Investing for Reliability and Security in Transportation Networks
Abstract
Alternative transportation investment policies can lead to very different network forms in the future. The desirability of a transportation network should be assessed not only by its economic efficiency but also by its reliability and security, because the cost of an incidental capacity loss in a road network can be massive. This research concerns how investment rules shape the hierarchical structure of roads and affect network fragility to natural disasters, congestion, and accidents and vulnerability to targeted attacks. A microscopic network growth model predicts the equilibrium road networks under two alternative policy scenarios: investment based on benefit–cost analysis and investment based on bottleneck removal. A set of Monte Carlo simulation runs, in which a certain percentage of links was removed according to the type of network degradation analyzed, was carried out to evaluate the equilibrium road networks. It was found that a hierarchy existed in road networks for reasons such as economic efficiency but that an overly hierarchical structure had serious reliability problems. Throughout the equilibrating or evolution process, the grid network studied under benefit–cost analysis had better efficiency performance, as well as error and attack tolerance. The paper demonstrates that reliability and security considerations can be integrated into the planning of transportation systems.
Get full access to this article
View all access and purchase options for this article.
References
1. Iida Y., and Wakabayashi H. An Approximation Method of Terminal Reliability of a Road Network Using Partial Minimal Path and Cut Set. Proc., 5th World Conference on Transport Research, Yokohama, Japan, 1989, pp. 367–380.
2. Asakura Y., and Kashiwadani M. Road Network Reliability Caused by Daily Fluctuation of Traffic Flow. Proc., 19th PTRC Summer Annual Meeting, Brighton, U.K., PTRC, London, 1991, pp. 73–84.
3. Bell M. G. H., Cassir C., Iida Y., and Lam W. H. K. A Sensitivity Based Approach to Reliability Assessment. Proc., 14th International Symposium on Transportation and Traffic Theory, Pergamon, New York, 1999, pp. 283–300.
4. Chen A., Yang H., Lo H. K., and Tang W. A Capacity Related Reliability for Transportation Networks. Journal of Advanced Transportation, Vol., 33, No. 2, 1999, pp. 183–200.
5. Lam W. H. K., and Zhang N. A New Concept of Travel Demand Satisfaction Reliability for Assessing Road Network Performance. Presented at the Matsuyama Workshop on Transport Network Analysis, Matsuyama, Japan, Aug. 2000.
6. D'Este G. M., and Taylor M. A. P. Network Vulnerability: An Approach to Reliability Analysis at the Level of National Strategic Transport Networks. In The Network Reliability of Transport (Bell M. G. H. and Iida Y., eds.), Elsevier Science, Oxford, United Kingdom, 2003.
7. Asakura Y., Hato E., and Kashiwadani M. Stochastic Network Design Problem: An Optimal Link Investment Model for Reliable Network. In The Network Reliability of Transport (Bell M. G. H. and Iida Y., eds.), Elsevier Science, Oxford, United Kingdom, 2003.
8. Haynes K. E., and Fotheringham A. S. Gravity and Spatial Interaction Models. Sage Publications, Beverly Hills, Calif., 1984.
9. Bar-Gera H., and Boyce D. Origin-Based Algorithm for Combined Travel Forecasting Models. Transportation Research, Part B, Vol. 37, No. 5, 2003, pp. 405–422.
10. Bureau of Public Roads. Traffic Assignment Manual. Urban Planning Division, U.S. Department of Commerce, Washington, D.C., 1964.
11. Roth G. Roads in a Market Economy. Avebury Technical, Aldershot, England, 1996.
12. Keeler T. E., and Small K. A. Optimal Peak-Load Pricing, Investment, and Service Levels on Urban Expressways. Journal of Political Economy, Vol. 85, No. 1, 1977, pp. 1–26.
13. Levinson D., and Karamalaputi R. Induced Supply: A Model of Highway Network Expansion at the Microscopic Level. Journal of Transportation Economics and Policy, Vol. 37, No. 3, 2003, pp. 297–318.
14. Gómez-Ibáñez J. Pricing A. In Essays in Transportation Economics and Policy: A Handbook in Honor of John R. Meyer (Gómez-Ibáñez J. A., Tye W. B., and Winston C., eds.), Brookings Institution Press, Washington, D.C., 1999, p. 121.
15. Heggie I. G. Management and Financing of Roads: An Agenda for Reform. Working Paper No. 8. Sub-Sahara Africa Transport Policy Program, World Bank, Washington, D.C., 1995.
