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Main Authors: Li, Mingyuan, Liu, Chunyu, Li, Zhuojun, Liu, Xiao, Yu, Guangsheng, Du, Bo, Shen, Jun, Wu, Qiang
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.09368
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author Li, Mingyuan
Liu, Chunyu
Li, Zhuojun
Liu, Xiao
Yu, Guangsheng
Du, Bo
Shen, Jun
Wu, Qiang
author_facet Li, Mingyuan
Liu, Chunyu
Li, Zhuojun
Liu, Xiao
Yu, Guangsheng
Du, Bo
Shen, Jun
Wu, Qiang
contents Traffic accidents result in millions of injuries and fatalities globally, with a significant number occurring at intersections each year. Traffic Signal Control (TSC) is an effective strategy for enhancing safety at these urban junctures. Despite the growing popularity of Reinforcement Learning (RL) methods in optimizing TSC, these methods often prioritize driving efficiency over safety, thus failing to address the critical balance between these two aspects. Additionally, these methods usually need more interpretability. CounterFactual (CF) learning is a promising approach for various causal analysis fields. In this study, we introduce a novel framework to improve RL for safety aspects in TSC. This framework introduces a novel method based on CF learning to address the question: ``What if, when an unsafe event occurs, we backtrack to perform alternative actions, and will this unsafe event still occur in the subsequent period?'' To answer this question, we propose a new structure causal model to predict the result after executing different actions, and we propose a new CF module that integrates with additional ``X'' modules to promote safe RL practices. Our new algorithm, CFLight, which is derived from this framework, effectively tackles challenging safety events and significantly improves safety at intersections through a near-zero collision control strategy. Through extensive numerical experiments on both real-world and synthetic datasets, we demonstrate that CFLight reduces collisions and improves overall traffic performance compared to conventional RL methods and the recent safe RL model. Moreover, our method represents a generalized and safe framework for RL methods, opening possibilities for applications in other domains. The data and code are available in the github https://github.com/AdvancedAI-ComplexSystem/SmartCity/tree/main/CFLight.
format Preprint
id arxiv_https___arxiv_org_abs_2512_09368
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle CFLight: Enhancing Safety with Traffic Signal Control through Counterfactual Learning
Li, Mingyuan
Liu, Chunyu
Li, Zhuojun
Liu, Xiao
Yu, Guangsheng
Du, Bo
Shen, Jun
Wu, Qiang
Machine Learning
Methodology
Traffic accidents result in millions of injuries and fatalities globally, with a significant number occurring at intersections each year. Traffic Signal Control (TSC) is an effective strategy for enhancing safety at these urban junctures. Despite the growing popularity of Reinforcement Learning (RL) methods in optimizing TSC, these methods often prioritize driving efficiency over safety, thus failing to address the critical balance between these two aspects. Additionally, these methods usually need more interpretability. CounterFactual (CF) learning is a promising approach for various causal analysis fields. In this study, we introduce a novel framework to improve RL for safety aspects in TSC. This framework introduces a novel method based on CF learning to address the question: ``What if, when an unsafe event occurs, we backtrack to perform alternative actions, and will this unsafe event still occur in the subsequent period?'' To answer this question, we propose a new structure causal model to predict the result after executing different actions, and we propose a new CF module that integrates with additional ``X'' modules to promote safe RL practices. Our new algorithm, CFLight, which is derived from this framework, effectively tackles challenging safety events and significantly improves safety at intersections through a near-zero collision control strategy. Through extensive numerical experiments on both real-world and synthetic datasets, we demonstrate that CFLight reduces collisions and improves overall traffic performance compared to conventional RL methods and the recent safe RL model. Moreover, our method represents a generalized and safe framework for RL methods, opening possibilities for applications in other domains. The data and code are available in the github https://github.com/AdvancedAI-ComplexSystem/SmartCity/tree/main/CFLight.
title CFLight: Enhancing Safety with Traffic Signal Control through Counterfactual Learning
topic Machine Learning
Methodology
url https://arxiv.org/abs/2512.09368