Neuroevolution Application to Collaborative and Heuristics-Based Connected and Autonomous Vehicle Cohort Simulation at Uncontrolled Intersection

Frédéric F. Jacquelin, J. Bae, Bo Chen, D. Robinette
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Abstract

Artificial intelligence is gaining tremendous attractiveness and showing great success in solving various problems, such as simplifying optimal control derivation. This work focuses on the application of Neuroevolution to the control of Connected and Autonomous Vehicle (CAV) cohorts operating at uncontrolled intersections. The proposed method implementation’s simplicity, thanks to the inclusion of heuristics and effective real-time performance are demonstrated. The resulting architecture achieves nearly ideal operating conditions in keeping the average speeds close to the speed limit. It achieves twice as high mean speed throughput as a controlled intersection, hence enabling lower travel time and mitigating energy inefficiencies from stop-and-go vehicle dynamics. Low deviation from the road speed limit is hence continuously sustained for cohorts of at most 50 m long. This limitation can be mitigated with additional lanes that the cohorts can split into. The concept also allows the testing and implementation of fast-turning lanes by simply replicating and reconnecting the control architecture at each new road crossing, enabling high scalability for complex road network analysis. The controller is also successfully validated within a high-fidelity vehicle dynamic environment, showing its potential for driverless vehicle control in addition to offering a new traffic control simulation model for future autonomous operation studies.
神经进化在非受控交叉口协同启发式联网与自动驾驶车辆队列仿真中的应用
人工智能正获得巨大的吸引力,并在解决各种问题方面取得了巨大的成功,例如简化最优控制推导。这项工作的重点是应用神经进化来控制在不受控制的十字路口运行的联网和自动驾驶车辆(CAV)队列。该方法采用了启发式算法,实现简单,实时性好。由此产生的架构在保持平均速度接近速度限制方面实现了近乎理想的操作条件。它的平均速度吞吐量是受控交叉路口的两倍,因此可以缩短行驶时间,并减轻因走走停停的车辆动态而造成的能源效率低下。因此,对于最长50米长的队列,可以持续保持较低的道路速度限制偏差。这个限制可以通过额外的通道来缓解,队列可以分成。该概念还允许通过简单地复制和重新连接每个新十字路口的控制架构来测试和实施快速转弯车道,从而为复杂的道路网络分析提供高可扩展性。该控制器还在高保真车辆动态环境中成功验证,展示了其在无人驾驶车辆控制方面的潜力,并为未来的自动驾驶研究提供了新的交通控制仿真模型。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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