Robot impedance control and passivity analysis with inner torque and velocity feedback loops 被引量：6

Robot impedance control and passivity analysis with inner torque and velocity feedback loops

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摘要 Impedance control is a well-established technique to control interaction forces in robotics. However, real implementations of impedance control with an inner loop may suffer from several limitations. In particular, the viable range of stable stiffness and damping values can be strongly affected by the bandwidth of the inner control loops （e.g., a torque loop） as well as by the filtering and sampling frequency. This paper provides an extensive analysis on how these aspects influence the stability region of impedance parameters as well as the passivity of the system. This will be supported by both simulations and experimental data. Moreover, a methodology for designing joint impedance controllers based on an inner torque loop and a positive velocity feedback loop will be presented. The goal of the velocity feedback is to increase （given the constraints to preserve stability） the bandwidth of the torque loop without the need of a complex controller. Impedance control is a well-established technique to control interaction forces in robotics. However, real implementations of impedance control with an inner loop may suffer from several limitations. In particular, the viable range of stable stiffness and damping values can be strongly affected by the bandwidth of the inner control loops （e.g., a torque loop） as well as by the filtering and sampling frequency. This paper provides an extensive analysis on how these aspects influence the stability region of impedance parameters as well as the passivity of the system. This will be supported by both simulations and experimental data. Moreover, a methodology for designing joint impedance controllers based on an inner torque loop and a positive velocity feedback loop will be presented. The goal of the velocity feedback is to increase （given the constraints to preserve stability） the bandwidth of the torque loop without the need of a complex controller.

作者 Michele FOCCHI Gustavo A. MEDRANO-CERDA Thiago BOAVENTURA Marco FRIGERIO Claudio SEMINI Jonas BUCHLI Darwin G. CALDWELL

机构地区 Department of Advanced Robotics Agile & Dexterous Robotics Lab revised accepted

出处《Control Theory and Technology》 EI CSCD 2016年第2期97-112,共16页 控制理论与技术（英文版）

基金 This work was supported by the Istituto Italiano di Tecnologia, and Dr. J. Buchli was supported by a Swiss National Science Foundation professorship.

关键词 Impedance control torque control passivity and stability analysis Impedance control, torque control, passivity and stability analysis

分类号 TP242 [自动化与计算机技术—检测技术与自动化装置] TU857 [建筑科学]

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Robot impedance control and passivity analysis with inner torque and velocity feedback loops 被引量：6

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