首页 /研究 /Neural Gaits: Learning Bipedal Locomotion via Control Barrier Functions and Zero Dynamics Policies
LOCOMOTION

Neural Gaits: Learning Bipedal Locomotion via Control Barrier Functions and Zero Dynamics Policies

Ivan Dario Jimenez Rodriguez, Noel Csomay-Shanklin, Yisong Yue, Aaron D. Ames

发表年份
2022
引用次数
3
访问权限
开放获取

摘要

This work presents Neural Gaits, a method for learning dynamic walking gaits through the enforcement of set invariance that can be refined episodically using experimental data from the robot. We frame walking as a set invariance problem enforceable via control barrier functions (CBFs) defined on the reduced-order dynamics quantifying the underactuated component of the robot: the zero dynamics. Our approach contains two learning modules: one for learning a policy that satisfies the CBF condition, and another for learning a residual dynamics model to refine imperfections of the nominal model. Importantly, learning only over the zero dynamics significantly reduces the dimensionality of the learning problem while using CBFs allows us to still make guarantees for the full-order system. The method is demonstrated experimentally on an underactuated bipedal robot, where we are able to show agile and dynamic locomotion, even with partially unknown dynamics.

关键词

Control theory (sociology)Curse of dimensionalityComputer scienceRobotDynamics (music)UnderactuationSet (abstract data type)Artificial intelligenceControl (management)Physics

相关论文

查看 LOCOMOTION 分类全部论文