基于自适应阻抗控制的轮足式机器人隔振控制研究

Shou Kun Wang; Ming Xin Shi; Bin Kai Yue; Kang Xu; Jun Zheng Wang

doi:10.15918/j.tbit1001-0645.2019.133

基于自适应阻抗控制的轮足式机器人隔振控制研究

Translated title of the contribution: A Vibration Isolation Control Based on Adaptive Impedance Control for Wheel-Legged Robot

Shou Kun Wang, Ming Xin Shi, Bin Kai Yue, Kang Xu, Jun Zheng Wang

School of Automation

Beijing Institute of Technology

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

4 Citations (Scopus)

Abstract

Wheel-legged robots are inevitably in contact with the environment during movement. Due to the fixed parameters of the target impedance model, the traditional method of impedance isolation force control often puts up a poor robustness under an unknown information environment (stiffness and position) or time-varying. Considering traditional impedance control, an adaptive impedance controller was designed based on Lyapunov stability theorem. The method was arranged to indirectly adjust the impedance parameters with position compensation, make the steady-state error of the system to be zero and improve the adaptability to the unknown and changeable environment. Vibration isolation force control experiments were carried out for the robot under the condition of moving on different deceleration belts. Results show the superiority of the adaptive impedance control.

Translated title of the contribution	A Vibration Isolation Control Based on Adaptive Impedance Control for Wheel-Legged Robot
Original language	Chinese (Traditional)
Pages (from-to)	888-893
Number of pages	6
Journal	Beijing Ligong Daxue Xuebao/Transaction of Beijing Institute of Technology
Volume	40
Issue number	8
DOIs	https://doi.org/10.15918/j.tbit1001-0645.2019.133
Publication status	Published - 1 Aug 2020

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10.15918/j.tbit1001-0645.2019.133

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title = "基于自适应阻抗控制的轮足式机器人隔振控制研究",

abstract = "Wheel-legged robots are inevitably in contact with the environment during movement. Due to the fixed parameters of the target impedance model, the traditional method of impedance isolation force control often puts up a poor robustness under an unknown information environment (stiffness and position) or time-varying. Considering traditional impedance control, an adaptive impedance controller was designed based on Lyapunov stability theorem. The method was arranged to indirectly adjust the impedance parameters with position compensation, make the steady-state error of the system to be zero and improve the adaptability to the unknown and changeable environment. Vibration isolation force control experiments were carried out for the robot under the condition of moving on different deceleration belts. Results show the superiority of the adaptive impedance control.",

keywords = "Adaptive impedance, Impedance control, Lyapunov, Vibration isolation control, Wheeled-legged robot",

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T1 - 基于自适应阻抗控制的轮足式机器人隔振控制研究

AU - Wang, Shou Kun

AU - Shi, Ming Xin

AU - Yue, Bin Kai

AU - Xu, Kang

AU - Wang, Jun Zheng

PY - 2020/8/1

Y1 - 2020/8/1

N2 - Wheel-legged robots are inevitably in contact with the environment during movement. Due to the fixed parameters of the target impedance model, the traditional method of impedance isolation force control often puts up a poor robustness under an unknown information environment (stiffness and position) or time-varying. Considering traditional impedance control, an adaptive impedance controller was designed based on Lyapunov stability theorem. The method was arranged to indirectly adjust the impedance parameters with position compensation, make the steady-state error of the system to be zero and improve the adaptability to the unknown and changeable environment. Vibration isolation force control experiments were carried out for the robot under the condition of moving on different deceleration belts. Results show the superiority of the adaptive impedance control.

AB - Wheel-legged robots are inevitably in contact with the environment during movement. Due to the fixed parameters of the target impedance model, the traditional method of impedance isolation force control often puts up a poor robustness under an unknown information environment (stiffness and position) or time-varying. Considering traditional impedance control, an adaptive impedance controller was designed based on Lyapunov stability theorem. The method was arranged to indirectly adjust the impedance parameters with position compensation, make the steady-state error of the system to be zero and improve the adaptability to the unknown and changeable environment. Vibration isolation force control experiments were carried out for the robot under the condition of moving on different deceleration belts. Results show the superiority of the adaptive impedance control.

KW - Adaptive impedance

KW - Impedance control

KW - Lyapunov

KW - Vibration isolation control

KW - Wheeled-legged robot

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基于自适应阻抗控制的轮足式机器人隔振控制研究

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