Learning to Adapt through Bio-Inspired Gait Strategies for Versatile Quadruped Locomotion
December 12, 2024 Β· Declared Dead Β· π Nature Machine Intelligence
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Authors
Joseph Humphreys, Chengxu Zhou
arXiv ID
2412.09440
Category
cs.RO: Robotics
Citations
8
Venue
Nature Machine Intelligence
Last Checked
4 months ago
Abstract
Legged robots must adapt their gait to navigate unpredictable environments, a challenge that animals master with ease. However, most deep reinforcement learning (DRL) approaches to quadruped locomotion rely on a fixed gait, limiting adaptability to changes in terrain and dynamic state. Here we show that integrating three core principles of animal locomotion-gait transition strategies, gait memory and real-time motion adjustments enables a DRL control framework to fluidly switch among multiple gaits and recover from instability, all without external sensing. Our framework is guided by biomechanics-inspired metrics that capture efficiency, stability and system limits, which are unified to inform optimal gait selection. The resulting framework achieves blind zero-shot deployment across diverse, real-world terrains and substantially significantly outperforms baseline controllers. By embedding biological principles into data-driven control, this work marks a step towards robust, efficient and versatile robotic locomotion, highlighting how animal motor intelligence can shape the next generation of adaptive machines.
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