DocumentCode
663623
Title
Teleimpedance control of a synergy-driven anthropomorphic hand
Author
Ajoudani, Arash ; Godfrey, Sasha B. ; Catalano, M. ; Grioli, G. ; Tsagarakis, N.G. ; Bicchi, A.
Author_Institution
Dept. of Adv. Robot., Ist. Italiano di Tecnol., Genoa, Italy
fYear
2013
fDate
3-7 Nov. 2013
Firstpage
1985
Lastpage
1991
Abstract
In this paper, a novel synergy driven teleimpedance controller for the Pisa-IIT SoftHand is presented. Towards the development of an efficient, robust, and low-cost hand prothesis, the Pisa-IIT SoftHand is built on the motor control principle of synergies, through which the immense complexity of the hand is simplified into distinct motor patterns. As the SoftHand grasps, it follows a synergistic path with built-in flexibility to allow grasping of objects of various shapes using only a single motor. In this work, the hand grasping motion is regulated with an impedance controller which incorporates the user´s postural and stiffness synergy profiles in realtime. In addition, a disturbance observer is realized which estimates the grasping contact force. The estimated force is then fedback to the user via a vibration motor. Grasp robustness and transparency improvements were evaluated on two healthy subjects while grasping different objects. Implementation of the proposed teleimpedance controller led to the execution of stable grasps by controlling the grasping forces, via modulation of hand compliance. In addition, utilization of the vibrotactile feedback resulted in reduced physical load on the user. While these results need to be validated with amputees, they provide evidence that a low-cost, robust hand employing hardware-based synergies is a viable alternative to traditional myoelectric prostheses.
Keywords
anthropometry; dexterous manipulators; elasticity; grippers; haptic interfaces; robust control; telerobotics; vibrations; Pisa-IIT SoftHand; disturbance observer; grasp robustness; grasping contact force; hand complexity; hand compliance modulation; hand grasping motion; low-cost hand prothesis; motor control principles; motor patterns; myoelectric prostheses; physical load; stiffness synergy profiles; synergistic path; synergy driven teleimpedance controller; synergy-driven anthropomorphic hand; transparency improvements; user postural profiles; vibration motor; vibrotactile feedback utilization; DC motors; Electromyography; Grasping; Mathematical model; Muscles; Robustness; Torque;
fLanguage
English
Publisher
ieee
Conference_Titel
Intelligent Robots and Systems (IROS), 2013 IEEE/RSJ International Conference on
Conference_Location
Tokyo
ISSN
2153-0858
Type
conf
DOI
10.1109/IROS.2013.6696620
Filename
6696620
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