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Bibliographic Details
Main Authors: Jusoh, Ruzanna Mat, Ampountolas, Konstantinos
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2403.06312
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author Jusoh, Ruzanna Mat
Ampountolas, Konstantinos
author_facet Jusoh, Ruzanna Mat
Ampountolas, Konstantinos
contents A control scheme for the multi-gated perimeter traffic flow control problem of cities is presented. The proposed scheme determines feasible and optimally distributed input flows for the various gates located at the periphery of a protected network. A parsimonious model is employed to describe the traffic dynamics of the protected network. To describe traffic dynamics outside of the protected area, the state-space model is augmented with additional state variables to account for vehicle queues at store-and-forward origin links at the periphery. The perimeter flow control problem is formulated as a convex optimisation problem with finite horizon, and constrained control and state variables. It aims to equalise the relative queues at origin links and to maintain the vehicle accumulation in the protected network around a desired set point, while the system's throughput is maximised. For real-time control, the optimal control problem is embedded in a rolling-horizon scheme using the current state of the system as the initial state as well as predicted demand flows at entrance links. Furthermore, practical flow allocation policies for single-region perimeter control without explicitly considering entrance link dynamics are presented. These policies allocate a global perimeter-ordered flow to candidate gates at the periphery of a protected network by taking into account the different geometric characteristics of origin links. The proposed flow allocation policies are then benchmarked against the multi-gated perimeter flow control. A study is carried out for a 2.5 square mile protected network area of San Francisco, CA, including fifteen gates of different geometric characteristics. The results have showed that the proposed scheme is able to manage excessive queues outside of the protected network and to optimally distribute the input flows, which confirms its efficiency and equity properties.
format Preprint
id arxiv_https___arxiv_org_abs_2403_06312
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Multi-gated perimeter flow control for monocentric cities: Efficiency and equity
Jusoh, Ruzanna Mat
Ampountolas, Konstantinos
Systems and Control
A control scheme for the multi-gated perimeter traffic flow control problem of cities is presented. The proposed scheme determines feasible and optimally distributed input flows for the various gates located at the periphery of a protected network. A parsimonious model is employed to describe the traffic dynamics of the protected network. To describe traffic dynamics outside of the protected area, the state-space model is augmented with additional state variables to account for vehicle queues at store-and-forward origin links at the periphery. The perimeter flow control problem is formulated as a convex optimisation problem with finite horizon, and constrained control and state variables. It aims to equalise the relative queues at origin links and to maintain the vehicle accumulation in the protected network around a desired set point, while the system's throughput is maximised. For real-time control, the optimal control problem is embedded in a rolling-horizon scheme using the current state of the system as the initial state as well as predicted demand flows at entrance links. Furthermore, practical flow allocation policies for single-region perimeter control without explicitly considering entrance link dynamics are presented. These policies allocate a global perimeter-ordered flow to candidate gates at the periphery of a protected network by taking into account the different geometric characteristics of origin links. The proposed flow allocation policies are then benchmarked against the multi-gated perimeter flow control. A study is carried out for a 2.5 square mile protected network area of San Francisco, CA, including fifteen gates of different geometric characteristics. The results have showed that the proposed scheme is able to manage excessive queues outside of the protected network and to optimally distribute the input flows, which confirms its efficiency and equity properties.
title Multi-gated perimeter flow control for monocentric cities: Efficiency and equity
topic Systems and Control
url https://arxiv.org/abs/2403.06312