regular bus service on the basis of a fixed schedule, thereby converting the probabilistic system into the next best thing to a deterministic one. On the one hand, this approach brings a measure of orderliness into transportation demand as the passengers are enabled to plan in advance the routes and times of travel; on the other hand, however, the passengers' freedom of choice is somewhat curbed. Reconciling these two contradictions is the problem con- fronting any effort to plan the operation of a passenger transport service as a technical system. Several problems also arise if the passenger motor transport service is viewed as an economic system. Thus, transportation demand can only be met on the basis of some resources, but these must be administered in the most effective way. Since the available resources are never unlimited and, de- pending on the particular conditions of use, vary widely in terms of effective- ness of utilization and economics, one finds oneself on the horns of a typical dilemma: either to try to find the most effective use for the available resources, or to plan resources to meet a prescribed level of effectiveness. Furthermore, serious problems must be dealt with while considering the passenger transport service as a social system. At the present level of civilization, movement turns into one of the most important problems which Approved For Release 2001/11/19 : CIA-RDP79-00798AO00200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 368 may presage the success or failure of any effort to develop productive forces, raise the cultural level and living standards, and meet other social needs of society. Viewed in this light, the passenger transport system is called upon to satisfy transportation requirements on the basis of social needs. Such an approach, however, is fraught with conflict between the demands the transport system must meet as a social system, on the one hand, and as a technico-economic entity, on the other. Thus, one can conclude that the object under consideration is a large, complex, dynamic and probabilistic system whose planning and control present considerable difficulties. 3. Requirements for an Automatic Stem for Planning and_ Controlling the Bus Service The problems one encounters while working out and adopting decisions to set up, develop, and operate a passenger transport system, are by and large of a poorly structured type. For this reason, no control strategy can rely on a single utility function which would describe the system in all its dimensions: technical, economic, and social. Furthermore, social objectives as often as not defy attempts at quantitative analysis and can only be repre- sented qualitatively. Most technical and economic problems do lend themselves to quantitative description, though some of them cannot he formalized. With this in mind, the requirements to an automatic control system may be stated as follows: The system must be a man-machine combination, with the man being responsible for the final decision adopted on the basis of a high-order set of objectives which can neither he formalized nor described in quantitative terms It must conduce to compatible technico-economic indicators for each ApptWM Ff IteMar6UT/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 369 It must be adaptable to various modifications of invariable and con- ditionally invariable input information It must be able to cope with all problems of technico-economic planning and day-to-day control both continuously and discretely, providing final and intermediate results It must provide all data needed for the purposes of day-to-day control by all hierarchical levels of the ministry's control system, with the information verified as to reliability, completeness, and timeliness, and taking into account the terms of reference of the personnel partici- patine, In the planning and controlling of the passenger transport operation; It must be able to cope with new problems related to the transport system without requiring substantial modification The above leads to the conclusion that the man-machine system for planning and controlling the operation of the passenger motor transport net- work must be able to solve problems of two classes: those related to an improved traffic pattern; and those related to the automatic processing of technico-economic and control data. 4. Solution Experience As an example of the way to solve first-class problems, let us discuss how the interurban bus service of the republic is planned and organized. The traffic plan is based on the population transport demand. Using statistical methods, one can process the data of passenger flow surveys or line documents in order to form a three-dimensional matrix of passenger relationships which would reflect the pattern of population movement in space and time. A survey of the republican interurban bus service indicates that the passenger flows fluctuate widely both during the day and from one day of the Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 week to another. Seasonal fluctuations have also been noted. (The survey, conducted in 1970-71, used special questionnaires for each running bus in the interurban bus network filled in every day during one demonstration week every quarter.) After statistical reduction (with a ten-percent deviation from the meanvalues), the data were used to construct a three- dimensional matrix for week days of the same type (working days and rest days) and for different seasons (summer and fall-winter periods). Thus, four combinations of a three-dimensional matrix of passenger flows were obtained, which formed one part of the planning data base. Another component of this data base is represented by the road network. The peculiar geography of the Georgian Republic shapes its road network which carries interurban buses: almost all towns and population centers are con- nected by solitary highways and no dense road network is in evidence. So, in actuality, the passenger who wants to travel from one town to another in most cases is left without options. The structure of the highways con- forms to a single pattern: four routes of the same configuration sprouting from the republic's capital city. Analysis of the passenger flows suggests that the movement among the population centers lying on different routes is negligibly small and can be ignored to the first approximation. For this reason, a model of the transportation process was constructed on the basis of one route or direction (western), which can be represented as a nondirected graph whose nodes are constituted by the towns and the arcs by the roads interconnecting these towns. The passenger flows on interurban routes may be carried by rolling stock of various kinds. So, accordingly, the third component of the data base comprises rolling stock characteristics, such as passenger capacity, class Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 of comfort, and speed of travel over roads of different categories. The data base is used to plan a regular bus service. The planning pro- cedure consists of three steps, viz. (a) development of a network of routesi (b) assignment of the type of rolling stock; and (c) scheduling of the service. Step (a) implies listing all routes and all buses on each route as well as the time each bus starts to run. Each route is defined by the list of network nodes that the bus must pass in a prescribed sequence in both directions. Assignment of the type of rolling stock implies selecting vehicles with the necessary characteristics corresponding to the principles of the service and permitting to meet them either in the most effective way or at minimum cost. And, finally, scheduling is a procedure of setting the time when the buses must pass all nodes along the route, with the names of the stops and the duration of each stop being spelled out. The above-described components of the planning process are closely inter- related and thus necessitate simultaneous consideration. Attempts at presenting all possible alternatives of bus service plans as a system of inequalities and equations generally involve large-dimension problems which often prove too difficult to solve even for computers. So in practice, optimal solutions remain an impossible dream and one has to be content with just rational solutions, at least in some cases. Therefore, the problem has been solved by heuristic programming tech- niques. A generalized model of the bus service operation has been constructed on the basis of the following assumptions and constraints which reflect the chief parameters of the passenger movement process: The policy of the passenger service from the viewpoint of a set schedule does not affect the distribution of the paired relationships in space and tine; i.e., the passengers may be classed only as those catered to Ai ep )S%4 F#-tRM 3Opa/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The possibility that one and the same vehicle may run on several routes is disregarded While assigning a bus, the first to be considered are short routes, and then long ones. This sequence ensures a maximum number of through routes and a minimum of transit passengers Through passengers enjoy priority when buses are assigned to routes, and only then the sections between the various route nodes which are not covered by the shorter routes, come in for consideration Buses are assigned to routes depending on their capacity, larger-capacity vehicles enjoying priority A bus run is considered to be acceptable if the dynamic coefficient of bus capacity utilization lies within admissible limits, the lower limit being chosen on the grounds of efficiency while the upper on the grounds of reliability Permissible limits are set to the time of bus stay at the intermediate stops of the route as well as to the bus driver's working hours For some route nodes, the time of arrival of the bus at the destination is set at the latest possible hour The problem can be solved if the output of the system includes the list of routes and the numbers of all buses running on a given route, the time each bus starts its trip, the type of rolling stock, and the values of the dynamic coefficient of capacity utilization. Simultaneously, information is furnished on the bus schedule. If the above-listed assumptions and constraints are taken into account, the choice of the route network, the assignment of the buses to their respec- tive routes and the selection of the suitable type of rolling stock hermit rationalizing the network and optimalizing the rolling stock. For practical Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 purposes, however, higher-order goals and a number of other constraints intro- duce certain changes at the expense of system properties. The