具有局部障碍物规避功能的感知脚踏装置

arXiv - CS - Robotics Pub Date : 2024-09-11 DOI:arxiv-2409.07195

Jonas Stolle, Philip Arm, Mayank Mittal, Marco Hutter

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引用次数: 0

摘要

脚踏机器人利用腿部机器人的脚进行移动操纵，无需专用机械臂。虽然之前的研究已经展示了盲人和特定任务的脚踏技能，但它们未能考虑到环境中的静态和动态障碍。为了解决这一局限性，我们引入了一种基于强化学习的方法来训练全身障碍感知策略，该策略可在避开障碍的同时跟踪脚的位置指令。尽管只在五个不同的模拟场景中训练了该策略，但我们发现它可以泛化到具有不同数量和类型障碍物的未知环境中。我们通过一系列模拟实验分析了该方法的性能，并成功地在 ANYmal 四足动物上部署了学习到的策略，证明了它能够在绕过静态和动态障碍物的同时遵循脚部指令。

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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Perceptive Pedipulation with Local Obstacle Avoidance

Pedipulation leverages the feet of legged robots for mobile manipulation, eliminating the need for dedicated robotic arms. While previous works have showcased blind and task-specific pedipulation skills, they fail to account for static and dynamic obstacles in the environment. To address this limitation, we introduce a reinforcement learning-based approach to train a whole-body obstacle-aware policy that tracks foot position commands while simultaneously avoiding obstacles. Despite training the policy in only five different static scenarios in simulation, we show that it generalizes to unknown environments with different numbers and types of obstacles. We analyze the performance of our method through a set of simulation experiments and successfully deploy the learned policy on the ANYmal quadruped, demonstrating its capability to follow foot commands while navigating around static and dynamic obstacles.

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arXiv - CS - Robotics

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