Identifying Topological Credentials of Physical Infrastructure Components to Enhance Transportation Network Resilience: Case of Florida Bridges
Publication: Journal of Transportation Engineering, Part A: Systems
Volume 148, Issue 9
Abstract
Physical infrastructure systems contribute to human civilization significantly and play a key role in the smooth operation of society. However, such systems may experience loss of functionality because of external shocks, i.e., human-made or natural hazards. To enhance the resiliency of the infrastructure systems, network positions or credentials of infrastructure components (e.g., roads, bridges) based on their topology or connectivity need to be assessed. The empirical literature does not provide specific guidance how such topological credentials may contribute to system resilience, i.e., reducing overall adverse impacts as well as recovering from loss of performance. This study emphasized a coordinated and extensive network of experiments at different geographic scales by applying complex network principles to explore the resiliency of Florida road networks. Geographic modeling was used along with Florida road (with bridges) network data to perform network experiments and prioritize certain bridges based on their network credentials. In particular, the study established a systematic approach to rank the topological credentials of bridges based on the connectivity and attributes (i.e., weights) of road networks. Such credentials change significantly when different weights (i.e., vehicular traffic) are introduced to the network topology at different geographic scales. The practical implications for transportation network resilience as well as the scaling effects are examined by quantifying resilience in terms of average network travel time and developing recovery schemes of bridges for a sample road network. The study developed a credible methodology that would benefit states, municipalities, and other transportation authorities to prioritize risk-based recovery strategies.
Practical Applications
This research presents a methodology that can rank the relative importance of bridges in a road network based on their position in the network. Such topological credentials of bridges may change at different geographic scales (i.e., city or county or state) when different network metrics (i.e., centrality) are considered and/or different attributes are introduced as weights (i.e., traffic volume) to network connectivity or topology. The relative importance of different bridges would allow bridge engineers, maintenance personnel, and other practitioners to decide on which bridge should be inspected, maintained, or constructed first based on the position of the bridges in a network setting. Different transportation agencies engage in solving unprecedented problems observed on local roads or bridges. This study provides novel insights on how to go beyond the local context and incorporate a broader network perspective. Bridges are typically inspected every 2 years for regular maintenance purposes. Because of time and budget constraints, inspection of all the bridges may not be possible often in a timely manner. As a result, bridges that would carry more importance in terms of traffic, construction, or other impacts should be given priority. By having a rank of bridges, activities on bridges can be done more systematically.
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Data Availability Statement
Some or all data, models, or code that support the findings of this study are available from the corresponding author upon reasonable request.
Acknowledgments
The authors are grateful to the US Department of Transportation and the Accelerated Bridge Construction University Transportation Center (ABC-UTC) for supporting the research presented in this study. Moreover, the authors greatly appreciate the constructive comments provided by the reviewers, which significantly improved the quality of the research. However, the authors are solely responsible for the findings presented in this study.
References
Abdel-Rahim, A., P. Oman, B. Johnson, L.-W. Tung, and R. Sedid. 2006. Modeling and assessing large-scale surface transportation network component criticality. Moscow, ID: National Institute for Advanced Transportation Technology.
Ahmed, M. A., A. M. Sadri, and M. Hadi. 2020. “The role of social networks and day-to-day sharing activity on hurricane evacuation decision consistency and shared evacuation capacity.” In Proc., 99th Annual Meeting of Transportation Research Board. Washington, DC: Transportation Research Board.
Albert, R. 2000. “Attack and error tolerance in complex networks.” Nature 406 (6794): 378–382. https://doi.org/10.1038/35019019.
Alipour, A., D. Gransberg, and N. Zhang. 2018. An integrated project to enterprise-level decision-making framework for prioritization of accelerated bridge construction.. Ames, IA: Iowa State Univ.
Arafat, M., S. Iqbal, and M. Hadi. 2020. “Utilizing an analytical hierarchy process with stochastic return on investment to justify connected vehicle-based deployment decisions.” Transp. Res. Rec. 2674 (9): 462–472. https://doi.org/10.1177/0361198120929686.