above considerations formed the basis of an algorithm which, upon changes in the solution of the problem, forms a new network of routes, selects a suitable type of rolling stock adapted to the new conditions, and calculates the dynamic coefficients of bus capacity utilization. Should the results prove to be unsatisfactory, this algorithm makes it possible to change the initial conditions and perform the next step of iteration until acceptable results are obtained. Another class of problems aimed at obtaining optimal solutions arises when one considers the possibility that one and the same bus makes several trips. In this case, the number of vehicles for a given network of routes may be minimized. One and the same bus may make two trips provided the following conditions are satisfied: The end point of one trip serves as the starting point of the other The time of completion of the first trip coincides with the starting time of the second one (allowing the stop) for the duration of the bus stay at The overall duration of the two-step operation does not exceed the maximum working hours of the driver (crew) These conditions lead to mathematical minimization problems which can he solved by known methods. The bus traffic plan also includes a problem of assigning routes to the various motor pools, the advisability of having each motor pool cater to a specified route depending on the pretrip and posttrip expenses as well as on the technological capability of a given motor pool. The expenses on a zero run and on the maintenance of a bus at the starting point of the trip outside Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 the motor pool territory (overnight trip) may serve as a criterion for de- ciding whether or not to assign a given route to a given motor pool. All the other conditions constitute constraints. The solution to this problem yields a list of fixed routes for each motor pool and a matching rolling stock structure. Thus, the problem of organizing interurban bus services is solved by heuristic modeling techniques involving a certain hierarchy of subproblems, whereby the solution for each subproblem is obtained by descending from optimization to suboptimization or approximate solutions. After the bus service plan has been compiled, a need arises to determine the economics of the bus operation. Suitable technical-economic indicators characterizing the bus operation may be obtained for each route and for each motor pool on the basis of the bus schedules, the plans of rolling stock assignments to routes, and routes to motor pools. Aggregation of the route plan indicators by the hierarchical levels of the Ministry of Motor Transport allows for planning passenger traffic for the whole industry in technical and economic terms and objectively enough. It is further envisaged that branch plans will he coordinated with the national economic plans through automatic plan information exchange between the Ministry of Motor Transport and the publican State Planning committee. The passenger motor transport system falls in the category of open-loop systems. To make it adaptable to the changing environment, a mechanism is required for disclosing deviations from the plan as well as suggesting and adopting decisions with a view to restoring the balance: i.e., meeting the transportation demand within the set plan targets. Thus, day-to-day traffic control problems must be dealt with. This system must perform the following functions: Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Determine the actual state of the system (accounting); Compare the actual state against the plan and pinpoint all deviations (monitoring) Analyze the causes behind the deviations (analysis) Prepare decisions to adapt the system (prediction) Of the problems listed, the first three readily lend themselves to formalization and can be described by quantitative models, so that auto- mation presents no difficulties here. As for problem four, it belongs to the group of problems which can hardly be formalized. On this basis, when developing the first portion of the day-to-dav control system, the primary emphasis was on automating the accounting, monitoring, and analysis functions. At the present stage, accounting in the bus industry is done by use of three kinds of special documents, viz. driver's trip ticket, bus ticket record, and hooking-office record. These documents contain complete infor- mation describing the state of the object during one working day, so automatic processing of these data is essential if the accounting problem is to be solved successfully. Currently, the Ministry of Motor Transport is in the process of developing an integrated system for processing the data of trans- port documents, which, when completed, will register and record the indi- cators characterizing the operation of all kinds of motor transport. This system will actually mark the emergence of a data bank to cover the entire sphere of motor transport operation. The same system will also permit monitoring the state of any object; i.e., checking the actual data against the planned figures and revealing deviations. Rearing in mind the multilevel structure of the passenger transport control hierarchy in the Ministry of Motor Transport, effective control requires that each level be supplied with enough information and within a time 1~~R I~ a b1i i e -fFtb~f~- 6 0 21 of the control system.  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 310; To meet this requirement, the system is broken down into hierarchical levels, each having its own list of indicators, sensitivity threshold (the least deviation to which a given level should respond) and schedule of data delivery. Each higher level differs from the one immediately below by an extended list of indicators, a lower sensitivity threshold, and longer in- tervals of data delivery. Analysis indicates that quantification of the above components is a formidable task, what with the heuristic nature of the process and the utter impossibility of formalizing the decision formulation and adoption procedures. Hence, the quantitative values of the system components which represent its state were arrived at by means of expert assessment. However, to satisfy the demands of a great number of consumers and make the system quickly adaptable to the individual requirements of managers, the system has a built-in capability of furnishing additional information on demand (a list of questions worked out in advance). Eventually the system will permit a real-time man-machine dialog. Alongside data on the state of the object, the day-to-day control system must furnish information on the causes of deviation from the planned target figures and also provide initial data for subsequent planning needs. To meet these requirements, special data analysis programs are being developed on the basis of a list of standard causative factors which disrupt the functioning of the system. With all the elements of the system operating on the basis of the same data, the same software and hardware, we are sure we will be able to arovide effective planning and control of the passenger motor transport operation. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 CIA-RDP79-00798A000200020005-9 AUTOMATION OF BOOKING AND RESERVATION OPERATIONS ON SOVIET RAILROADS B. E. Marchuk It is common practice nowadays to book train tickets in advance through reservation bureaus, transportation and travel agencies, etc. Acceptance and registration of reservation orders are rather complicated and important procedures. Aside from the sheer number of such orders (hundreds of thousands every day), they come following a highly random pattern, while would-be passengers present extremely diverse demands. The advance booking system, which leans on a train seat file, does indeed facilitate the booking operation; yet, it falls short of the main objective, viz. high-speed, high-level service. A typical seat file is found in a special bureau, or in a so-called reser- vation center which receives telephone requests from personnel manning hooking offices and direct calls from passengers. Under such a reservation system, one dispatcher of the reservation bureau is able to cater to some five permanently operating hooking offices. But with a large number of booking offices, this system of dispatcher-con- trolled operation becomes overcomplicated and all but unwieldy: the number of dispatchers grows proportionately to the number of booking offices; the time of operation gets longer as dispatchers have to queue up if one and the same card is required by several people; finally, longer time is needed for the booking clerk to get through to the dispatcher. A variety of steps have been taken to improve the dispatcher-control system and thus streamline the train reservation service, but all of them have fallen short of their objective and failed to justify the expenses. The Laboratory Chief of All-Union Scientific Research Instutute of Dept. 4pqQA*Eg# It 2QQt1I1&(19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 trouble is that the gain in processing time is disproportionately small if the approach consists in simply beefing up the reservation Personnel or in- creasing the amount of equipment. There are certain limits to such growth which are rooted in technological, economic, and biological factors, so that at a certain stage of dispatcher system growth the quality of service starts deteriorating: the seat-occupancy rate drops; the newly emergent drawbacks of the system detract from the pas- senger satisfaction level; the response of the system to ticket cancellation lengthens. This trend is particularly pronounced where the total number of hooking workers reaches the 310 to 500 mark. Hence, a need arose to develop automatic booking systems free from the above-listed disadvantages and capable of effecting a major improvement in the booking procedure. Past experience suggests that at an annual passenger turnover of up to four million the manual dispatcher booking system is sufficiently effective, but passenger volumes above 10 or 12 million per annum absolutely warrant a switchover to automatic booking. Automatic booking systems using computers, data transmission facilities, and booking office terminals, provide for automatic collection and Processing of all information inputs from travel agencies and hooking centers. Such svstems may be of two types: for simple hooking, and for the entire scope of booking operations, including automatic sale of all forms of travel documents. Systems of the latter kind, though 5 to 10 percent more expensive, are far more economical, since they operate on the basis of much more extensive passenger traffic information and thus can handle all aspects of the booking operation. The advantages of such a system more than outweigh the extra cost involved. