Title :
Human-preference-based control design: Adaptive robot admittance control for physical human-robot interaction
Author :
Okunev, Vladislav ; Nierhoff, Thomas ; Hirche, Sandra
Author_Institution :
Inst. of Autom. Control Eng. (LSR), Tech. Univ. Munchen, München, Germany
Abstract :
Aiming at the application in physical human-robot interaction, this paper presents a novel adaptive admittance control scheme for robotic manipulators. Special emphasis is drawn on the avoidance of oscillatory behavior in the presence of closed kinematic chains while keeping the rendered impedance low. The approach uses an online fast Fourier transform of the measured manipulator endeffector forces in order to detect oscillations and to adapt the admittance parameters dynamically. As a novel method towards human-centered control design the adaptation strategy is determined in a user study evaluated with a machine-learning algorithm. Experiments conducted with ten human participants show superiority over the non-adaptive admittance control scheme.
Keywords :
adaptive control; control system synthesis; electric admittance; end effectors; fast Fourier transforms; human-robot interaction; learning (artificial intelligence); manipulator kinematics; rendering (computer graphics); user centred design; adaptive robot admittance control; closed kinematic chains; dynamic admittance parameter adaptation; human-centered control design; human-preference-based control design; impedance rendering; machine-learning algorithm; manipulator endeffector force measurement; online fast Fourier transform; oscillation detection; physical human-robot interaction; robotic manipulators; Admittance; Couplings; Damping; Humans; Manipulators; Oscillators;
Conference_Titel :
RO-MAN, 2012 IEEE
Conference_Location :
Paris
Print_ISBN :
978-1-4673-4604-7
Electronic_ISBN :
1944-9445
DOI :
10.1109/ROMAN.2012.6343792
