Title :
Friction Compensation for Enhancing Transparency of a Teleoperator With Compliant Transmission
Author :
Mahvash, Mohsen ; Okamura, Allison
Author_Institution :
Johns Hopkins Univ., Baltimore
Abstract :
This paper presents a model-based compensator for canceling friction in the tendon-driven joints of a haptic-feedback teleoperator. Unlike position-tracking systems, a teleoperator involves an unknown environment force that prevents the use of tracking position error as a feedback to the compensator. Thus, we use a model-based feedforward friction compensator to cancel the friction forces. We provide conditions for selecting compensator parameters to ensure passivity of the teleoperator and demonstrate performance experimentally.
Keywords :
compensation; force feedback; friction; haptic interfaces; telecontrol; compliant transmission; friction canceling; friction compensation; haptic-feedback teleoperator; model-based compensator; model-based feedforward friction compensator; teleoperator transparency enhancement; tendon-driven joints; Force control; Force feedback; Force sensors; Friction; Haptic interfaces; Immune system; Manipulator dynamics; Master-slave; Teleoperators; Tendons; Friction compensation; haptic feedback; passivity; telerobotics; transparency;
Journal_Title :
Robotics, IEEE Transactions on
DOI :
10.1109/TRO.2007.909825