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 At present, automatic reservation systems are employed in the railway networks of Japan, Germany, Spain, Italy, France, Denmark and Canada. Of these, the most comprehensive system is Japan's MARS-ins with a capacity of up to a million tickets a day and the capability of catering to some 1,500 booking offices. Since 1972 the Soviet railways have also had the benefit of an automatic booking system called the "Express" which is superior to the volume of operation to any of its European counterparts. However, automation of hooking operations is a far more formidable challenge in the Soviet Union than in Europe considering the large volume of passenger traffic and the much greater railway mileage involved. The automatic control system "Express" is intended to automate the whole range of booking operations associated with the processes of reserving seats on trains, keeping a check on the seats on long-distance trains, and selling various kinds of travel documents. "Express" is a large computerized control system operating in real time and designed to offer service to a great number of passengers. Analysis shows that in terms of labor consumption the procedures in- volved in the bookine operation are ranked as follows: ticket registration and documentation of sold tickets with a breakdown by individual bookinQ- clerks, 65%; registration of vacant seats and apportioning them among the booking offices, 20%; and accounting, 15%. It follows that primary emphasis should be on facilitating the booking clerks' job. Thus, the "Express" automatic control system executes the following functions: (a) checking the vacant seats and furnishing them in response to booking clerks' requests; (b) informing passengers and hooking clerks alike as to the availability of vacant seats on trains; (c) determining Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 the size of the fare; (d) compiling and printing out the various travel and auxiliary documents; (e) computing the amount of money from the sale of tickets and other documents for the whole network of booking offices and for each booking office taken separately; and (f) carrying out all forms of statistical and financial accounting relating to passenger transportation. Structurally, the system is composed of three elements: (a) a computer center, which is an information storage and processing facility; (h) peripheral (terminal) equipment comprising booking devices and information displays, which are installed at the booking offices; and (c) switchgear and data-transmission equipment linking the computer center with the data terminal equipment. The computer center is a multiprocessor system made up of three inter- changeable computers which control all phases of the booking operation at the various booking points (terminal offices, agencies, railway stations within the city, central reservation bureaus, etc.). Resides, the same computers check and perform statistical reduction of the data on the sale, cancellation, and reservation of train tickets. The computers further compile statistical and running accounts on the utilization of the rolling stock, on the volume of ticket sale for each booking office as a whole and for each clerk in the office, etc. Normally, two of the three computers function in a synchronous duplex mode, carrying out real time processing of the inquiries arriving from the booking-clerks and inquiry devices, while the third computer is in hot reserve, executing statistical accounting functions. The computer center is so structured as to ensure that the system will continue to function normally even if any two of the three computers fail. The computer center capacity is 200,000 seat orders in 300 trains per day (calculated on the aroung-the-clock basis), with a reservation period of ten days for one-way tickets and forty-five days for return tickets. For people Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 who wish to reserve tickets long periods (up to two months) in advance, there is an option of acquiring special "Passeord" coupons which guarantee a seat on the train, but the actual tickets (without seat indication) are issued any time before the train's departure. The booking equipment is designed as an aid to booking clerks and,as such, is installed directly in the booking offices. This set of equipment comprises what is known as booking clerk manipulators (BCM), each consisting of a clerk's console, a ticket printer, and a control device. One BCM can be used by two booking clerks simultaneously. The clerk's console is built around a full-size keyboard which permits cutting down the time required to set an order and minimizing the error rate. The console is also easy to master and can he readily switched from one function to another depending on where it is installed. The information on an order being executed may be sequenced as the booking clerk sees fit. This information set includes the following data; point of departure (terminal or station); destination (route); the train number and the type of car which the passenger prefers; the kinds of docu- ments ordered and their quantity; the passenger's privileges, if any; the passenger's requirements to the seat layout; and the type of order (order, cancellation, group order, report, response to an inquiry, invalidation of a wrong document, etc.). If necessary, it is possible to fulfill an order for a specific seat in a specific car. Booking equipment, depending on the type of job, may be installed both in regular booking offices and in specialized booking offices which do not provide face-to-face service to passengers, such as telephone- and mail-order booking offices; offices invalidating the fares connected with wrong docu- ments issued by hooking offices; offices reserving seats on requests from other citis d passing information on vacancies down the train route. Approved or elease 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Regular hooking offices, which sell and cancel tickets, may be of any kind, from all purpose to narrowly specialized ones. In principle, each booking office could sell and cancel tickets for any train and for any date. The total time it takes the booking clerk to issue two travel documents is not greater than one minute. The maximum daily capacity of a single booking office (with due regard for shift rotation of the personnel) may be as high as 1,500 to 2,n00 travel documents. The ticket printers automatically prepare travel documents on the basis of a unitized letterpress printed form, all travel document forms being letterpress numbered and rigorously accounted for. As a form is fed into the ticket printer, the latter fills in the requisite information obtained from the computer center of the system. The first line of the document pro- duced by the system always contains its name: ticket, pass, children's ticket, excess fare, excess fare to the children's ticket, excess fare to the pass, ticket paid for by written order (check), or servicemen's ticket. If the form is used as an auxiliary document, the first line also carries its name: report, hoarding ticket, disembarkation information, etc. The second and third lines are filled, in with the names of the points of departure and destination, respectively. If the travel document is a return-ticket, the station names change places. The fourth line carries digital information (in decimal characters): the number of the hooking office that has issued the travel document, the number of the tariff zone of the destination, the time of train departure, the train number, the train category, the car number, the seat number, the ticket price, the document code indicating how the document has been acquired and showing that the advance booking surcharge has been collected. For passengers planning a chance of train en route, the upper right- hand comb i L ~Q~1~~+~1~aR-t~e~ gt7$t4~i ~&4@fd0@AZOa@5 nger is  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 supposed to pass on the way. The fare is determined by the system auto- matically on the basis of the points of departure and destination entered into the system by the booking clerk at his console. Information-inquiry devices exist in several versions: seat availa- bility display boards and information devices for passengers and passenger service personnel. The display board consists of a booking hall board (BHB) and a booking clerk display board (BCDB). The BfBs are to be installed in a prominent position in the large halls of hooking offices to inform the passengers as to seat availability. The left-hand portion of each BHB carries permanent information representing the train schedule, while the right-hand side is variable and automatically shows the seat availability picture for each train on the first, second, third, fourth, and fifth day prior to departure. The seat status information for each day is broken down into six categories. The display board is linked with the computer center automatically, so that the information is constantly updated as tickets are bought. Every new day, the information is automatically shifted to the left by the space of one day. A single board is capable of providing information on sixty-three trains. Booking clerk display boards (BCDB) are installed in the booking clerk booths, enabling the clerk to scan all trains at once for available seats in one of the six categories. The BCDB displays the numbers of all trains which have vacant seats of the category required. The information-inquiry device is built around a typical ticket printer, differing from the latter only by a simplified manipulator console design and a more versatile printer. The data-transmission equipment (DTE) may use half-duplex two- or four-wire switching or nonswitching telephone channels, transmission being c p a a seed f 1,200/600 baud. DTE provides communication links c fuv eu r ortRelease 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 between the computer center and booking offices as well as between computer centers over distances of up to 5,000 km. The system features thirty-two intercommunication channels and ninety-six channels for communication with the peripheral equipment. The maximum carrying capacity of a single channel is two orders ner second. when the "Express" systems intercommunicate, they share their terminal equipment, for the accessing booking clerk to indicate the number of the particular system he wants. Thus, the hookinc clerk has access to all the systems and is accordingly capable of procuring seats at all railways. In this case the computer centers which handle the booking clerk's demand operate as information switchboards, storing the data transmitted. Special switchgear is used to switch demands at the terminal locations. The experience with the above-described system in the Moscow Junction suggests the following conclusions: 1. The booking clerks' productivity can he boosted twofold or even threefold. 