DocumentCode :
741495
Title :
Bringing Nonlinear 
Optimality to Robot Controllers
Author :
Min Jun Kim ; Youngjin Choi ; Wan Kyun Chung
Author_Institution :
Robot. Lab., Pohang Univ. of Sci. & Technol., Pohang, South Korea
Volume :
31
Issue :
3
fYear :
2015
fDate :
6/1/2015 12:00:00 AM
Firstpage :
682
Lastpage :
698
Abstract :
This paper proposes a framework called nonlinear robust internal-loop compensator that enables us to bring nonlinear H∞ optimality to robot controllers in a unified and simple way. Using the framework, a controller designed for the nominal plant can achieve additional robustness by simply adding PID-type auxiliary input to the original control law. Robust performance is guaranteed by the nonlinear 1-1 optimality and robust stability is guaranteed by proving the extended disturbance input-to-state stability. Moreover, the framework preserves the passivity property of the original controller. Finally, the performance bound can be predicted and leads to the gain tuning rules. By virtue of the tuning rules, the performance can be tuned using only a single variable. The proposed method was validated through the simulations and experiments.
Keywords :
H∞ control; compensation; control system synthesis; nonlinear control systems; robots; robust control; three-term control; PID-type auxiliary input; controller design; gain tuning rules; input-to-state stability; nonlinear H∞ optimality; nonlinear robust internal-loop compensator; robot controllers; Mathematical model; Optimal control; Robots; Robustness; Tuning; Uncertainty; Upper bound; Force control; H∞ control; H??? control; motion control; robot control; robust control;
fLanguage :
English
Journal_Title :
Robotics, IEEE Transactions on
Publisher :
ieee
ISSN :
1552-3098
Type :
jour
DOI :
10.1109/TRO.2015.2419871
Filename :
7101283
Link To Document :
