Online Search-Based Collision-Inclusive Motion Planning and Control for Impact-Resilient Mobile Robots

Zhouyu Lu; Zhichao Liu; Merrick CampbellKonstantinos Karydis

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Online Search-Based Collision-Inclusive Motion Planning and Control for Impact-Resilient Mobile Robots

机译：Online Search-Based Collision-Inclusive Motion Planning and Control for Impact-Resilient Mobile Robots

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This article focuses on the emerging paradigm shift of collision-inclusive motion planning and control for impact-resilient mobile robots, and develops a unified hierarchical framework for navigation in unknown and partially observable cluttered spaces. At the lower level, we develop a deformation recovery control and trajectory replanning strategy that handles collisions that may occur at run time, locally. The low-level system actively detects collisions (via embedded Hall effect sensors on a mobile robot built in-house), enables the robot to recover from them, and locally adjusts the postimpact trajectory. Then, at the higher level, we propose a search-based planning algorithm to determine how to best utilize potential collisions to improve certain metrics, such as control energy and computational time. Our method builds upon A* with jump points. We generate a novel heuristic function, and a collision checking and adjustment technique, thus making the A* algorithm converge faster to reach the goal by exploiting and utilizing possible collisions. The overall hierarchical framework generated by combining the global A* algorithm and the local deformation recovery and replanning strategy, as well as individual components of this framework, are tested extensively both in simulation and experimentally. An ablation study draws links to related state-of-the-art search-based collision-avoidance planners (for the overall framework), as well as search-based collision-avoidance and sampling-based collision-inclusive global planners (for the higher level). Results demonstrate our method's efficacy for collision-inclusive motion planning and control in unknown environments with isolated obstacles for a class of impact-resilient robots operating in 2-D.

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《IEEE Transactions on Robotics: A publication of the IEEE Robotics and Automation Society》 |2023年第2期|1029-1049|共21页
作者
Zhouyu Lu; Zhichao Liu; Merrick CampbellKonstantinos Karydis;
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Department of Electrical and Computer Engineering, University of California, Riverside, CA, USA;

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原文格式 PDF
正文语种英语
中图分类机器人技术;
关键词
Robots; Collision avoidance; Planning; Trajectory; Robot sensing systems; Strain; Mobile robots;

Online Search-Based Collision-Inclusive Motion Planning and Control for Impact-Resilient Mobile Robots

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