2. The booking clerk's duties are largely simplified as the automatic system disrenses with the need to calculate the fare and fill in the travel document forms; nor is it necessary to compile a lengthy - report on the travel documents sold, since it is printed out auto- matically. Under the new conditions, the booking clerk actually becomes an operator who hears a passenger's demand, inputs it into the machine and receives the travel documents printed out by the system. 3. Booking clerks can be trained to work with the system within a short time (one week). The average error rate for booking clerks thus trained is three to four percent. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 385 4. The system marks a dramatic improvement in the quality of service offered to the passengers who are now able to book reservations at any hooking office (irrespective of its location), for any direction of travel, and not only personally but also by mail and by telephone. Furthermore, passengers are kept constantly informed about seat availability through information devices. 5. The system raises the cost effectiveness of passenger service through (a) a higher occupancy rate; (h) a more effective utilization of seats as trains move along their routes; and (c) prompt action on the cancellation or use of additional cars or trains judging by the .occupancy information (supplied as the tickets are being sold). 6. The system permits improving the quality of plannine and evaluating passenger flows on the basis of relevant statistical reports. According to foreign railways and air carriers, automatic reservation systems conduce to a five to ten percent improvement in the occupancy rate, while the investments into such systems are recouped within three to four years through the cost reduction made possible by higher occupancy rates and boosted profits from advance reservation. Under current plans, Soviet railways are going; to be equipped at the first stage with separate automatic systems to cater to a specified track mileage. As these systems progressively come on line, they will be linked by automatic communication lines, so that eventually all the systems will evolve as a single multicomputer entity with enough scone to cover the entire rail- way network of the Soviet Union. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 THE SIREN SYSTEM: A NATIONWIDE AUTOMATIC CONTROL SYSTEM FOR BOOKING AND RESERVING SEATS ON DOMESTIC AIRLINES V.A. 7hozhik.ashvili et al. Airline booking and reservation is a typical mass service process of a high degree of complexity steeminp from the high frequency of flights and the extremely variable conditions, including the highly fickle weather situ- ation. That is the reason why air carriers were among the first to employ real-time computerized teleprocessing systems and to have achieved the greatest successes in this field. Experience of U.S. and European air carriers with systems of this sort suggests that they are instrumental in atemmin? the tide of personnel ex- pansion, which would otherwise swamp all companies, and in achieving a higher seat occupancy rate on the planes. Aeroflot differs from most of its foreign counterparts in that it carries out domestic operations on an enormous scale. Thus, the annual passenger turnover is currently approaching the 100 million mark and shows no sign of pace slackening. The booking procedure for domestic flights radically differs from the international booking operation. Domestic flights have long been a common- place occurrence, so that it is paramount to relieve the passengers of ex- cessive formalities and make the booking procedure a fast and simple operation. The passenger must be able to book a seat on the plane at any time prior to the takeoff. To achieve this goal, the booking operation must turn into a simple and fast procedure. Besides, domestic flights are far cheaper than international flights. The Aeroflot domestic rates are below Chief Constructor of the Automated System, Main Computing Center, Ueflppteeed Rdr FMddsdk1Wt*W19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 387 those used by most other carriers. Hence, the automatic system should not be overly expensive, calling for a thorough analysis of the various services in economic terms and for a no-frills plan. These considerations have been taken into account in full measure while developing the Siren system, a unique system in its own right. The agent-system interaction procedure is extremely simple and fast. In most cases the agent has to access the system only once or twice to cater to each passenger. Tickets are by and large printed out automatically. If need he, the system may automatically print out several tickets, requiring no additional accessing. The response of the system lies in the range from 1.5 to 3 seconds, while the ticket printing operation takes 5 seconds. Therefore, to take care of a passenger, all the agent needs to do is to receive a demand and the payment, which rarely takes more than one or two minutes. At this rate, around 20,000 passengers can buy tickets in one hour. These principles built into the Siren system are going to he extensively used in the nationwide system, too. The latter system is designed for a capacity of 200 million passengers per annum. No other system in the world can boast such a capacity. The-nationwide system is made up of several zonal subsystems covering the entire territory of the county. The zonal subsystems include the agencies and airports which territorially fall within each zone. In terms of function, the zonal subsystems are identical and have the same type of configuration. The data processing centers (1PC) are interconnected and linked with their component units by means of a communication network, so that together they form a single system. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The Aeroflot nationwide system was conceived as a single system in the full sense of the word. The centers and zonal subsystems are not going to compete for passengers, but will rather strive for a common goal for the good of a single carrier. While mapping a complicated route involving changes or while searching for an optimal growth strategy, the subsystem centers will view one another as members of the same family pursuing common objectives, rather than as competing or even cooperating companies. This will certainly be reflected in the ways user programs will he executed. Furthermore, there will be an additional task of optimizing the system as a whole, rendering the Aeroflot system different in essence from the totality of systems run by different carriers. In technical terms, the system will widely use minicomputers for small centers, alongside huge machines that will be installed in major centers. The first system, the groundwork of the forthcoming nationwide system, has been in operation since April 1972. It is the above-mentioned Siren which controls over 500 flights from the Moscow airports daily and affords fast and equal access to the seats on these flights for 250 agents in Moscow and another forty-two cities of the country (figure 1). Designed for a daily capacity of 50,000 seats, the Siren is one of the largest systems in the world in terms of capacity. In 1972, the Siren gave service to 2 million passengers; in 1973, 4 million; in 1974, 6 million; and the expected figure for 1975 was in the vicinity of 8 to 9 million. Thanks to this system, all operations are now executed much faster and the productivity of the agents has been raised severalfold, largely adding to the passenger satisfaction index and thereby boosting the traffic volume. Upon introduction of the Siren, the seat occupancy rate started to grow Ap~~o~# ~' - I efebs%'Hb1r11A',usCt TRW P~9 00798A000200of the 02 005 9oportion of  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200016805-9 c Jo~ Approved For . e1e 1 /1 CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 booked seats on the system-controlled flights, while curve 2 presents a similar picture for the uncontrolled flights. The figure clearly shows that the controlled flights definitely have an edge on the flights operating outside the system. The relative magnitude of this edge is shown in figure 2-b. It is expected that in 1975 it will reach approximately 89%. (The dash lines in the diagrams represent predictions; Ikb means first quarter). The Siren is built around an integrated system of technical facilities, all made in the USSR., which include a highly automated data processing center, data transmission equipment and a large number of display terminals. The system uses a special language for man-machine dialogue and an operating system controlling real-time multiprogram operations. The Siren is a means of automating a number of services, booking operations, and monitoring the activities of the passenger service personnel. The need for such an automatic system stems from the fact that the old methods of booking and reservation as well as the techniques for controlling these processes run increasingly counter to the mass traffic requirements in a situation characterized by fast growth of the airline network, larger passenger aircraft, higher speeds, and increasingly hectic pace in the activities of airports and agencies. Thus, prior to the introduction of the Siren, the files of the Main Air Traffic Agency run by the Ministry of Civil Aviation contained up to half a million seat cards which were accessible to over 250 booking clerks, dispatchers of the transit services of the Moscow airports, and personnel of the reservation bureaus and agencies located outside Moscow. Every day up to 8 to 10 thousand seats were booked by cable. In spite of the regularly increasing staff handling the booking demands, the booking clerks had to wait for an average of thirty seconds to one minute, and as often as not up to ten or fifteen minutes, which caused Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 CIA-RDP79-00798A0002000200e%19 ,4 b" 040 Ais 1-94.9. 