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Automated Vehicle Scenarios: Simulation of System-Level Travel Effects Using Agent-Based Demand and Supply Models in the San Francisco Bay Area

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  • Rodier, Caroline
  • Jaller, Miguel
  • Pourrahmani, Elham
  • Bischoff, Joschka
  • Freedman, Joel
  • Pahwa, Anmol

Abstract

In much in the same way that the automobile disrupted horse and cart transportation in the 20th century, automated vehicles hold the potential to disrupt our current system of transportation in the 21st century. Experts predict that vehicles could be fully automated by as early as 2025 or as late as 2035. Methods are needed to help the public and private sector understand automated vehicle technologies and their system-level effects. First, we explore the effects of automated vehicles using the San Francisco Bay Area Metropolitan Transportation Commission’s activity-based travel demand model (MTC-ABM). The simulation is unique in that it articulates the size and direction of change on travel for a wide range of automated vehicles scenarios. Second, we simulate the effects of the introduction of an automated taxi service on conventional personal vehicle and transit travel in the San Francisco Bay Area region and use new research on the costs of automated vehicles to represent plausible per mile automated taxi fares. We use an integrated model for the San Francisco Bay Area that includes the MTC-ABM combined with the agent-based MATSim model customized for the region. This model set uses baseline travel demand data from the region’s official activity-based travel model and dynamically assigns vehicles on road and transit networks by the time of day. Third, we use the MTC-ABM and the MATSim dynamic assignment model to simulate different “first” mile transit access services, including ride-hailing (Uber and Lyft) and ridesharing (Uber Pool/Lyft Line and Via) with and without automated vehicles. The results provide insight into the relative benefits of each service and automated vehicle technology and the potential market for these services. View the NCST Project Webpage

Suggested Citation

  • Rodier, Caroline & Jaller, Miguel & Pourrahmani, Elham & Bischoff, Joschka & Freedman, Joel & Pahwa, Anmol, 2018. "Automated Vehicle Scenarios: Simulation of System-Level Travel Effects Using Agent-Based Demand and Supply Models in the San Francisco Bay Area," Institute of Transportation Studies, Working Paper Series qt4dk3n531, Institute of Transportation Studies, UC Davis.
  • Handle: RePEc:cdl:itsdav:qt4dk3n531
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    References listed on IDEAS

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    1. Arentze, Theo A. & Molin, Eric J.E., 2013. "Travelers’ preferences in multimodal networks: Design and results of a comprehensive series of choice experiments," Transportation Research Part A: Policy and Practice, Elsevier, vol. 58(C), pages 15-28.
    2. Lyons, Glenn & Jain, Juliet & Holley, David, 2007. "The use of travel time by rail passengers in Great Britain," Transportation Research Part A: Policy and Practice, Elsevier, vol. 41(1), pages 107-120, January.
    3. Wadud, Zia & MacKenzie, Don & Leiby, Paul, 2016. "Help or hindrance? The travel, energy and carbon impacts of highly automated vehicles," Transportation Research Part A: Policy and Practice, Elsevier, vol. 86(C), pages 1-18.
    4. Itf, 2015. "Urban Mobility System Upgrade: How shared self-driving cars could change city traffic," International Transport Forum Policy Papers 6, OECD Publishing.
    5. Román, Concepción & Espino, Raquel & Martín, Juan Carlos, 2007. "Competition of high-speed train with air transport: The case of Madrid–Barcelona," Journal of Air Transport Management, Elsevier, vol. 13(5), pages 277-284.
    6. Chen, T. Donna & Kockelman, Kara M. & Hanna, Josiah P., 2016. "Operations of a shared, autonomous, electric vehicle fleet: Implications of vehicle & charging infrastructure decisions," Transportation Research Part A: Policy and Practice, Elsevier, vol. 94(C), pages 243-254.
    7. Bruce Schaller, 1999. "Elasticities for taxicab fares and service availability," Transportation, Springer, vol. 26(3), pages 283-297, August.
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    Cited by:

    1. Chai, Huajun & Rodier, Caroline & Song, Jeffery & Zhang, Michael & Jaller, Miguel, 2020. "The Impacts of Automated Vehicles on Center City Parking Demand," Institute of Transportation Studies, Working Paper Series qt63m6k29n, Institute of Transportation Studies, UC Davis.
    2. Chai, Huajun & Rodier, Caroline J. & Song, Jeffery W. & Zhang, Michael H. & Jaller, Miguel, 2023. "The impacts of automated vehicles on Center city parking," Transportation Research Part A: Policy and Practice, Elsevier, vol. 175(C).

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    Keywords

    Business; Automated Vehicles; Travel Demand Modeling; Agent-Based Models; Transit Access;
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