Title :
Inverse System Decoupling Control for Induction Motor Based on Neural Network On-Line Learning
Author :
Ni Wei ; Zhang Yu
Author_Institution :
Dept. of Electron. & Inf. Eng., Huaiyin Inst. of Technol., Huaiyin, China
Abstract :
The induction motor is a MIMO, nonlinear and high coupling system. The reversibility of the induction motor is testified. Consequently, a pseudo-linear system is completed by constructing a neural network inverse (NNI) system and combining it with the motor system. The inverse can transform the MIMO nonlinear system into two SISO linear subsystems (i.e., rotor speed and flux subsystems). In order to approach the inversion exactly in operation of the motor, the control method online learning based on NNI system is proposed, in which connection value can be amended continuously on-line to make the NN adapt to the changes of environment to strengthen its robustness. Simulation and experiment results have shown that NN can be adjusted in the control process. The good applicability of NN along with the strong stability and robustness of the system can be achieved by using the proposed method.
Keywords :
MIMO systems; induction motors; learning (artificial intelligence); linear systems; machine control; neurocontrollers; nonlinear control systems; robust control; MIMO nonlinear system; NNI system; SISO linear subsystem; high coupling system; induction motor; inverse system decoupling control; motor system; neural network inverse system; neural network on-line learning; pseudolinear system; robustness; stability; Control systems; Couplings; Induction motors; MIMO; Neural networks; Nonlinear systems; Robust control; Robust stability; Rotors; Testing; induction motor; inverse system; neural network; on-line learning;
Conference_Titel :
Measuring Technology and Mechatronics Automation, 2009. ICMTMA '09. International Conference on
Conference_Location :
Zhangjiajie, Hunan
Print_ISBN :
978-0-7695-3583-8
DOI :
10.1109/ICMTMA.2009.482