1970 1911-1FT2 1913 1'9T~r / i " ~oo~sio3 - - 7 ~K ~,(~~! c7wya, Figure 2a  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 queueing and complaints. The cable demands from other locations for seats for transit passengers were dealt with only the next day. Curing one shift in Moscow, several tens of thousands of telephone demands would be handled. The hectic pace, the often poor audibility, the inevitable blunting of attention under conditions of incessant monotonous calls, the swarms of people manually writing down short (five to six digits) notes, all added up to errors detracting from the quality of the service and causing much damage. Naturally, execution of orders and monitoring of the personnel's work were all but impossible. The Siren system automated to a maximum possible degree the most typical operations, furnished the booking clerks and dispatchers with diverse and accurate information and thus made it possible to more than double the booking speed. As a result, the quality of the service was raised considerably and sizeable saving of social time was achieved. The heart of the Siren is a data processing center (DPC) (figure 3). It is composed of two computer centers with accessory devices whereby the two computers can operate jointly, and special devices interfacing the computer facilities with communication channels. Each computer is equipped with a processor, memory units, input-output devices, and standby facilities. .The DPC memory (both computers) stores all information necessary for the system to perform its technical functions: data on schedules, rates, tariff distances, aircraft seat mock-ups and the sequence in which they are booked, and restrictions connected with traffic rules. The system functions are backed up by a software support system made up of a great number of programs. A specially developed real-time operating system provides for the operation of the DPC in a variety of modes, communication with the many data transmission channels, and response to emergency situations. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-3 L___. - Figure 3: 1 - Mainframe memor (1 reserve) 2 - Processor 3 - Interprocessor link via interface 1R 4 - Input-output channels (1-reserve) 5 - Input/output device 6 - Control devices 7 - Distribution-conversion complex 8 - Magnetic-tape memory unit (2-reserve) 9 - Magnetic-drum memory unit 8 mechanisms (4-reserve) 10 - communication lines Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 ti  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The chief operating mode of the DPC is duplex operation whereby each request is processed by both computers, the results are compared and issued to the caller in case of complete coincidence of the two sets of results. Should there be a failure of any device, the computer center in which the failure has occurred is automatically switched off, and the system switches into a simplex mode while the DPC operator is notified about the cause of the failure. After the fault has been eliminated, the system reverts to the duplex mode, the switchovers from one mode to the other in no way affecting the processing operation. The particular configuration of the DPC which involves two independent computer centers capable of functioning both jointly and separately, is an important factor contributing to the realiability of the system as a whole. To the same end, all principal DPC devices have built-in reserve capability and there are special programs for speedy faultfinding. Thanks to all these facilities, the DPC has a high level of reliability. Special measures have been taken to protect information. Apart from protection programs, the system uses magnetic drums which continuously record the information status in real time, as well as any change caused by booking, cancellation, or any other operation. This information can be used.to restore the system. The information stored on magnetic drums is updated by the results of each individual access. Operating experience indicates that at the present level of reliability, the duplex mode is redundant and one of the two computers may be employed to solve concomitant problems in a batch mode. The main technological unit of the Siren system which provides for man-machine interaction, is a console. The operator's dialog with the system is effected by use of a keyboard dd c~tT ai l hi 1, shows the Approved For Release 2001/11/19: CIA-RDP79-60798AO ah8Z22OD5=-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 text of the operator's call and then the information furnished by the DPC in response to the call. The console has a built-in printer for documenting the most important data obtained by the operator. The booking offices covered by the system are equipped with printers for making out tickets. The Siren consoles are installed in the subdivisions of the Ministry of Civil Aviation Main Agency in Moscow, at the airports of the Moscow area, in some communities in the Moscow region, as well as in the air travel agencies of another forty-two cities of the country. The consoles may perform different functions depending on the particular task with which given subdivisions are charged. In terms of functions, the Siren system can be subdivided into the following technological units: Department of short-term planning of commercial flight loads (for flights taking off from Moscow), which includes a day-to-day system control center. The airports of Moscow are equipped with consoles; using these the control center dispatchers execute similar functions, and the system with information about the newly vacant seats immediately prior to flights, and obtain data on the booking operation for transmission to the computer center. Most of the available consoles are installed in the booking offices which cater to passengers who wish to buy tickets in person. A reservation office has been set up to take care of passengers who make telephone bookings. This office interacts with the system via its consoles and delivers the tickets to the passengers by messenger or else issues them in a special booking outlet at the passengers' convenience. Certain booking clerks, transit dispatchers at the Moscow airports, reservation agents, and some other workers cannot interact with the Siren system since consoles are not available to everybody. To enable the group Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 to have access to the system, the personnel of the commercial flight loads division receive telephone calls from them, pass the calls to the system, and transmit the answers to the callers by telephone. Special mention should be made of a large group of consoles installed in over forty agencies located outside Moscow. Passengers in these communi- ties are able to book seats on flights involving a change in Moscow. It would be erroneous to assume that the range of the Siren is unlimited by the locations of its consoles. The out-of-Moscow agencies connected to the Siren form their own networks of agencies of sorts in their vicinity, which book the seats on the system-controlled flights through the medium of said agencies with which they keep contact by cable or telephone. Thus, for instance, the consoles of the Pyatigorsk agency cater to all the booking points of the Mineral'nye Vody resort area and the other booking offices in its zone. Similarly, the Alma-Ata agency uses the Siren to hook passengers from all cities of Kazakhstan and even some cities outside that republic on flights which involve a change in Moscow. The number of cities thus covered by the system directly or indirectly is well over 400, their network encom- passing practically the entire territory of the Soviet Union. The system contains mock-ups of aircraft with fifty different seat lay- outs, The seats are sold in two different sequences depending on the type of aircraft, from the front row to the last one or the other way around. However, the system can also accommodate passengers claiming specific seats. With the information completely centralized and the system operating very fast, the system operators, wherever they may be, enjoy practically simultaneous and unlimited access to all data. Thus, a seat cancelled, say, in Magadan in the far east of the country, may be sold within seconds in Leningrad. It takes from 1.5 to 3 seconds for the answer to come through a telephone channel and 20 to 25 seconds by cable. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 397 The Siren includes an information display showing the situation with seat availability for the next seven days. The display incorporates an automatic calendar and a system-controlled vacant seat indicator. This dis- play is installed on the airport premises in plain view of the passengers. An important place in the Siren system is occupied by the communication network which links the numerous users with the data processing center. Information is transmitted over standard unswitched telephone and telegraph channels. In order to improve the reliability of the data communication network, use is made of accessory devices, viz, data transmission facilities whose functions include encoding, transmitting, decoding and checking the information being transmitted for correctness. Console switches, employed in those cases where more than one console is installed, contribute to the effective use of the communication channels. One console switch using one or two communication channels can cater to eight to sixteen consoles. The system may perform many different functions, such as issuing or cancelling seats and selling tickets; furnishing, information about the schedule, seat availability, number of vacant seats on a particular flight, changes in the schedules, etc. A number of functions of the system are executed requiring no operator's request: calculation of the total rate if a group of passengers requires service; offering the next flight which has the required number of seats; making up records; compiling statistics of, say, unsatisfied demand. The bulk of requests are concerned with booking. If the operation is ticket selling, the information fed from the Data Processing Center to the console has the format of a ticket and in the course of printing all the blanks of the form are precisely filled in with the names a*ftwe*tFxrdkleamd2f 'ttMdt.9ai(3 7sl07 Ai 11t011AObwC105* date and  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 time of departure, and the rate of payment. The tickets may be sold at a full rate or at a discount (school children, university students, etc.). In the latter case, the system checks whether the particular grade of privilege corresponds to the rate of discount, reminds about the time for booking; if several seats are requested, the system furnishes the overall rate with due regard to the size of discount for each passenger. The seat issuing operation is executed in those cases where the passenger holds a paid transit or return ticket without a fixed data. While executing both operations, if the required flight does not offer the needed number of seats, the system automatically retrieves the two closest flights (prior to, and after, the flight in question) which have the number of seats as requested. The system indicates the number of seats available on the flight requested and furnishes all information relating to the two alternatives offered. Thus, the operator is able to help the passenger in choosing the most convenient flight. The cancelled seats may be returned to the system. The operator can also use the seat inquiry request to obtain infor- mation on seat availability on a particular flight as well as the schedule and rate data. If the seats are unavailable, the system again offers two closest flights. If the passenger has not named the desired flight, but only the desired time of departure, a schedule inquiry is in order., In response to this request the system gives information on several flights in the same direction, the data being sequenced in a chronological order, as well as data on the flight numbers, the airports of departure, the times of departure, and the number of vacant seats on each flight. The package further contains the data on the rate, the day of the week which falls on the date given, and the time of inquiry. In case there are many suitable flights, the inquiry may be narrowed to a certain time interval. