Fosgerau, Mogens and Small, Kenneth E. (2012): Hypercongestion in downtown metropolis. Forthcoming in: Journal of Urban Economics
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Abstract
Engineering studies demonstrate that traffic in dense downtown areas obeys a stable functional relationship between average speed and density, including a region of 'hypercongestion' where flow decreases with density. This situation can be described as queuing behind a bottleneck whose capacity declines when the queue is large. We combine such a variable-capacity bottleneck with Vickrey scheduling preferences for the special case where there are only two possible levels of capacity. Solving the model leads to several new insights, including that the marginal cost of adding a traveler is especially sensitive to the lowest level of capacity reached. We analyze an optimal toll, a coarse toll, and metering, showing substantial benefits from using these policies to eliminate the period of reduced capacity. Under hypercongestion, all of these policies can be designed so that travelers gain even without considering any toll revenues.
| Item Type: | MPRA Paper |
|---|---|
| Original Title: | Hypercongestion in downtown metropolis |
| Language: | English |
| Keywords: | hypercongestion; congestion; road pricing; |
| Subjects: | R - Urban, Rural, Regional, Real Estate, and Transportation Economics > R4 - Transportation Economics > R40 - General |
| Item ID: | 43411 |
| Depositing User: | Prof. Mogens Fosgerau |
| Date Deposited: | 24 Dec 2012 17:06 |
| Last Modified: | 29 Sep 2019 04:34 |
| References: | Arnott, R. (2011) A Bathtub Model of Traffic Congestion Working Paper . Arnott, R., de Palma, A. and Lindsey, R. (1990) Economics of a bottleneck Journal of Urban Economics 27(1), 111–130. Arnott, R., de Palma, A. and Lindsey, R. (1993) A structural model of peak-period congestion: A traffic bottleneck with elastic demand American Economic Review 83(1), 161–179. Arnott, R., de Palma, A. and Lindsey, R. (1998) Recent developments in the bottleneck model in K. Button and E. T. Verhoef (eds), Road Pricing, Traffic Congestion and the Environment: Issues of Efficiency and Social Feasibility Edward Elgar Cheltenham, UK pp. 79–110. Chu, X. (1995) Alternative congestion pricing schedules Regional Science and Urban Economics 29(6), 697–722. Daganzo, C. F. (2007) Urban gridlock: Macroscopic modeling and mitigation approaches Transportation Research Part B: Methodological 41(1), 49–62. Fargier, P. (1983) Effects of the choice of departure time on road traffic congestion in V. Hurdle, E. Hauer and G. N. Steuart (eds), Proceedings of the Eighth International Symposium on Transportation and Traffic Theory University of Toronto Press Toronto pp. 223–262. Fosgerau, M. (2011) How a fast lane may replace a congestion toll Transportation Research Part B 45(6), 845–851. Geroliminis, N. and Daganzo, C. F. (2008) Existence of urban-scale macroscopic fundamental diagrams: Some experimental findings Transportation Research Part B: Methodological 42(9), 759–770. Geroliminis, N. and Levinson, D. M. (2009) Cordon pricing consistent with the physics of overcrowding Proceedings of the 18th International Symposium on Transportation and Traffic theory . Gonzalez, E. J. and Daganzo, C. F. (2011) Morning Commute with Competing Modes and Distributed Demand: User Equilibrium, System Optimum, and Pricing Kuhmo Nectar conference on transportation economics Stockholm, Sweden. Henderson, J. (1981) The economics of staggered work hours Journal of Urban Economics 9, 349–364. Laih, C.-H. (1994) Queueing at a bottleneck with single- and multi-step tolls Transportation Research Part A 28(3), 197–208. Laih, C. H. (2004) Effects of the optimal step toll scheme on equilibrium commuter behaviour Applied Economics 36(1), 59–81. Mahmassani, H. and Herman, R. (1984) Dynamic User Equilibrium Departure Time and Route Choice on Idealized Traffic Arterials Transportation Science 18(4), 362–384. Shen, W. and Zhang, H. (2010) Pareto-improving ramp metering strategies for reducing congestion in the morning commute Transportation Research Part A 44(9), 676–696. Small, K. (1982) The scheduling of Consumer Activities: Work Trips American Economic Review 72(3), 467–479. Small, K. A. and Chu, X. (2003) Hypercongestion Journal of Transport Economics and Policy 37, 319–352. Vickrey, W. (1969) Congestion theory and transport investment American Economic Review 59(2), 251–261. Walters, A. A. (1961) The Theory and Measurement of Private and Social Cost of Highway Congestion Econometrica 29(4), 676–699. Yang, H. and Huang, H. J. (1997) Analysis of the time-varying pricing of a bottleneck with elastic demand using optimal control theory Transportation Research Part B: Methodological 31(6), 425–440. Zhang, X., Zhang, H. M. and Li, L. (2010) Analysis of User Equilibrium Traffic Patterns on Bottlenecks with Time-Varying Capacities and their Applications International Journal of Sustainable Transportation 4(1), 56–74. |
| URI: | https://mpra.ub.uni-muenchen.de/id/eprint/43411 |
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