Multi-contact bipedal robotic locomotion-Reference-Cited by-同舟云学术

Multi-contact bipedal robotic locomotion

Published:2015-12-02 Issue:5 Volume:35 Page:1072-1106
ISSN:0263-5747
Container-title:Robotica
language:en
Short-container-title:Robotica

Author:

Zhao Huihua,Hereid Ayonga,Ma Wen-loong,Ames Aaron D.

Abstract

SUMMARYThis paper presents a formal framework for achieving multi-contact bipedal robotic walking, and realizes this methodology experimentally on two robotic platforms: AMBER2 and Assume The Robot Is A Sphere (ATRIAS). Inspired by the key feature encoded in human walking—multi-contact behavior—this approach begins with the analysis of human locomotion and uses it to motivate the construction of a hybrid system model representing a multi-contact robotic walking gait. Human-inspired outputs are extracted from reference locomotion data to characterize the human model or the spring-loaded invert pendulum (SLIP) model, and then employed to develop the human-inspired control and an optimization problem that yields stable multi-domain walking. Through a trajectory reconstruction strategy motivated by the process that generates the walking gait, the mathematical constructions are successfully translated to the two physical robots experimentally.

Publisher

Cambridge University Press (CUP)

Subject

Computer Science Applications,General Mathematics,Software,Control and Systems Engineering

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