Title :
The neural network inverse decoupling control of bearingless synchronous reluctance motor
Author :
Xu Mengzhe ; Diao Xiaoyan ; Feng Dongmei ; Zhu Huangqiu
Author_Institution :
Sch. of Electr. & Inf. Eng., Jiangsu Univ., Zhenjiang, China
Abstract :
A bearingless synchronous reluctance motor (BSRM) is a nonlinear, strong-coupled complicated system. The linearization and decoupling control is a key to stable operation and practicability for BSRM. Based on the research of BSRM, the accurate mathematical model of BSRM is given in this paper. Reversibility of the model is proved, using the neural network inverse system. By using static neural network and integrator to structure BSRM neural network inverse system, the system was decoupled into two independent second-order linear displacement subsystems and a first-order linear rotor subsystem, and design the regulator to control each of the subsystems, so as to be easy to achieve the dynamic decoupling. Simulation and experimental results show the good static and dynamic decoupling performance.
Keywords :
control system synthesis; integration; linearisation techniques; neurocontrollers; nonlinear control systems; reluctance motors; rotors; BSRM; BSRM accurate mathematical model; bearingless synchronous reluctance motor; dynamic decoupling; dynamic decoupling performance; first-order linear rotor subsystem; independent second-order linear displacement subsystems; integrator; linearization control; model reversibility; neural network inverse decoupling control; nonlinear strong-coupled complicated system; regulator design; static decoupling performance; static neural network; AC motors; Educational institutions; Electronic mail; Magnetic levitation; Mathematical model; Neural networks; Reluctance motors; Bearingless Motor; Decoupling Control; Inverse System; Neural Network; Simulation;
Conference_Titel :
Control Conference (CCC), 2013 32nd Chinese
Conference_Location :
Xi´an