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 On the operator's demand, the system sums up his activity for the shift or for any time of day, indicating the number of booking operations, seats issued and cancelled, and the receipts. The dispatchers of the control center run the system through control requests, such as temporary change of schedule for one or several days or permanent schedule change, introduction of a new flight, cancellation of a flight, temporary ban or removal of ban on ticket sales, increase or decrease in the number of seats, substitution of one type of aircraft for another, and the like. Besides, the dispatcher may request information on the passenger load on any flight, the number of flights in any one direction for which all the seats were sold out, the results of work of any operator or all operators, any subdivision or the whole system, the latter document indicating the number of seats sold as of the time of inquiry, the number of documents issued by the system, the number of operators employed in the system, etc. All these operations are executed in real time. The system operators' work is monitored by use of the daily records issued by the system. This document outlines all operations carried out during the day, each operation being entered in the record under the number corresponding to that on the document printed out by the operator and with the time of execution indicated. The records contain information on the type of each operation, the flight number, the date, the seat number, the rate, the kind of discount, and the commission. If the operation was executed outside Moscow, the records will show the date of flight number of the passenger's arrival in Moscow. Taking into account shift rotation, the Siren system employs over 700 operators, many of whom are located thousands of miles away from Moscow. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 With this number, a constant flux of employees is inevitable, which places particular emphasis on the ease of trainine, on the one hand, and on the foolnroofing of the system, on the other. These considerations were allowed for by the system designers. Information exchance between the operator and the system proceeds in a comprehensible language; the names of cities and many communications are printed out in full; the abbreviations used need no special conversion tables to he understood. The system contains information on a special instruction flight which can be used to train operators on the job. If the operator does make a mistake, requests information on a non- existent flight, misses some element, or uses a wrong sequence of elements in the set, the input vetting program will block such a request. The screen will display the text of the erroneous request and indicate the nature of the error. Thus, not only is erroneous information barred from the system, but the operator is assisted in locating and easily correcting his mistake. The system, in effect, trains the onerators. Over the period of pilot-scale operation, the system has been enriched with almost forty new programs and changes in the old programs aimed at im- proving the quality of the service, raising the efficiency and reliability of the system, and facilitating the operators' job. All these changes were effected without shutting down the system. In 1974, daily control centers were set up at the Moscow airports, marking a new stage in the system development plan. These centers permit tickets to be sold practically until the very takeoff, the seats vacated by passengers switching to earlier flights to he entered into the system, and additional seats to be entered into the system if a flight is executed by a plane with a larger number of seats than envisaged by the schedule. Thanks to these centers, the occupancy rate is bound to rise still higher. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The above-listed advantages of the system can be enjoyed not only by the hooking offices of Moscow. The benefits of the system are even more tellin' in the eyes of the passengers chancing flights in Moscow. It must be admitted that the traditional reservation system for transit passengers falls far short of meeting the Passengers' requirements. Transmission of cabled requests, processinj of cables at the post centers, the booking pro- cedure proper--all take a lot of time, so much so that passengers are able to acquire a transit hooking with a confirmed reservation the next day at the earliest, and not infrequently on the third or fourth day. But the Siren revolutionized the entire transit booking business. Now an efficient service, equivalent to that offered to passengers booking tickets in the booking offices of Moscow, is available to thousands of nassengers in many cities who fly via Moscow. The operator sitting at a console connected with the data processing center by an ordinary cable link receives information from Moscow within twenty to twenty-five seconds; the information for non-Mus- covites is as convenient as that provided to the capital inhabitants. Of course, this modern form of service is in a different class from the traditional cable hooking operation. Initially, the plans envisaged that the Siren would cater to twenty-eight cities. However, already today their number has passed the forty mark, and the process of expansion of the system will continue. It is not in the least accidental that the passenger community has hailed the Siren with enthusiasm: in 1973 the number of bookings from out- of-Moscow agencies increased from 65,000 to 593,000 as against 1972: and in 1974 the volume of bookings skyrocketed by almost three times. It has been mentioned that the Siren is a man-machine system in which the human operator plays a very important role. The Siren or any other Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 comparable system calls for an intensive training program (740 operators were trained in Moscow and in other cities), but also for a drastic recon- struction of the organizational pattern, new technology in all segments of the service, new instructions, and new manuals. In one year, i.e., from May 1972 to April 1973, the Siren gave an economic effect amounting to 3,120,000 rubles, primarily through a higher occupancy rate. The savings of social time constituted about 3 million hours within the same year. The system of moral and material incentives for the personnel has been revised, and new targets planned for the main a'ency. The automatic system also performs a major social function. The operators' condition has been dramatically improved. The booking clerks are now spared nervous breakdowns which earlier accompanied their attempts to place a call to the flight loading people, particularly when audibility was bad; they work much more calmly and smoothly. They can communicate calmly with the passengers and obtain fast and full answers to many questions that would otherwise cause difficulties! they no longer have to consult reference books or seek clarification by telephone. A dramatic cut has been achieved in the number of conflicts because of lack of seats on flights, since.the system immediately offers acceptable alternatives, and such an answer obviously meets with a far less adverse reaction on the part of the passenger. The passengers also feel much better because now they have to wait in line half the time they would spend under a manual hooking system, even during periods of peak demand. The situation has changed even more dramatically for the better in out- of-Moscow agencies equipped with consoles. Thus, while earlier passengers had to come at least twice to procure a seat on a flight passing through Mosco' now they ceive their tickets immediately. This affected in a major i4 proved or Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 403 way the structure of transit passenger flows: the number of passengers coming to Moscow on an "open" ticket, i.e., one containing no date of the next flight, has been cut down considerably. The vastly facilitated reser- vation procedure has boosted the number of neople who prefer to fly via Moscow, having previously reserved a seat on a specified outbound flight. As transit passengers reserve seats with a change in Moscow, they are immediately told the seat number, which relieves them from the duty of havine the ticket registered by the transit dispatcher and thus snares them the formerly unavoidable exhausting waits to obtain a seat on the next leg of their travel. This has also benefited the transit dispatchers of the Moscow airports. For all these reasons, the volume of passenger traffic has risen by a substantial margin. Thus, during the first ten months of 1974, the seat occupancy rate for the Moscow air junction rose by 3.1% as compared to the comparable period of the previous year, and amounted to three times the average figure for the rest of the Aeroflot units. The experience with the development and introduction of an automatic system for booking and reservation operations has proved beyond all doubt that systems of this type can find wide application as a means of automating many processes in the civil aviation field which are characterized by high speeds of execution and call for fast decisions within a limited time. Examples of such operations are as follows: daily control of airports, short-term crew planning, redistribution and mapping: of optimal routes for supplying spare parts to grounded planes, inquiry and information service, information flow control on a nationwide basis, and many others. Centralized storage of vast quantities of diverse and rapidly changing data, availability of this information at any point in time to any user who may be th a et?po"i 4fa a '0Sf~9/ e C~I~u S~PfS-007983A dQU20005 ,,)rage  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 and allocation in real time of limited resources (plane tickets, hotel rooms, hospital beds, tourist passes and the like) to hundreds of users, high reli- ability of information, high degree of automation of operations--all these factors testify to the enormous potential of teleautomatic mass service systems, such as the Siren, and not only in civil aviation, but in many other branches of the national economy as well. The large body of designers working with the Ministry of Instruments, Means of Automation and Control Systems, together with the experts of the Ministry of Civil Aviation, who designed and built the Siren, can be justly proud of a major achievement in developing an automatic mass-service real-time system with a unique information network, which links the remotest cities of the country with the central computer in Moscow. