Abstract
Work zone areas are frequent congested sections considered as the freeway bottleneck. Connected and autonomous vehicle (CAV) trajectory optimization can improve the operating efficiency in bottleneck areas by harmonizing vehicles’ manipulations. This study presents a joint trajectory optimization of cooperative lane changing, merging, and car-following actions for CAV control at a local merging point together with upstream points. The multiagent reinforcement learning (MARL) method is applied in this system, with one agent providing a merging advisory service at the merging point and controlling the inner-lane vehicles’ headway for smooth outer-lane vehicle merging, while other agents provide lane-changing advisory services at advance lane-changing points to control how vehicles make lane changes in advance and perform corresponding headway adjustment, similar to and jointly with the merging advisory service. Uniting all agents, the coordination graph (CG) method is applied to seek the global optimum, overcoming the exponential growth problem in MARL. Using MATLAB and the VISSIM COM interface, an online simulation platform is established. The simulation results show that MARL is effective for online computation with in-timing response. More importantly, comparisons of the results obtained in various scenarios demonstrate that the proposed system obtained smoother vehicle trajectories in all controlled sections, rather than only in the merging area, indicating that it can achieve better traffic conditions in freeway work zone areas.
Highlights
Work zone areas are bottleneck sections affecting the operating efficiency of freeways [1]
In the United States, traffic congestion in work zone areas accounts for 10% of the total mileage driven, while in Germany, it accounts for 31% [2]
To address the gap in previous research, this paper aims to propose an overall joint optimization method based on the reinforcement learning (RL) for connected and autonomous vehicle (CAV) control to control lane changing, merging, and car-following action in multisections upstream of the work zone area
Summary
Work zone areas are bottleneck sections affecting the operating efficiency of freeways [1]. To reduce the occurrence of traffic congestion resulting from human factors, real-time vehicle-to-vehicle (V2V) and vehicle-to-infrastructure (V2I) information sharing and communication technologies for autonomous vehicles (AVs) can be used in traffic management [5,6,7]. With the development of wireless communication technology, AVs are developing in the direction of Journal of Advanced Transportation collaborative autonomous driving among multiple vehicles, known as multivehicle cooperative driving [8, 9]. The technologies of vehicle adaptive control can be implemented separately, when they are integrated to create a connected and autonomous vehicle (CAV) environment, traffic flow performance in terms of factors such as safety, comfort, and efficiency are expected to be dramatically improved [12]. Considering the large number of work zones for road maintenance and road reconstruction that will be necessary in the future, it is necessary to investigate approaches to improve efficiency by manipulating CAVs
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