Jingxuan Cao scite author profile

Quadruped robots working in jungles, mountains or factories should be able to move through challenging scenarios. In this paper, we present a control framework for quadruped robots walking over rough terrain. The planner plans the trajectory of the robot's center of gravity by using the normalized energy stability criterion, which ensures that the robot is in the most stable state. A contact detection algorithm based on the probabilistic contact model is presented, which implements eventbased state switching of the quadruped robot legs. And an on-line detection of contact force based on generalized momentum is also showed, which improves the accuracy of proprioceptive force estimation. A controller combining whole body control and virtual model control is proposed to achieve precise trajectory tracking and active compliance with environment interaction. Without any knowledge of the environment, the experiments of the quadruped robot SDUQuad-144 climbs over significant obstacles such as 38 cm high steps and 22.5 cm high stairs are designed to verify the feasibility of the proposed method.

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An online terrain classification framework for legged robots based on acoustic signals

Qin

Zhang

Zhu

et al. 2023

Biomimetic Intelligence and Robotics

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Jingxuan Cao

Sim-to-real: Quadruped Robot Control with Deep Reinforcement Learning and Parallel Training

Whole‐body motion planning and control of a quadruped robot for challenging terrain

An online terrain classification framework for legged robots based on acoustic signals

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