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9405 INFORMATION MODELING FOR MANAGING SOVIET MARITIMF. TRANSPORTATION * V. S. Bondarenko Goals and Methods of Modeling It is common knowledge that the control process is composed of the following elements: acquisition of initial data characterizing the status and behaviour of the object of control and of the environment; transmission of these data to a control facility: accumulation, storage, and analysis of the information thus received by the control facility; formulation of possible alternatives of control decisions: selection of the best decision for a given set of circumstances; and transmission of the latter decision to the object of control. Formulation and selection of control decisions are procedures which lend themselves to varying degrees of formalization, may or may not include optimization algorithms, and may or may not be computerized. However, what- ever the case may be, no control decision can be developed without initial information which is liable to vary widely in terms of composition, contents, acquisition intervals, and other parameters, the variation being due to both objective causes (different objects of control, different functional goals of the objects of control, different quality criteria and the like) and many subjective factors, including individual traits of the control facility managers and rank-and-file personnel. Since the real objects, their functional processes and control algorithms, are highly complex, a huge number of control alternatives and for practical purposes, an infinite number of information models can be suggested. Each information model features its own depth and degree of description of the object of control, its own mode of inputing data into the control system, and * Ada o ec For F eileaseen~e1r11 19 artmeR a7 07 ~-00 020 O 05-9 Chief 6 a n ompu ng p ea ans on  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 its own quantitative and qualitative parameters characterizinc* the control system's response to changes in the object of control and in the environment. In order to provide the most rational type of control systems combining high efficiency with favorable economics, it is paramount to analyze thoroughly and prove the all-round advantages of a suitable information input. . The comparative approach to the evaluation of various input systems and the fact that some of the possible alternatives simply cannot be realized, suggest that it may he helpful to try and simulate information processes. Information modeling in this context is viewed as an oranic component of the comprehensive control system model, on a par with economico-mathe- matical modeling of objects of control where problems of optimization, pre- diction, and analysis are involved. However, as distinct from economico-mathematical modeling. employed in highly developed control systems which are called upon to formalize the pro- cedures of optimal decision making and quantitative analysis of trends, cycles and future programs, information modeling is feasible in all kinds of control systems, including the most trivial computerized and noncomputerized data processin- systems. Information models can he broadly classified into two types: particular models characterizing some local or narrowly functional elements of the information input of real control systems, and generalized models which may be regarded as analogs of full inputs of real control systems. The matrix techniques of analyzing and synthesizing the information inputs of control systems, which are widely used in modern design institutions, can be successfully employed for constructing particular and generalized information models. Comparative technico-economic analysis of these models--particular and generalized alike--is a method for subsequently selecting decisii s most co ffornins to he goals and objectives of control. Approved For Release 001/11/'i9 : CrA-RIiP79-00798A0O0200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 The importance of information models rises as control systems develop, i.e., with the degree of their sophistication, resolving power and, naturally, cost. Objects of Simulation The information models of control systems should reflect, within certain limits of accuracy, the state and behaviour of the objects of control and of the environment, on the one hand; and the response of the control systems to the changes occurring in the objects of control and in the environment, on the other. The groups of indicators or information modules which define the state of the object of control and of the environment, present an important characteristic of the information input of any control system and, hence, must be among the primary parameters coming up for simulation study. The most efficient set of indicators is apparently one that is minimal but sufficient for describing the object of control and its environment in terms of formal and informal decision-making algorithms used in a given control system. But the algorithm structure, in its turn, depends on the available data base as well as on the scope of numerical methods and the technology. So, modeling of the set of indicators is closely associated with the economico-mathematical modeling of the object of control and decision-making processes. If all these models are viewed together, it is possible to select effectively the important characteristics of the object of control for regular measurement, registration, and inputting into the control system. The need and advisability of inputting into the system of a group of indicators characterizing the state of the object of control and of the environment depends on a number of other factors: Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 1. Forecast of changed requirements to the data base of the control system brought on by the evolution of the object of control and by the dynamics of its functions and control objectives 2. The technological capability of the available facilities for data acquisition, transmission, and processing as well as the prospects of their development 3. Economic considerations and, among other things, evaluation of the costs of increasing the amount of information inputted into the system against the effect due to the possible improvement of the quality of control In multilevel control systems, the number of hierarchical levels and the way information-computation tasks are allotted to them may affect the technical characteristics and the economics of the system. Consequently, information modeling may be set a goal of determining the most efficient indicators of information filtration and condensation as the data move from one hierarchical level to another. Since such indicators depend on the ability of each level to process information and make decisions, analysis of the various patterns of allotment of informational and computational tasks in the course of information modeling may lead to an efficient vertical structure of control facilities and the optimal information volumes to be processed on each level. The modes of inputting and processing of the starting data are important functions of real control systems, which by and large determine the infor- mation capacity and sensitivity of the systems. The frequency at which the on-line numerical values of the'parameters of the object of control and of the environment are registered and introduced into the system, is either determined by the control resolution (critical value of displacement) or else rey~~d~lasfiet~60lJa1@I~4-F2~Pf3~W?9E90909(J-xl~on  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9409 modeling, the mode of information registration and inputting is varied and each alternative evaluated in technical and economic terms in order to make a justified choice of an optimal or near-optimal "pulse" of the control system. To combat irregularities in the arrival and processing of information in the course of information modeling, the data are smoothed through varying the information density of the various groups of indicators during the week or the day, taking into account the effect of information delays on the per- formance of the control system. Modeling of data arrays and banks gives an idea about the structure and configuration of the data base which is most advantageous for a given control system. Bearing in mind that the data base is among the most crucial elements of modern control systems, the various configurations of the arrays making up the data bank as well as the various relationships between them are analyzed by comparing the costs of setting up and operating data banks against the current and predicted requirements of the control systems with a view to avoiding any reconstruction costs in the future and minimizing the direct and indirect expenditures. Any general decision offers some advantages as well as some disad- vantages-as against a totality of particular decisions. Hence the need to compare generalized data banks with specialized arrays before deciding which alternative to adopt. The technical parameters and the economics of a control system are known to depend on how successfully one evaluated the comparative advantages of slow and fast external memory units, determines the efficient balance between the volumes of initial data and the inter- mediate information package resulting from statistical generalization and smoothing (mean values, indices, characteristics of dynamic series and the like), and evaluates the various data configurations and relationships between Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 arrays.  