Essential Bicycle Dynamics for Microscopic Traffic Simulation: An Example Using the Social Force Model

C.M. Schmidt*, A. Dabiri, F. Schulte, R. Happee, J.K. Moore

*Corresponding author for this work

Research output: Chapter in Book/Conference proceedings/Edited volumeConference contributionScientificpeer-review

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Abstract

Microscopic simulation is an established tool in traffic engineering and research, where aggregated traffic performance measures are inferred from the simulation of individual agents. Additionally, measures describing the safety and efficiency of road user interactions gain importance for recent developments such as automated vehicles and urban cycling. However, current simulation frameworks model interactions including cyclists only with limited realism. To address this issue, we propose to bring bicycle dynamics to traffic simulation. We demonstrate that a novel reformulation of the social force framework can create input signals for a controlled inverted pendulum bicycle model and thereby enable a fully two-dimensional open space simulation of cyclist interactions. The inverted pendulum model introduces the need to stabilize the bicycle as a constraint to the reactive behavior of simulated cyclists. Furthermore, it enables the simulation of countersteering and weaving for stabilization. Our cyclist social forces have anisotropic force fields with respect to relative interaction position and orientation to describe the varying interaction constellations in open space. With these models, we simulate five single- and multi-cyclist test cases and show that the generated trajectories notably differ from results obtained from a 2D bicycle model without lean angle simulation. Measurements of the maximum lateral path deviation and post-encroachment time show that these differences are relevant for typical applications. Our work demonstrates the potential of introducing physics-based realistic bicycle dynamics to the microscopic simulation of individual road user interactions and the fundamental capability of our reformulated cyclist social forces to do so. Going further, we plan to calibrate and validate our model based on naturalistic cycling data to support the initial results of this work.
Original languageEnglish
Title of host publicationProceedings of the 5th Symposium on the Dynamics and Control of Single-track Vehicles
Subtitle of host publicationBicycle and Motorcycle Dynamics 2023, October 18-20, Delft, The Netherlands
EditorsJason Moore, Edwin de Vries, Andrew Dressel, Leila Alizadehsarav
PublisherTU Delft OPEN Publishing
Number of pages12
ISBN (Electronic)978-94-6366-958-0
DOIs
Publication statusPublished - 2024
EventBMD 2023 - Bicycle & Motorcycle Dynamics
: 5th Symposium on the Dynamics and Control of Single Track Vehicles
- Delft University of Technology, Delft, Netherlands
Duration: 18 Oct 202320 Oct 2023
https://2023.bmdconf.org/index.html

Publication series

NameThe Evolving Scholar
PublisherTU Delft OPEN Pubishing
Volume3
ISSN (Electronic)2667-2812

Conference

ConferenceBMD 2023 - Bicycle & Motorcycle Dynamics
Country/TerritoryNetherlands
CityDelft
Period18/10/2320/10/23
Internet address

Keywords

  • Social force model
  • Microscopic traffic simulation
  • Cyclist behaviour
  • Bicycle dynamics
  • Bicycle trajectories

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