Abstract
Advanced deep reinforcement learning shows promise as an approach to addressing continuous control tasks, especially in mixed-autonomy traffic. In this study, we present a deep reinforcement-learning-based model that considers the effectiveness of leading autonomous vehicles in mixed-autonomy traffic at a non-signalized intersection. This model integrates the Flow framework, the simulation of urban mobility simulator, and a reinforcement learning library. We also propose a set of proximal policy optimization hyperparameters to obtain reliable simulation performance. First, the leading autonomous vehicles at the non-signalized intersection are considered with varying autonomous vehicle penetration rates that range from 10% to 100% in 10% increments. Second, the proximal policy optimization hyperparameters are input into the multiple perceptron algorithm for the leading autonomous vehicle experiment. Finally, the superiority of the proposed model is evaluated using all human-driven vehicle and leading human-driven vehicle experiments. We demonstrate that full-autonomy traffic can improve the average speed and delay time by 1.38 times and 2.55 times, respectively, compared with all human-driven vehicle experiments. Our proposed method generates more positive effects when the autonomous vehicle penetration rate increases. Additionally, the leading autonomous vehicle experiment can be used to dissipate the stop-and-go waves at a non-signalized intersection.
Highlights
Traffic congestion leads to a lot of wasted time and slow traffic, and it is one of the main challenges that traffic management agencies and traffic participants have to overcome
We demonstrate that full-autonomy traffic can improve the average speed and delay time by 1.38 times and 2.55 times, respectively, compared with all human-driven vehicle experiments
The policy optimization (PPO) with an adaptive KL penalty algorithm controls the distance between the updated policy and the old policy in order to avoid noise during a gradient update
Summary
Traffic congestion leads to a lot of wasted time and slow traffic, and it is one of the main challenges that traffic management agencies and traffic participants have to overcome. According to a national motor vehicle crash survey of the United States, 47% of collisions in 2015 happened at intersections [1]. Automated vehicles (AVs) have recently shown the potential to prevent human errors and improve the quality of a traffic service, with full autonomy expected as soon as 2050 [2]. This means of transportation can save the economy of the United States approximately $450 billion each year [3]. The intelligent transport system (ITS) domain was developed to provide a smoother, smarter, and safer journey to traffic participants. The early applications of ITS, such as traffic control in
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