用于互联和自动驾驶车辆的二维行动异步合作变道轨迹规划方法

IF 2 4区 工程技术 Q2 ENGINEERING, CIVIL
Liyang Wei, Weihua Zhang, Haijian Bai, Jingyu Li
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引用次数: 0

摘要

安全、高效、舒适地变换车道是车联网(CAV)应用的重要前提。在针对 CAV 的五阶多项式轨迹规划基础上,进一步考虑纵向和横向驾驶动作执行时间参数,构建了二维动作异步变道(AALC)轨迹规划模型。这样做是为了改善变道模型的适用性,提高 CAV 变道的成功率。通过轨迹曲线参数的单调性和碰撞形式分类确定碰撞轨迹参数解空间的连续性条件,构建连续碰撞空间算法。通过该算法实现了 AALC 轨迹安全判断。在考虑多车舒适性和效率的基础上,构建了合作变道轨迹评价目标函数。最后,根据最优目标函数在连续碰撞空间中求解 AALC 模型,并根据优化结果将变道分为自由变道、合作变道和拒绝变道。结果表明,AALC 模型通过行为执行时间窗的异步过程实现了车道间碰撞空间的转移,从而降低了车辆碰撞的可能性。AALC 模型通过异步行为过程降低了协同变道参数的变化程度,使自由变道轨迹数量增加了约 17%,有效减少了拒绝变道的发生,提高了变道成功率,提升了变道的整体评价。AALC 模型通过异步过程实现了不同车道间碰撞空间的重新分配,更适用于匝道并线等车辆间隙差异较大的环境。基于碰撞的轨迹优化算法可以快速获得相应的安全空间和最优轨迹。单次合作变道的最大计算时间为 0.073 秒,从而实现了实时轨迹规划。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

2D-Action Asynchronous Cooperative Lane Change Trajectory Planning Method for Connected and Automated Vehicles

2D-Action Asynchronous Cooperative Lane Change Trajectory Planning Method for Connected and Automated Vehicles

The ability to change lanes safely, efficiently, and comfortably is an important prerequisite for the application of Connected-Automated Vehicles (CAVs). Based on the five-order polynomial trajectory planning for CAVs, the 2D-Action Asynchronous Lane Change (AALC) trajectory planning model is constructed by further considering the longitudinal and lateral driving action execution time parameters. This is done to improve the applicability of the lane change model and increase the CAV lane change success rate. The continuous collision space algorithm is constructed by determining the continuity condition of collision trajectory parameter solution space through the monotonicity of trajectory curve parameters and collision form classification. AALC trajectory safety judgment is realized through this algorithm. A cooperative lane change trajectory evaluation objective function is constructed, considering multivehicle comfort and efficiency. Finally, the AALC model is solved in the continuous collision space according to the optimal objective function, and the lane change is divided into free, cooperative, and refused according to the optimization. The results indicate that the AALC model achieves the transfer of collision space between lanes through asynchronous process of behavior execution time window, thereby reducing the possibility of vehicle collision. The AALC model reduces the degree of change of cooperative lane change parameters by asynchronous process of behavior, increasing the number of free lane change trajectories by about 17%, effectively reducing the occurrence of lane change refusal, improving the successful rate of lane change, and enhancing the overall evaluation of the lane change. The AALC model realizes the reallocation of collision space between different lanes through asynchronous process, making it more suitable for environments with large differences in vehicle gaps such as ramp merging. The collision-based trajectory optimization algorithm can quickly obtain the corresponding safety space and optimal trajectory. The maximum calculation time for a single cooperative lane change is 0.073 s, thus enabling real-time trajectory planning.

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来源期刊
Journal of Advanced Transportation
Journal of Advanced Transportation 工程技术-工程:土木
CiteScore
5.00
自引率
8.70%
发文量
466
审稿时长
7.3 months
期刊介绍: The Journal of Advanced Transportation (JAT) is a fully peer reviewed international journal in transportation research areas related to public transit, road traffic, transport networks and air transport. It publishes theoretical and innovative papers on analysis, design, operations, optimization and planning of multi-modal transport networks, transit & traffic systems, transport technology and traffic safety. Urban rail and bus systems, Pedestrian studies, traffic flow theory and control, Intelligent Transport Systems (ITS) and automated and/or connected vehicles are some topics of interest. Highway engineering, railway engineering and logistics do not fall within the aims and scope of JAT.
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