Bao, Z., Y. Cao, L. Ding, and G. Wang. 2009. “Comparison of cascading failures in small-world and scale-free networks subject to vertex and edge attacks.” Physica A 388 (20): 4491–4498. https://doi.org/10.1016/j.physa.2009.07.017.
Barabási, A.-L., and R. Albert. 1999. “Emergence of scaling in random networks.” Science 286 (5439): 509–512. https://doi.org/10.1126/science.286.5439.509.
Bar-Gera, H. 2016. “The traffic assignment problem.” Accessed April 12, 2021. https://www.bgu.ac.il/∼bargera/tntp/.
Bocchini, F., D. M. Frangopol, T. Ummenhofer, and T. Zinke. 2014. “Resilience and sustainability of civil infrastructure: Toward a unified approach.” J. Infrastuct. Syst. 20 (2): 04014004. https://doi.org/10.1061/(ASCE)IS.1943-555X.0000177.
Brandes, U. 2001. “A faster algorithm for betweenness centrality.” J. Math. Sociol. 25 (2): 163–177. https://doi.org/10.1080/0022250X.2001.9990249.
Brandes, U. 2008. “On variants of shortest-path betweenness centrality and their generic computation.” Soc. Networks 30 (2): 136–145. https://doi.org/10.1016/j.socnet.2007.11.001.
Brandes, U., and C. Pich. 2007. “Centrality estimation in large networks.” Int. J. Bifurcation Chaos 17 (07): 2303–2318. https://doi.org/10.1142/S0218127407018403.
Bruneau, M., S. E. Chang, R. T. Eguchi, G. C. Lee, T. D. O’Rourke, A. M. Reinhorn, M. Shinozuka, K. Tierney, W. A. Wallace, and D. Von Winterfeldt. 2003. “A framework to quantitatively assess and enhance the seismic resilience of communities.” Earthquake Spectra 19 (4): 733–752. https://doi.org/10.1193/1.1623497.
Chen, J., J. Liu, Q. Peng, and Y. Yin. 2022. “Resilience assessment of an urban rail transit network: A case study of Chengdu subway.” Physica A 586 (Jan): 126517. https://doi.org/10.1016/j.physa.2021.126517.
Derrible, S. 2012. “Network centrality of metro systems.” PLoS One 7 (7): e40575. https://doi.org/10.1371/journal.pone.0040575.
Derrible, S., and C. Kennedy. 2010. “The complexity and robustness of metro networks.” Phys. A 389 (17): 3678–3691. https://doi.org/10.1016/j.physa.2010.04.008.
Derrible, S., and C. Kennedy. 2011. “Applications of graph theory and network science to transit network design.” Transp. Rev. 31 (4): 495–519. https://doi.org/10.1080/01441647.2010.543709.
FDOT (Florida DOT). 2017. “Geographic information system (GIS).” Accessed February 16, 2020. https://www.fdot.gov/statistics/gis/default.shtm.
FDOT (Florida DOT). 2019. “Florida traffic online, AADT/hourly data.” Accessed March 15, 2020. https://tdaappsprod.dot.state.fl.us/fto/.
Frangopol, D. M., and P. Bocchini. 2011. “Resilience as optimization criterion for the rehabilitation of bridges belonging to a transportation network subject to earthquake.” In Proc., Structures Congress. Reston, VA: ASCE. https://doi.org/10.1061/41171(401)178.
Frank, M., and P. Wolfe. 1956. “An algorithm for quadratic programming.” Nav. Res. Logist. Q. 3 (1–2): 95–110. https://doi.org/10.1002/nav.3800030109.
Hawick, K., and H. James. 2007. Vol. 11 of Node importance ranking and scaling properties of some complex road networks, 23–32, Wellington, New Zealand: Massey Univ., Research Letters in the Information and Mathematical Sciences.
