Title :
Hybrid intelligent controller for high precision positioning mechanism
Author :
Abd-Elhameed, Esam H. ; Iwasaki, Makoto
Author_Institution :
Dept. of Comput. Sci. & Eng., Nagoya Inst. of Technol., Nagoya, Japan
Abstract :
Ball-screw-driven mechanism has been used in many industrial applications. In microscopic displacement range, resonant modes, dead time in addition to nonlinear friction of this mechanism deteriorate the positioning performance. To obtain high precision response in this displacement range, a control scheme was proposed as a composition of two types of control methodology: a feedforward compensator and a feedback hybrid approach with nonlinear friction compensation using DOB (Disturbance Observer). The hybrid approach combines RCGAs (real-coded genetic algorithms) as optimization techniques to provide an automatic off-line selection for PDFLC (Proportional plus Derivative Fuzzy Logic Controller) membership function parameters. Simulated and experimental results demonstrated the effectiveness and robustness of the proposed controller.
Keywords :
PD control; displacement control; feedback; feedforward; fuzzy control; genetic algorithms; intelligent control; nonlinear control systems; observers; servomechanisms; ball-screw-driven mechanism; displacement range; disturbance observer; feedback hybrid approach; feedforward compensator; hybrid intelligent control; microscopic displacement range; nonlinear friction; nonlinear friction compensation; positioning mechanism; proportional plus derivative fuzzy logic controller; real-coded genetic algorithms; Automatic control; Displacement control; Feedback; Friction; Fuzzy logic; Genetic algorithms; Microscopy; PD control; Proportional control; Resonance;
Conference_Titel :
Advanced Motion Control, 2010 11th IEEE International Workshop on
Conference_Location :
Nagaoka, Niigata
Print_ISBN :
978-1-4244-6668-9
Electronic_ISBN :
1943-6572
DOI :
10.1109/AMC.2010.5464100
