A global and local integrated dynamic path planning algorithm for village roads region

Jinyi Liu, Fushan Yan, He Dong, Lirong Fu, Ying Zhao
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Abstract

In China, the village roads are characterized by numerous intersections and significant differences in road widths, creating a complex maze-like terrain. This undoubtedly increases the difficulty of path planning for autonomous vehicles. This study proposes an improved bidirectional RRT* algorithm that utilizes the advantages of the rapid random search of the RRT* algorithm. It introduces virtual points to address the irregularity of road networks and creates enveloping circles at expanding nodes to enhance path reachability, thus obtaining the optimal global planning path. To enhance path tracking comfort, a fifth-order B-spline curve is utilized to smooth the global path, and local path planning is performed using Quadratic Programming (QP). The proposed combined global and local path planning method was evaluated through Co-simulation experiments basing on the Matlab/CarSim/PreScan platform. Simulation results demonstrate that the enhanced RRT* algorithm outperforms the traditional RRT* algorithm in the same scenario. Specifically, the improved algorithm reduces the running time by 29.56%, increases node utilization by approximately 15.33%, and decreases the planned path length by 2.8%. Additionally, the vehicle’s final lateral tracking error was controlled within 0–0.04 m, and the longitudinal tracking error was controlled within 0–0.1 m, fully demonstrating the vehicle’s excellent path-tracking performance. The study’s innovative ideas will offer methodological support for researching path planning for autonomous vehicles in specific scenarios.
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乡村道路区域的全局和局部综合动态路径规划算法
在中国,乡村道路的特点是交叉路口多、路面宽度差异大,形成了复杂的迷宫般地形。这无疑增加了自动驾驶车辆路径规划的难度。本研究利用 RRT* 算法快速随机搜索的优点,提出了一种改进的双向 RRT* 算法。它引入虚拟点来解决路网不规则的问题,并在扩展节点处创建包络圆来增强路径可达性,从而获得最优的全局规划路径。为了提高路径跟踪的舒适度,利用五阶 B 样条曲线平滑全局路径,并使用二次编程(QP)进行局部路径规划。通过基于 Matlab/CarSim/PreScan 平台的协同仿真实验,对所提出的全局和局部相结合的路径规划方法进行了评估。仿真结果表明,在相同场景下,增强型 RRT* 算法优于传统 RRT* 算法。具体来说,改进算法的运行时间减少了 29.56%,节点利用率提高了约 15.33%,计划路径长度减少了 2.8%。此外,车辆的最终横向跟踪误差控制在 0-0.04 米以内,纵向跟踪误差控制在 0-0.1 米以内,充分展示了车辆卓越的路径跟踪性能。该研究的创新思路将为研究特定场景下自动驾驶车辆的路径规划提供方法论支持。
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来源期刊
CiteScore
4.40
自引率
17.60%
发文量
263
审稿时长
3.5 months
期刊介绍: The Journal of Automobile Engineering is an established, high quality multi-disciplinary journal which publishes the very best peer-reviewed science and engineering in the field.
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