导线
强化学习
地形
容错
机器人
控制器(灌溉)
计算机科学
模拟
钢筋
接头(建筑物)
断层(地质)
执行机构
控制理论(社会学)
实时计算
工程类
人工智能
分布式计算
控制(管理)
生物
结构工程
古生物学
生态学
大地测量学
地理
农学
作者
Dikai Liu,Tianwei Zhang,Jianxiong Yin,Simon See
标识
DOI:10.48550/arxiv.2210.00474
摘要
Modern quadrupeds are skillful in traversing or even sprinting on uneven terrains in a remote uncontrolled environment. However, survival in the wild requires not only maneuverability, but also the ability to handle potential critical hardware failures. How to grant such ability to quadrupeds is rarely investigated. In this paper, we propose a novel methodology to train and test hardware fault-tolerant controllers for quadruped locomotion, both in the simulation and physical world. We adopt the teacher-student reinforcement learning framework to train the controller with close-to-reality joint-locking failure in the simulation, which can be zero-shot transferred to the physical robot without any fine-tuning. Extensive experiments show that our fault-tolerant controller can efficiently lead a quadruped stably when it faces joint failures during locomotion.
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