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Compatibility of Automated Vehicles in Street Spaces: Considerations for a Sustainable Implementation

Author

Listed:
  • Aggelos Soteropoulos

    (Future.lab, Technical University of Vienna, 1040 Vienna, Austria
    Institute for Transportation System Planning, Technical University of Vienna, 1040 Vienna, Austria)

  • Martin Berger

    (Institute for Transportation System Planning, Technical University of Vienna, 1040 Vienna, Austria)

  • Mathias Mitteregger

    (Future.lab, Technical University of Vienna, 1040 Vienna, Austria)

Abstract

Automated Vehicles (AVs) will bring a fundamental change in the mobility sector in the coming years. Whereas many studies emphasize opportunities with AVs, studies on the impacts of AVs on travel behavior particularly show an overall increase in traffic volume. This increase could impair the needs of other uses and users within street spaces and decrease the permeability of the street space for pedestrians and cyclists. However, only a few studies, so far, have looked at the changes of traffic volume due to AVs at the street level, and to what extent these impair the needs of other uses and users within different street spaces was not in the focus at all. This paper investigates the compatibility of AVs in street spaces, building on different modeling results of scenarios with AVs based on the Multi-Agent Traffic Simulation (MATSim) framework. Using the so-called compensatory approach and the whole street network of Vienna, Austria, as a case study, we examine how compatible AVs and their related changes in traffic volume are with the needs of other uses and users, i.e., pedestrians and cyclists, within different street spaces, by specifically considering the various characteristics of the latter. Results show that the effects of AVs on the compatibility of street spaces would be unevenly distributed across the city. For Shared Automated Vehicles (SAVs), a deterioration in compatibility is observable, especially in inner-city dense areas, because of an increase in traffic volume and an already high amount of competing uses. In contrast, especially (on main roads) in the outskirts, improvements in compatibility are possible. This particularly applies to SAVs with a stop-based service. However, private AVs interlinked with an overall capacity increase would lead to a deterioration in compatibility, especially in parts of the higher-level street network that already have incompatible traffic volumes, further increasing the separating or barrier effect of such streets. The results can provide insights for policymakers and stakeholders about where and how to facilitate AVs, to reach an implementation that is compatible with the different uses and needs of users within street spaces: While SAVs should be implemented particularly in the outskirts, as a complement for public transport, an implementation of AVs in the lower-level street network in inner parts of the city should not be facilitated, or it should at least be linked to measures that make street spaces more compatible with the needs of pedestrians and cyclists, e.g., implementation of walking and cycling infrastructure.

Suggested Citation

  • Aggelos Soteropoulos & Martin Berger & Mathias Mitteregger, 2021. "Compatibility of Automated Vehicles in Street Spaces: Considerations for a Sustainable Implementation," Sustainability, MDPI, vol. 13(5), pages 1-32, March.
    • Handle: RePEc:gam:jsusta:v:13:y:2021:i:5:p:2732-:d:509681
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    References listed on IDEAS

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    1. Luca Staricco & Valentina Rappazzo & Jacopo Scudellari & Elisabetta Vitale Brovarone, 2019. "Toward Policies to Manage the Impacts of Autonomous Vehicles on the City: A Visioning Exercise," Sustainability, MDPI, vol. 11(19), pages 1-21, September.
    2. González-González, Esther & Nogués, Soledad & Stead, Dominic, 2020. "Parking futures: Preparing European cities for the advent of automated vehicles," Land Use Policy, Elsevier, vol. 91(C).
    3. Arellana, Julián & Saltarín, María & Larrañaga, Ana Margarita & González, Virginia I. & Henao, César Augusto, 2020. "Developing an urban bikeability index for different types of cyclists as a tool to prioritise bicycle infrastructure investments," Transportation Research Part A: Policy and Practice, Elsevier, vol. 139(C), pages 310-334.
    4. Soteropoulos, Aggelos & Mitteregger, Mathias & Berger, Martin & Zwirchmayr, Jakob, 2020. "Automated drivability: Toward an assessment of the spatial deployment of level 4 automated vehicles," Transportation Research Part A: Policy and Practice, Elsevier, vol. 136(C), pages 64-84.
    5. Su, Shiliang & Zhou, Hao & Xu, Mengya & Ru, Hu & Wang, Wen & Weng, Min, 2019. "Auditing street walkability and associated social inequalities for planning implications," Journal of Transport Geography, Elsevier, vol. 74(C), pages 62-76.
    6. Yu Ye & Wei Zeng & Qiaomu Shen & Xiaohu Zhang & Yi Lu, 2019. "The visual quality of streets: A human-centred continuous measurement based on machine learning algorithms and street view images," Environment and Planning B, , vol. 46(8), pages 1439-1457, October.
    7. Correia, Gonçalo Homem de Almeida & Looff, Erwin & van Cranenburgh, Sander & Snelder, Maaike & van Arem, Bart, 2019. "On the impact of vehicle automation on the value of travel time while performing work and leisure activities in a car: Theoretical insights and results from a stated preference survey," Transportation Research Part A: Policy and Practice, Elsevier, vol. 119(C), pages 359-382.
    8. Erling Holden & Geoffrey Gilpin & David Banister, 2019. "Sustainable Mobility at Thirty," Sustainability, MDPI, vol. 11(7), pages 1-14, April.
    9. Aggelos Soteropoulos & Martin Berger & Francesco Ciari, 2019. "Impacts of automated vehicles on travel behaviour and land use: an international review of modelling studies," Transport Reviews, Taylor & Francis Journals, vol. 39(1), pages 29-49, January.
    10. Paulo Rui Anciaes & Peter Jones & Jennifer S. Mindell, 2016. "Community Severance: Where Is It Found and at What Cost?," Transport Reviews, Taylor & Francis Journals, vol. 36(3), pages 293-317, May.
    11. Beck, Matthew J. & Hensher, David A. & Wei, Edward, 2020. "Slowly coming out of COVID-19 restrictions in Australia: Implications for working from home and commuting trips by car and public transport," Journal of Transport Geography, Elsevier, vol. 88(C).
    12. Itf, 2015. "Urban Mobility System Upgrade: How shared self-driving cars could change city traffic," International Transport Forum Policy Papers 6, OECD Publishing.
    13. Oh, Simon & Seshadri, Ravi & Azevedo, Carlos Lima & Kumar, Nishant & Basak, Kakali & Ben-Akiva, Moshe, 2020. "Assessing the impacts of automated mobility-on-demand through agent-based simulation: A study of Singapore," Transportation Research Part A: Policy and Practice, Elsevier, vol. 138(C), pages 367-388.
    14. Kolarova, Viktoriya & Steck, Felix & Bahamonde-Birke, Francisco J., 2019. "Assessing the effect of autonomous driving on value of travel time savings: A comparison between current and future preferences," Transportation Research Part A: Policy and Practice, Elsevier, vol. 129(C), pages 155-169.
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