Henry, E., A. Furno, and N.-E. El Faouzi. 2019. “A graph-based approach with simulated traffic dynamics for the analysis of transportation resilience in smart cities.” In Proc., 98th Annual Meeting Transportation Research Board, 21. Washington, DC: Transportation Research Board.
Henry, E., A. Furno, and N.-E. E. Faouzi. 2021. “Approach to quantify the impact of disruptions on traffic conditions using dynamic weighted resilience metrics of transport networks.” Transp. Res. Rec. 2675 (4): 61–78. https://doi.org/10.1177/0361198121998663.
Hurlburt, R., H. Neff, S. Croome, and A. Thomas. 2019. “Assessing the impact of potential road closures on 8th Street in downtown Boise.” 019 Undergraduate Research and Scholarship Conf., 72. Boise, ID: Boise State Univ.
Karamlou, A., and P. Bocchini. 2014. “Optimal bridge restoration sequence for resilient transportation networks.” In Proc., Structures Congress, 1437–1447. Reston, VA: ASCE. https://doi.org/10.1061/9780784413357.127.
Kermanshah, A., and S. Derrible. 2017. “Robustness of road systems to extreme flooding: Using elements of GIS, travel demand, and network science.” Nat. Hazards 86 (1): 151–164. https://doi.org/10.1007/s11069-016-2678-1.
Kumar, A., and S. Peeta. 2015. “Entropy weighted average method for the determination of a single representative path flow solution for the static user equilibrium traffic assignment problem.” Transp. Res. Part B: Methodol. 71 (Jan): 213–229. https://doi.org/10.1016/j.trb.2014.11.002.
LeBlanc, L. J. 1975. “An algorithm for the discrete network design problem.” Transp. Sci. 9 (3): 183–199. https://doi.org/10.1287/trsc.9.3.183.
Liu, J., P. M. Schonfeld, S. Zhan, Q. Peng, and Y. Liu. 2021. “Measuring and enhancing the connectivity reliability of a rail transit network.” Transportmetrica A: Transp. Sci. 17 (1): 1–168. https://doi.org/10.1080/23249935.2021.1965241.
Louf, R., C. Roth, and M. Barthelemy. 2014. “Scaling in transportation networks.” PLoS One 9 (7): e102007. https://doi.org/10.1371/journal.pone.0102007.
Machado-León, J. L., and A. Goodchild. 2017. “Review of performance metrics for community-based planning for resilience of the transportation system.” Transp. Res. Rec. 2604 (1): 44–53. https://doi.org/10.3141/2604-06.
Mohmand, Y. T., and A. Wang. 2013. “Weighted complex network analysis of Pakistan highways.” In Discrete dynamics in nature and society. London: Hindawi, Discrete Dynamics in Nature and Society.
Mortula, M. M., M. A. Ahmed, A. M. Sadri, T. Ali, I. Ahmad, and A. Idris. 2020. “Improving resiliency of water supply system in arid regions: Integrating centrality and hydraulic vulnerability.” J. Manage. Eng. 36 (5): 05020011. https://doi.org/10.1061/(ASCE)ME.1943-5479.0000817.
Murray-Tuite, P. M. 2006. “A comparison of transportation network resilience under simulated system optimum and user equilibrium conditions.” In Proc., 2006 Winter Simulation Conf., 1398–1405. New York: IEEE.
NetworkX. 2019. “NetworkX—Software for complex networks.” Accessed April 23, 2020. https://networkx.github.io/.
NetworkX. 2021. “Network analysis in Python.” Accessed March 19, 2020. https://networkx.orgdocumentation/stable/reference/algorithms/generated/networkx.algorithms.centrality.edge_betweenness_centrality.html.
Newman, M. E. 2003. “The structure and function of complex networks.” SIAM Rev. 45 (2): 167–256. https://doi.org/10.1137/S003614450342480.
Newman, M. E., and M. Girvan. 2004. “Finding and evaluating community structure in networks.” Phys. Rev. E 69 (2): 026113. https://doi.org/10.1103/PhysRevE.69.026113.
