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Learning Complex Motor Skills for Legged Robot Fall Recovery

Chuanyu Yang, Can Pu, Guiyang Xin, Jie Zhang, Zhibin Li

2023IEEE Robotics and Automation Letters21 citationsDOIOpen Access PDF

Abstract

Falling is inevitable for legged robots in challenging real-world scenarios, where environments are unstructured and situations are unpredictable, such as uneven terrain in the wild. Hence, to recover from falls and achieve all-terrain traversability, it is essential for intelligent robots to possess the complex motor skills required to resume operation. To go beyond the limitation of handcrafted control, we investigated a deep reinforcement learning approach to learn generalized feedback-control policies for fall recovery that are robust to external disturbances. We proposed a design guideline for selecting key states for initialization, including a comparison to the random state initialization. The proposed learning-based pipeline is applicable to different robot models and their corner cases, including both small-/large-size bipeds and quadrupeds. Further, we show that the learned fall recovery policies are hardware-feasible and can be implemented on real robots.

Topics & Concepts

InitializationReinforcement learningTerrainRobotComputer sciencePipeline (software)Artificial intelligenceState (computer science)Key (lock)SimulationComputer securityGeographyAlgorithmProgramming languageCartographyRobotic Locomotion and ControlRobot Manipulation and LearningProsthetics and Rehabilitation Robotics
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