Torque-Stiffness-Controlled Dynamic Walking: Analysis of the Behaviors of Bipeds with Both Adaptable Joint Torque and Joint Stiffness

Yan Huang; Qining Wang

doi:10.1109/MRA.2015.2510753

Torque-Stiffness-Controlled Dynamic Walking: Analysis of the Behaviors of Bipeds with Both Adaptable Joint Torque and Joint Stiffness

Yan Huang
, Qining Wang

Peking University

Research output: Contribution to journal › Article › peer-review

17 Scopus citations

Abstract

This article presents a general paradigm, torque-stiffness-controlled dynamic walking, to analyze the behaviors of bipeds with both adaptable joint torque and joint stiffness. A bioinspired control method with central pattern generators (CPGs) is applied to realize limb coordination and smooth walking pattern transitions. To better illustrate the proposed paradigm, we show the respective effects of joint torque and joint stiffness on walking performance and motion control in both a four-link simulated model and a robot prototype. This study may develop a new solution for the motion control of bipedal robots with adaptable joint stiffness and provide insights into the principles of efficient and adaptive human walking.

Original language	English
Article number	7426539
Pages (from-to)	71-82
Number of pages	12
Journal	IEEE Robotics and Automation Magazine
Volume	23
Issue number	1
DOIs	https://doi.org/10.1109/MRA.2015.2510753
State	Published - Mar 2016
Externally published	Yes

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title = "Torque-Stiffness-Controlled Dynamic Walking: Analysis of the Behaviors of Bipeds with Both Adaptable Joint Torque and Joint Stiffness",

abstract = "This article presents a general paradigm, torque-stiffness-controlled dynamic walking, to analyze the behaviors of bipeds with both adaptable joint torque and joint stiffness. A bioinspired control method with central pattern generators (CPGs) is applied to realize limb coordination and smooth walking pattern transitions. To better illustrate the proposed paradigm, we show the respective effects of joint torque and joint stiffness on walking performance and motion control in both a four-link simulated model and a robot prototype. This study may develop a new solution for the motion control of bipedal robots with adaptable joint stiffness and provide insights into the principles of efficient and adaptive human walking.",

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Torque-Stiffness-Controlled Dynamic Walking: Analysis of the Behaviors of Bipeds with Both Adaptable Joint Torque and Joint Stiffness

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