运动规划
障碍物
修剪
路径(计算)
随机树
高斯分布
算法
树(集合论)
运动学
计算机科学
路径长度
分布(数学)
钥匙(锁)
数学优化
人工智能
数学
机器人
数学分析
农学
计算机网络
物理
计算机安全
量子力学
经典力学
政治学
法学
生物
程序设计语言
作者
Yuze Shang,Fei Liu,Ping Qin,Zhizhong Guo,Zhe Li
标识
DOI:10.1108/ec-11-2022-0672
摘要
Purpose The goal of this research is to develop a dynamic step path planning algorithm based on the rapidly exploring random tree (RRT) algorithm that combines Q-learning with the Gaussian distribution of obstacles. A route for autonomous vehicles may be swiftly created using this algorithm. Design/methodology/approach The path planning issue is divided into three key steps by the authors. First, the tree expansion is sped up by the dynamic step size using a combination of Q-learning and the Gaussian distribution of obstacles. The invalid nodes are then removed from the initially created pathways using bidirectional pruning. B-splines are then employed to smooth the predicted pathways. Findings The algorithm is validated using simulations on straight and curved highways, respectively. The results show that the approach can provide a smooth, safe route that complies with vehicle motion laws. Originality/value An improved RRT algorithm based on Q-learning and obstacle Gaussian distribution (QGD-RRT) is proposed for the path planning of self-driving vehicles. Unlike previous methods, the authors use Q-learning to steer the tree's development direction. After that, the step size is dynamically altered following the density of the obstacle distribution to produce the initial path rapidly and cut down on planning time even further. In the aim to provide a smooth and secure path that complies with the vehicle kinematic and dynamical restrictions, the path is lastly optimized using an enhanced bidirectional pruning technique.
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