DocumentCode
2541038
Title
Improving operational space control of heavy manipulators via open-loop compensation
Author
Maeda, Guilherme J. ; Singh, Surya P N ; Rye, David C.
Author_Institution
Australian Centre for Field Robot., Univ. of Sydney, Sydney, NSW, Australia
fYear
2011
fDate
25-30 Sept. 2011
Firstpage
725
Lastpage
731
Abstract
Operational space control has a number of desirable characteristics but is sensitive to model accuracy. For heavy machines the dynamics are difficult to model due to their friction and dynamic coupling, thus making full compensation imprecise. This work presents an approach in which a simplified model gives partial compensation via an open-loop feedforward input, pre-calculated in forward simulation. In this way, effects that are difficult to compensate for can be partially corrected without causing instability. Since the reference trajectory is known a priori, dynamic model parameters are tuned in its neighbourhood, reducing the burden of global modelling. The feasibility and performance of this approach is shown experimentally via improved free motion tracking of an excavator arm. This framework further supports efforts for direct impedance control between bucket tip and soil.
Keywords
compensation; excavators; feedforward; friction; manipulator dynamics; motion control; open loop systems; bucket tip; direct impedance control; dynamic coupling; dynamic model parameters; excavator arm; forward simulation; free motion tracking; friction; global modelling; heavy machines; heavy manipulators; open-loop compensation; open-loop feedforward input; operational space control; reference trajectory; Aerospace electronics; Friction; Joints; Manipulator dynamics; Predictive models; Trajectory;
fLanguage
English
Publisher
ieee
Conference_Titel
Intelligent Robots and Systems (IROS), 2011 IEEE/RSJ International Conference on
Conference_Location
San Francisco, CA
ISSN
2153-0858
Print_ISBN
978-1-61284-454-1
Type
conf
DOI
10.1109/IROS.2011.6094437
Filename
6094437
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