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2018 | OriginalPaper | Chapter

AMoDSim: An Efficient and Modular Simulation Framework for Autonomous Mobility on Demand

Authors : Andrea Di Maria, Andrea Araldo, Giovanni Morana, Antonella Di Stefano

Published in: Internet of Vehicles. Technologies and Services Towards Smart City

Publisher: Springer International Publishing

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Abstract

Urban transportation of next decade is expected to be disrupted by Autonomous Mobility on Demand (AMoD): AMoD providers will collect ride requests from users and will dispatch a fleet of autonomous vehicles to satisfy requests in the most efficient way. Differently from current ride sharing systems, in which driver behavior has a clear impact on the system, AMoD systems will be exclusively determined by the dispatching logic. As a consequence, a recent interest in the Operations Research and Computer Science communities has focused on this control logic. The new propositions and methodologies are generally evaluated via simulation. Unfortunately, there is no simulation platform that has emerged as reference, with the consequence that each author uses her own custom-made simulator, applicable only in her specific study, with no aim of generalization and without public release. This slows down the progress in the area as researchers cannot build on each other’s work and cannot share, reproduce and verify the results. The goal of this paper is to present AMoDSim, an open-source simulation platform aimed to fill this gap and accelerate research in future ride sharing systems.

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previous chapter Development of a Mobile Functional Near-Infrared Spectroscopy Prototype

next chapter Aggregated Multi-deep Deterministic Policy Gradient for Self-driving Policy

https://github.com/admaria/AMoDSim.

A particular version of SUMO, called SUMO MESO [2], is intended to reduce the details in vehicle movement simulation. However, we are not aware of any published study on AMoD systems based on SUMO MESO.

BlaBla Car. https://www.blablacar.com/

MESO: Mesoscopic version of SUMO. http://sumo.dlr.de/wiki/MESO

OMNeT++. https://www.omnetpp.org/

Toth, P., Vigo, D.: Vehicle Routing. SIAM-MOS, 2nd edn. (2014)

Agatz, N.A.H., Erera, A.L., et al.: Dynamic ride-sharing: a simulation study in metro Atlanta. Transp. Res. B-Method 45(9), 1450–1464 (2011)CrossRef

Alazzawi, S., Hummel, M., Kordt, P., Sickenberger, T., Wieseotte, C., Wohak, O.: Simulating the impact of shared, autonomous vehicles on urban mobility - a case study of Milan. In: SUMO User Conference (2018)

Alonso-Mora, J., Samaranayake, S., et al.: On-demand high-capacity ride-sharing via dynamic trip-vehicle assignment. PNAS 114(3), 462–467 (2017)CrossRef

Basu, R., et al.: Automated mobility-on-demand vs. mass transit: a multi-modal activity-driven agent-based simulation approach. Transp. Res. Rec. https://doi.org/10.1177/0361198118758630

Bischoff, J., Maciejewski, M.: Simulation of city-wide replacement of private cars with autonomous taxis in Berlin. In: ANT. Elsevier Masson SAS (2016)

10.

Boesch, P.M., Ciari, F., et al.: Autonomous vehicle fleet sizes required to serve different levels of demand. Transp. Res. Rec. 2542, 111–119 (2016)CrossRef

11.

Burgstaller, S., Flowers, D., et al.: Rethinking mobility: The ‘pay as you go’ car: ride hailing just the start. Technical report (2017)

12.

Clewlow, R.R., Mishra, G.S.: Disruptive transportation: the adoption, utilization, and impacts of ride-hailing in the United States. Technical report, UC Davis (2017)

13.

Elpern-Waxman, J.: Transportation Terms: Dwell Time (2017)

14.

Hyland, M., Mahmassani, H.: Dynamic autonomous vehicle fleet operations: optimization-based strategies to assign AVs to immediate traveler demand requests. Transp. Res. C-Emer. 92, 278–297 (2018)CrossRef

15.

Jaeyoung, J., Jayakrishnan, R., et al.: Design and modeling of real-time shared-taxi dispatch algorithms. In: TRB 92nd Annual Meeting (2013)

16.

Jung, J., Jayakrishnan, R., et al.: Design and modeling of real-time shared-taxi dispatch algorithms. In: TRB Annual Meeting, vol. 8 (2013)

17.

Lam, A.Y.S., Leung, Y., et al.: Autonomous-vehicle public transportation system: scheduling and admission control. IEEE Trans. Intell. Transp. Syst. 17(5), 1210–1226 (2016)CrossRef

18.

Linares, M.P., Montero, L., et al.: A simulation framework for real-time assessment of dynamic ride sharing demand responsive transportation models. In: WSC (2016)

19.

Ma, S., Zheng, Y., et al.: T-share : a large-scale dynamic taxi ridesharing. In: ICDE (2013)

20.

Martinez, L.M., Correia, G.H.A., et al.: An agent-based simulation model to assess the impacts of introducing a shared-taxi system: an application to Lisbon. JAT 49, 475–495 (2015)

21.

Robinson, S.: Measuring bus stop dwell time and time lost serving stop with London ibus automatic vehicle location data. Transp. Res. Rec. 2352(1), 68–75 (2013)CrossRef

22.

Santi, P., Resta, G., et al.: Quantifying the benefits of vehicle pooling with shareability networks. Proc. Natl. Acad. Sci. 111(37), 13290–13294 (2014)CrossRef

23.

Skulimowski, A.M.J., Ćwik, A.: Communication quality in anticipatory vehicle swarms: a simulation-based model. In: Peng, S.-L., Lee, G.-L., Klette, R., Hsu, C.-H. (eds.) IOV 2017. LNCS, vol. 10689, pp. 119–134. Springer, Cham (2017). https://doi.org/10.1007/978-3-319-72329-7_11CrossRef

24.

Vazifeh, M.M., Santi, P., et al.: Addressing the minimum fleet problem in on-demand urban mobility. Nature 557, 534 (2018)CrossRef

Title: AMoDSim: An Efficient and Modular Simulation Framework for Autonomous Mobility on Demand
Authors: Andrea Di Maria
Andrea Araldo
Giovanni Morana
Antonella Di Stefano
Publisher: Springer International Publishing
Book: Internet of Vehicles. Technologies and Services Towards Smart City
Print ISBN: 978-3-030-05080-1

Electronic ISBN: 978-3-030-05081-8

Copyright Year: 2018
DOI: https://doi.org/10.1007/978-3-030-05081-8_12

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