Connected Traffic Signal Coordination Optimization Framework through Network-Wide Adaptive Linear Quadratic Regulator-Based Control Strategy

Jiho Park, Tong Liu, Chieh Ross Wang, Andy Berres, Joseph Severino, Juliette Ugirumurera, Airton G. Kohls, Hong Wang, Jibonananda Sanyal, Zhong Ping Jiang

Research output: Contribution to journalArticlepeer-review

Abstract

Traffic congestion in metropolitan areas causes several significant challenges, such as longer travel times, decreased productivity, increased fuel consumption and vehicle emissions, and even severe injuries during crashes. Traffic signal control is a management approach to reduce traffic congestion and allocate the appropriate right of way for safety and mobility efficiency, both in temporal and spatial domains. This study proposes a network-wide adaptive signal control coordination optimization framework based on the linear quadratic regulator algorithm. The traffic flow conditions driven by signal control inputs are formulated based on their network-wide state-space representation. After modeling traffic control regulation constraints, an adaptive linear quadratic regulator algorithm is designed to maximize the network-wide total throughput under the current conditions. Optimal signal control split time durations for multiple intersections in the network are derived by solving the algebraic Riccati equation. Furthermore, the recursive least square parameter estimation method is employed to quantify dynamic traffic condition changes. To verify the effectiveness of this proposed signal control framework, both simulation and real-world experimental tests are conducted for multiple intersections in downtown Chattanooga, Tennessee, United States. In preparation for real-world experimental tests, pipelines for real-time data processing implementation and historical traffic flow data analysis are conducted. The test results demonstrate that the proposed control framework achieves a decrease in travel time by up to 19.4%, total time spent (TTS) by up to 11.9%, and relative queue balance (RQB) by up to 15.6%. The research findings indicate that the proposed signal control framework can be generalized to handle large scale signal control optimization network-wide.

Original languageEnglish
Article number04024113
JournalJournal of Transportation Engineering Part A: Systems
Volume151
Issue number2
DOIs
StatePublished - Feb 1 2025

Funding

The Chattanooga Department of Transportation and the Tennessee Department of Transportation installed GRDISMART cameras and radar sensors to collect real-time traffic data around the city, including the downtown area. Downtown is one of the major areas in Chattanooga where traffic congestion occasionally happens because of high traffic demands. Therefore, eight representative intersections in downtown Chattanooga are selected as the test intersections due to their complete detection and control infrastructure support. Some or all data, models, or code that support the findings of this study are available from the corresponding author upon reasonable request.

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