16. Kraus M. Scale Economies Analysis for Urban Highway Networks. Journal of Urban Economics, Vol. 9, 1981, p. 1.
17. Meyer J., Kain J., and Wohl M. The Urban Transportation Problem. Harvard University Press, Cambridge, Mass., 1965.
18. Wohl M., and Hendrickson C. Transportation Investment and Pricing Principles. John Wiley and Sons, Inc., New York, 1984.
19. Downs A. The Law of Peak-Hour Expressway Congestion. Traffic Quarterly, Vol. 16, No. 3, 1962, pp. 393–409.
20. Goodwin P. B. Empirical Evidence on Induced Traffic: A Review and Synthesis. Transportation, Vol. 23, 1996, pp. 35–54.
21. Parthasarathi P., Levinson D., and Karamalaputi R. Induced Demand: A Microscopic Perspective. Urban Studies, Vol. 40, No. 7, 2003, pp. 1335–1353.
22. Zipf G. K. Human Behavior and the Principles of Least Effort. Addison Wesley, Cambridge, Mass., 1949.
23. Granovetter M. Getting a Job: A Study of Contacts and Careers. University of Chicago Press, Chicago, Ill., 1995.
24. Albert R., Jeong H., and Barabási A. L. Attack and Error Tolerance in Complex Networks. Nature, Vol. 406, 2000, p. 378.
25. Aljanahi A. A. M., Rhodes A. H., and Metcalfe A. V. Speed, Speed Limits and Road Traffic Accidents Under Free Flow Conditions. Accident Analysis and Prevention, Vol. 31, 1999, pp. 161–168.
26. Cedar A., and Livneh L. Relationship Between Road Accidents and Hourly Traffic Flow. Accident Analysis and Prevention, Vol. 14, 1982, pp. 19–44.
27. Dickerson A., Peirson J., and Vickerman R. Road Accidents and Traffic Flows: An Econometric Investigation. Economica, Vol. 67, 2000, pp. 101–121.
28. Golob T. F., and Recker W. W. Relationships Among Urban Freeway Accidents, Traffic Flow, Weather, and Lighting Conditions. Journal of Transportation Engineering, Vol. 129, No. 4, 2003, pp. 342–353.
29. Zhou M., and Sisiopiku V. P. Relationship Between Volume-to-Capacity Ratios and Accident Rates. In Transportation Research Record 1581, TRB, National Research Council, Washington, D.C., 1997, pp. 47–52.
Cite article
Cite article
Cite article
OR
Download to reference manager
If you have citation software installed, you can download article citation data to the citation manager of your choice
Information, rights and permissions
Information
Published In
Article first published online: January 1, 2008
Issue published: January 2008
Authors
Metrics and citations
Metrics
Journals metrics
This article was published in Transportation Research Record: Journal of the Transportation Research Board.
VIEW ALL JOURNAL METRICSArticle usage*
Total views and downloads: 35
*Article usage tracking started in December 2016
Altmetric
See the impact this article is making through the number of times it’s been read, and the Altmetric Score.
Learn more about the Altmetric Scores
Articles citing this one
Receive email alerts when this article is cited
Web of Science: 0
Crossref: 17
- A Review of Volume-Delay Functions: Connecting Theoretical Fundamental...
- A method for urban air mobility network design using hub location and ...
- Evaluating the alignment of new metro line considering network vulnera...
- Performance of cross-border corridors in East Africa considering multi...
- Travel time variations over time and routes: endogenous congestion wit...
- A novel agent-based modelling framework for travel time reliability an...
- Evolution Mechanism of Roads Network
- Recent Advances in Modeling the Vulnerability of Transportation Networ...
- Measuring the Performance of Transportation Infrastructure Systems in ...
- Multimodality in a Metroplex Environment: A case study in the San Fran...
- Network Throughput and Reliability: Preventing Hazards and Attacks Thr...
- Robustness Analysis of City Road Network at Different Granularities
- Robustness of city road networks at different granularities
- Importance measures for inland waterway network resilience
- Structural robustness of city road networks based on community
- Positive Model of Departure Time Choice under Road Pricing and Uncerta...
- Modeling Departure Time Choice under Stochastic Networks Involved in N...
Figures and tables
Figures & Media
Tables
View Options
Get access
Access options
If you have access to journal content via a personal subscription, university, library, employer or society, select from the options below:
loading institutional access options
Alternatively, view purchase options below:
Purchase 24 hour online access to view and download content.
Access journal content via a DeepDyve subscription or find out more about this option.
