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Main Authors: Wang, Leizhen, Duan, Peibo, Lyu, Cheng, Ma, Zhenliang
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2505.20889
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author Wang, Leizhen
Duan, Peibo
Lyu, Cheng
Ma, Zhenliang
author_facet Wang, Leizhen
Duan, Peibo
Lyu, Cheng
Ma, Zhenliang
contents Modern navigation systems and shared mobility platforms increasingly rely on personalized route recommendations to improve individual travel experience and operational efficiency. However, a key question remains: can such sequential, personalized routing decisions collectively lead to system-optimal (SO) traffic assignment? This paper addresses this question by proposing a learning-based framework that reformulates the static SO traffic assignment problem as a single-agent deep reinforcement learning (RL) task. A central agent sequentially recommends routes to travelers as origin-destination (OD) demands arrive, to minimize total system travel time. To enhance learning efficiency and solution quality, we develop an MSA-guided deep Q-learning algorithm that integrates the iterative structure of traditional traffic assignment methods into the RL training process. The proposed approach is evaluated on both the Braess and Ortuzar-Willumsen (OW) networks. Results show that the RL agent converges to the theoretical SO solution in the Braess network and achieves only a 0.35% deviation in the OW network. Further ablation studies demonstrate that the route action set's design significantly impacts convergence speed and final performance, with SO-informed route sets leading to faster learning and better outcomes. This work provides a theoretically grounded and practically relevant approach to bridging individual routing behavior with system-level efficiency through learning-based sequential assignment.
format Preprint
id arxiv_https___arxiv_org_abs_2505_20889
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Reinforcement Learning-based Sequential Route Recommendation for System-Optimal Traffic Assignment
Wang, Leizhen
Duan, Peibo
Lyu, Cheng
Ma, Zhenliang
Artificial Intelligence
Modern navigation systems and shared mobility platforms increasingly rely on personalized route recommendations to improve individual travel experience and operational efficiency. However, a key question remains: can such sequential, personalized routing decisions collectively lead to system-optimal (SO) traffic assignment? This paper addresses this question by proposing a learning-based framework that reformulates the static SO traffic assignment problem as a single-agent deep reinforcement learning (RL) task. A central agent sequentially recommends routes to travelers as origin-destination (OD) demands arrive, to minimize total system travel time. To enhance learning efficiency and solution quality, we develop an MSA-guided deep Q-learning algorithm that integrates the iterative structure of traditional traffic assignment methods into the RL training process. The proposed approach is evaluated on both the Braess and Ortuzar-Willumsen (OW) networks. Results show that the RL agent converges to the theoretical SO solution in the Braess network and achieves only a 0.35% deviation in the OW network. Further ablation studies demonstrate that the route action set's design significantly impacts convergence speed and final performance, with SO-informed route sets leading to faster learning and better outcomes. This work provides a theoretically grounded and practically relevant approach to bridging individual routing behavior with system-level efficiency through learning-based sequential assignment.
title Reinforcement Learning-based Sequential Route Recommendation for System-Optimal Traffic Assignment
topic Artificial Intelligence
url https://arxiv.org/abs/2505.20889