Abstract

The prevailing variable speed limit (VSL) systems as an effective strategy for traffic control on motorways have the disadvantage that they only work with static VSL zones. Under changing traffic conditions, VSL systems with static VSL zones may perform suboptimally. Therefore, the adaptive design of VSL zones is required in traffic scenarios where congestion characteristics vary widely over space and time. To address this problem, we propose a novel distributed spatial-temporal multi-agent VSL (DWL-ST-VSL) approach capable of dynamically adjusting the length and position of VSL zones to complement the adjustment of speed limits in current VSL control systems. To model DWL-ST-VSL, distributed W-learning (DWL), a reinforcement learning (RL)-based algorithm for collaborative agent-based self-optimization toward multiple policies, is used. Each agent uses RL to learn local policies, thereby maximizing travel speed and eliminating congestion. In addition to local policies, through the concept of remote policies, agents learn how their actions affect their immediate neighbours and which policy or action is preferred in a given situation. To assess the impact of deploying additional agents in the control loop and the different cooperation levels on the control process, DWL-ST-VSL is evaluated in a four-agent configuration (DWL4-ST-VSL). This evaluation is done via SUMO microscopic simulations using collaborative agents controlling four segments upstream of the congestion in traffic scenarios with medium and high traffic loads. DWL also allows for heterogeneity in agents’ policies; cooperating agents in DWL4-ST-VSL implement two speed limit sets with different granularity. DWL4-ST-VSL outperforms all baselines (W-learning-based VSL and simple proportional speed control), which use static VSL zones. Finally, our experiments yield insights into the new concept of VSL control. This may trigger further research on using advanced learning-based technology to design a new generation of adaptive traffic control systems to meet the requirements of operating in a nonstationary environment and at the leading edge of emerging connected and autonomous vehicles in general.

Highlights

  • Everyday commuting in densely populated urban areas is accompanied by repetitive traffic jams, representing an evident violation of urban life quality

  • In our previous work [23], we proposed a distributed spatiotemporal multi-agent Variable speed limit (VSL) control based on reinforcement learning (RL) (DWL-ST-VSL) with dynamic VSL zone allocation

  • The objective of this study is to evaluate the impact of dynamically adjusting the VSL zone configurations and the different number of agents in distributed W-learning (DWL)-ST-VSL on the optimization of traffic flow within an active bottleneck and the motorway as a whole

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Summary

Introduction

Everyday commuting in densely populated urban areas is accompanied by repetitive traffic jams, representing an evident violation of urban life quality. As an integrated part of the urban road network, are affected by congestion. Variable speed limit (VSL) is an efficient traffic control strategy to improve motorways’. The speed limit value adapts to different traffic situations depending on weather conditions, accidents, traffic jams, etc [1]. The main objective of VSL is to improve traffic safety and throughput on motorways due to the concept of speed homogenization [2] and mainstream traffic flow control (MTFC) [3], respectively. VSL aims to ensure stable traffic flow in motorway areas affected by recurrent bottlenecks. A higher volume of traffic at the on-ramp can disrupt the main traffic flow and cause a bottleneck activation

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