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Summing up, one can assert that the goal of information modeling is to provide answers to the following questions: 1. What kind of information is needed for effective control? 2. What is the economic time frame of data acquisition, transmission and processing? 3. What are the requirements to the quality of information: complete- ness, reliability and timeliness? 4. How should the information input develop to match the evolution of the object of control and of the control system? An optimal data base for a control system may be put together by aggre- gating the partially optimized decisions on the composition of the set of information indicators, the allotment of informational and computational tasks to the various levels of the control hierarchy, the frequency with which information modules are entered into the system, the intervals at which control decisions are made, the success in smoothing irregularities in the system operation, as well as the composition and configuration of the data arrays and banks. Modeling Experience Information modeling is employed for developing an automatic system for controlling sea transport operations. In this system, the chief infor- mation elements are shipment orders and data characterizing the operation of ships, the situation on routes and in ports, as well as the international cargo and freight setup. An important role is also played by a constant flow of information on the cargo shipment capability, technical and operating characteristics of ships and ports, distances between world ports, freight and tariff rates, as well as other information of a technical and economic nature stored in the system. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9411 while designing the automatic control system, the indicators included in shipment orders, ship and port records, freightage documents, as well as all the other indicators contained by permanent and dynamic arrays, were selected by the results of an all-round analysis of appropriate information models. The models were obtained on the basis of currently available algorithms for optimizing control decisions, with due regard for the requirements and wishes of the managerial and rank-and-file personnel of the control bodies as well as for the recommendations of the designers of the functional sub- systems incorporated in the automatic control system under development. The structure of the functional subsystems was defined by the results of analysis of the activities carried out by the sea transport control bodies. It included: - a freight market analysis subsystem, which uses standard freightage reports as the input, and the results of analysis and forecasting of the freight market in its various parts by the kinds of cargo and by season as well as other freightage conditions as the output; 1. A subsystem for day-to-day accounting and analysis of the merchant marine and port operations. In this subsystem, the input is composed of daily reports of ships and ports, plans, schedules and timetables as well as various operating standards; whereas the output consists of reference and analytical material characterizing the state and dynamics of shipment operations and the data describing how the plans, schedules, and timetables are being fulfilled in terms of fleet operation and port work, and how the operating standards are being compiled with. 2. A statistics and bookkeeping subsystem, in which the input is built around statistical and bookkeeping reports of the shipping lines Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 and ports, while the output comprises analytical material charac- terizing the financial status of the merchant marine and its sub- divisions with a breakdown into periods and operations. 3. A subsystem of short-term planning of fleet and port operation. Its input includes the cargo owners' orders, operating standards, information on the freight market setup and on the times and places of the ships' fulfilling their obligations. The output of the sub- system consists of optimal draft plans of fleet utilization as well as the schedules and timetables of ship operation. 4. A subsystem of long-term planning of sea transport development. The input of this subsystem comprises the starting material for forecasting shipping operations and for producing economico-mathe- matical models of the optimal strategy of development and allocation of the sea transport resources. Its output consists of the recom- mendations on plan and design decisions. Alongside these principal subsystems, the sea transport control system being developed includes three back-up subsystems: technology monitoring subsystem, logistics subsystem, and personnel subsystem. Analysis of variants was found to be the simplest and most effective means of studying information models and selecting the best design decisions. The variants differed in the comprehensiveness of the information picture and in the degree to which they met the demands and wishes of the control personnel. A list of comvulsory indicators was compiled, which included all factors indispensable for making forecasts and plans of ship- ment, ship schedules, and other regular control decisions, as well as for systems analysis of the most important aspects of sea transport operations. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 413 Those indicators which are only needed from time to time and only in response to special requirements or to a disruption of the normal course of shipment, are considered as claimants to be included among the compulsory indicators in case statistical evaluation shows them to be needed frequently enough and economic assessment indicates that the benefits derived from their routine acquisition outweigh the added costs. The final selection of the claimant indicators was made on the basis of several criteria, the most important of which were control problems for which they were considered necessary, the frequency of their active use, and the costs involved in their acquisition, transmission, and storage. To determine the relative contributions of the indicators into the control process, use was made of questionnaires distributed among the designers of the functional subsystems and the control personnel. Also used were matrix and statistical methods of analysis. The results of this work went into a set of indicators made up of several different groups which were to be routinely inputted into the system. The frequency of inputting the various groups of indicators was worked out on the basis of economic considerations, taking into account the impact of the inputting intervals on the control system performance. Since direct relationships were impossible to obtain, the method used was expert assess- ment subsequently subjected to statistical evaluation. Where input data serve to obtain mean values, such as characteristics of a dynamic series, standards and the like, an additional factor was considered, viz. the stability of the mean values and the stability of the results of control problems derived on the basis of said mean values. The three-level structure of the control hierarchy (shipping line- agency-ministry) mandated a study into the quantity of information needed by all 1 vels to cope with their respective functions. Here situation Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 simulation and analysis of alternatives were used. As a result, decisions were made whereby the second and third control levels jointly served by the Main Computer Center were to be furnished with substantially smaller quantities of information than previously envisaged, and the information reaching these levels was to undergo special screening. All main information arrays were designed as generalized entities to cater simultaneously to many subsystems and many control problems. The standardized structure of the information arrays allows of a gradual switchover to a systematically organized data bank. Apart from a considerable economy of inputting and updating costs, such a data bank makes it possible to automate the programmed printing-out and displaying operations. Thus, the new demands are to be presented in a specially developed high-level language whose vocabulary is unambiguously interpreted by the standard program modules. The language vocabulary was composed of the names of standard arrays and their elements, and the trans- lation and editing procedures were tied in with information elements and formally described together with the latter, dramatically cutting down the programming time and improving the performance of the entire control system. Modeling Effect Information models are an effective means of evaluating different con- figurations of the control system data base and choosing a good decision before the stage of actual design, thus saving a lot of time and money when designing new, and reconstructing installed, control systems and-which is particularly important--affording a practicable way of optimizing control systems. Information alternatives are evaluated on the basis of the following factors: the amount of money spent on designing and introducing a given Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 system or its elements featuring given information characteristics; average annual costs of maintaining the system or its elements; and average annual costs of progressive modernization of the system or its elements. Unfortunately, the information models can be compared only on the basis of scant and unreliable initial data. Here the basic principles were as follows: 1. As the accuracy of the initial data decreases, the methods of com- parison and evaluation become rougher. 2. Particular decisions require more detailed calculation and more precise techniques of comparison. 3. If reliable initial data are lacking, it is mportant to obtain as many expert evaluations as possible. The results of evaluation of the effect of information modeling indicate that modernization costs are substantially lower than the overall costs of control system design operations, and modeling effects such savings that the modeling costs are recouped many times over within a few years of the system's operation. It is also clear that if the objects of control are to function efficiently, the inner structure of the control system must be optimized. Information modeling is not to be considered as an independent stage of design work. It must be carried out in the course of work on the draft in all cases where the control system being developed is complex enough to warrant a search for a priori rational design decisions. Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9  Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9 Approved For Release 2001/11/19 : CIA-RDP79-00798A000200020005-9