4.4 Article

Optimizing Right-Turn Signals to Benefit Pedestrian-Vehicle Interactions

Journal

TRANSPORTATION RESEARCH RECORD
Volume 2675, Issue 8, Pages 22-33

Publisher

SAGE PUBLICATIONS INC
DOI: 10.1177/0361198121995511

Keywords

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Funding

  1. Shanghai Sailing Program [19YF1435100]

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This paper addresses the issue of signal control in pedestrian-vehicle interaction by establishing a right-turn signal optimization model that considers both efficiency and safety. Through analysis of behavior and model establishment, it minimizes traffic delay and conflicts by introducing objective functions based on traffic conflict theory.
In most right-driving urban signalized intersections, right-turn vehicle signals do not usually control turns. To address the problem of signal control in a pedestrian-vehicle interaction, this paper establishes a right-turn signal optimization (RTSO) model that considers both efficiency and safety. First, the main factors influencing the behavior of vehicle and pedestrian during pedestrian-vehicle interaction are analyzed, and a pedestrian-vehicle interaction model (PVI model) at an urban road crosswalk is established. This model is used to determine the probabilities of four pedestrian-vehicle interaction situations. Then, based on the traffic conflict theory, the next step was to construct an objective function that minimizes the total delay of traffic participants considering pedestrian-vehicle interactions, and another objective function that minimizes the potential conflicts considering pedestrian-vehicle interactions. Then, an RTSO model is obtained by introducing a safety-efficiency coefficient to combine the previously described two constructed functions. Finally, the PVI model and delay model are verified through video observation data and the establishment of a cellular automata simulation platform of pedestrian-vehicle interaction. Using these models, a field signal plan, the delay minimization scheme, the conflict minimization scheme, and the proposed scheme are numerically analyzed under different yielding rates. This proposed scheme is further numerically analyzed under different safety-efficiency coefficients. The results show that this paper's RTSO model has certain advantages in increasing safety and reducing delay. In addition, using these results, this paper gives a recommended value for the safety-efficiency coefficients in different application scenarios.

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