Topology-preserved distorted space path planning

Yangmin Xie, Qiaoni Yang, Rui Zhou, Zhiyan Cao, Hang Shi
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Abstract

Purpose

Fast obstacle avoidance path planning is a challenging task for multijoint robots navigating through cluttered workspaces. This paper aims to address this issue by proposing an improved path-planning method based on the distorted space (DS) method, specifically designed for high-dimensional complex environments.

Design/methodology/approach

The proposed method, termed topology-preserved distorted space (TP-DS) method, mitigates the limitations of the original DS method by preserving space topology through elastic deformation. By applying distinct spring constants, the TP-DS autonomously shrinks obstacles to microscopic areas within the configuration space, maintaining consistent topology. This enhancement extends the application scope of the DS method to handle complex environments effectively.

Findings

Comparative analysis demonstrates that the proposed TP-DS method outperforms traditional methods regarding planning efficiency. Successful obstacle avoidance tasks in the cluttered workspace validate its applicability on a physical 6-DOF manipulator, highlighting its potential for industrial implementations.

Originality/value

The novel TP-DS method generates a topology-preserved collision-free space by leveraging elastic deformation and shows significant capability and efficiency in planning obstacle-avoidance paths in complex application scenarios.

拓扑保存的扭曲空间路径规划
目的对于在杂乱工作空间中导航的多关节机器人来说,快速避障路径规划是一项具有挑战性的任务。本文旨在通过提出一种基于扭曲空间(DS)方法的改进路径规划方法来解决这一问题,该方法专为高维复杂环境而设计。设计/方法/方法所提出的方法被称为拓扑保留扭曲空间(TP-DS)方法,它通过弹性变形保留空间拓扑来缓解原始 DS 方法的局限性。通过应用不同的弹簧常数,TP-DS 可自主将障碍物缩小到配置空间内的微观区域,从而保持拓扑结构的一致性。对比分析表明,所提出的 TP-DS 方法在规划效率方面优于传统方法。在杂乱的工作空间中成功完成避障任务,验证了该方法在物理 6-DOF 机械手上的适用性,凸显了其在工业应用中的潜力。原创性/价值新颖的 TP-DS 方法通过利用弹性形变生成拓扑结构保持不变的无碰撞空间,在复杂应用场景中规划避障路径方面显示出显著的能力和效率。
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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