research-article

A Vehicle-Intersection Coordination Scheme for Smooth Flows of Traffic Without Using Traffic Lights

Authors:

Md Abdus Samad Kamal,

Jun-ichi Imura,

Tomohisa Hayakawa,

Kazuyuki AiharaAuthors Info & Claims

IEEE Transactions on Intelligent Transportation Systems, Volume 16, Issue 3

Pages 1136 - 1147

https://doi.org/10.1109/TITS.2014.2354380

Published: 29 May 2015 Publication History

Abstract

This paper presents a coordination scheme of automated vehicles at an intersection without using any traffic lights. Using a two-way communication network, vehicles approaching the intersection from all sections are globally coordinated, by considering their states all together in a model predictive control framework, in order to achieve smooth traffic flows at the intersection. The optimal trajectories of the vehicles are computed based on avoidance of their cross-collision risks around the intersection under relevant constraints and preferences. The scheme efficiently utilizes the intersection area by preventing each pair of conflicting vehicles from approaching their cross-collision point at the same time, instead of reserving the whole intersection area for the conflicting vehicles one after another. The scheme also enables left- or right-turning movements of vehicles under constrained velocity without using any auxiliary lanes. The proposed vehicle-intersection coordination scheme is evaluated through numerical simulation in a typical test intersection consisting of both multilanes and single-lane approaches with turning movements of vehicles. Observations under different traffic flow conditions reveal that the proposed scheme significantly improves intersection performance compared with the traditional signalized intersection scheme.

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A Vehicle-Intersection Coordination Scheme for Smooth Flows of Traffic Without Using Traffic Lights

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cover image IEEE Transactions on Intelligent Transportation Systems

IEEE Transactions on Intelligent Transportation Systems Volume 16, Issue 3

June 2015

548 pages

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Copyright © 2014.

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IEEE Press

Publication History

Published: 29 May 2015

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