Newman, M. E. J. 2005. “A measure of betweenness centrality based on random walks.” Soc. Networks 27 (1): 39–54. https://doi.org/10.1016/j.socnet.2004.11.009.
Rokneddin, K., J. Ghosh, L. Dueñas-Osorio, and J. E. Padgett. 2013. “Bridge retrofit prioritisation for ageing transportation networks subject to seismic hazards.” Struct. Infrastruct. Eng. 9 (10): 1050–1066. https://doi.org/10.1080/15732479.2011.654230.
Rouhana, F., and D. Jawad. 2020. “Transportation network resilience against failures: GIS-based assessment of network topology role.” Int. J. Disaster Resilience Built Environ. 12 (4): 357–370. https://doi.org/10.1108/IJDRBE-06-2020-0064.
Roy, K., M. A. Ahmed, S. Hasan, and A. M. Sadri. 2020. “Dynamics of crisis communications in social media: Spatio-temporal and text-based comparative analyses of twitter data from hurricanes Irma and Michael.” In Proc., Int. Conf. on Information Systems for Crisis Response and Management (ISCRAM) 2020. Brussels, Belgium: ISCRASM.
Sheffi, Y. 1985. Urban transportation networks: Equilibrium analysis with mathematical programming methods. England Cliffs, NJ: Prentice Hall.
Speck, J. 2014. “Boise, Idaho downtown walkability analysis.” Accessed November 21, 2020. https://www.ccdcboise.com/wp-content/uploads/2014/12/Jeff-Speck-Boise-Report.pdf.
Stabler, B. 2020. “Transportation networks/SiouxFalls.” Accessed February 13, 2021. https://github.com/bstabler/TransportationNetworks/tree/master/SiouxFalls.
Sun, W., P. Bocchini, and B. D. Davison. 2018. “Resilience metrics and measurement methods for transportation infrastructure: The state of the art.” Sustainable Resilient Infrastruct. 5 (3): 168–199. https://doi.org/10.1080/23789689.2018.1448663.
US Dept. of Commerce, Bureau of Public Roads, and Office of Planning. 1964. Traffic assignment manual for application with a large, high speed computer. College Park, MD: US Dept. of Commerce.
Wei, C., H.-C. Yeh, and Y.-C. Chen. 2014. “Spatiotemporal scaling effect on rainfall network design using entropy.” Entropy 16 (8): 4626–4647. https://doi.org/10.3390/e16084626.
Zhang, W., and N. Wang. 2017. “Resilience-based post-disaster recovery strategies for road-bridge networks.” Struct. Infrastruct. Eng. 13 (11): 1404–1413. https://doi.org/10.1080/15732479.2016.1271813.
Zhang, W., N. Wang, C. Nicholsonc, and M. H. Tehrani. 2018. “A stage-wise decision framework for transportation network resilience planning.” Preprint, submitted August 11, 2018. http://arxiv.org/abs/1808.03850.
Zhang, X., E. Miller-Hooks, and K. Denny. 2015. “Assessing the role of network topology in transportation network resilience.” J. Transp. Geogr. 46 (Jun): 35–45. https://doi.org/10.1016/j.jtrangeo.2015.05.006.
Zhao, Y., K. Triantis, and P. Edara. 2010. “Evaluation of travel demand strategies: A microscopic traffic simulation approach.” Transportation 37 (3): 549–571. https://doi.org/10.1007/s11116-010-9258-0.
Zhong, R., X. Xie, J. Luo, T. Pan, W. Lam, and A. Sumalee. 2020. “Modeling double time-scale travel time processes with application to assessing the resilience of transportation systems.” Transp. Res. Part B: Methodol. 132 (Feb): 228–248. https://doi.org/10.1016/j.trb.2019.05.005.
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Journal of Transportation Engineering, Part A: Systems
Volume 148 • Issue 9 • September 2022
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© 2022 American Society of Civil Engineers.
History
Received: Jun 16, 2021
Accepted: Apr 11, 2022
Published online: Jun 20, 2022
Published in print: Sep 1, 2022
Discussion open until: Nov 20, 2022
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