Regular Papers
International Journal of Control, Automation and Systems 2004; 2(1): 83-91
© The International Journal of Control, Automation, and Systems
Neural Network-Based System Identification and Controller Synthesis for an Industrial Sewing Machine
The purpose of this paper is to obtain an accurate nonlinear system model to test various control schemes for a motion control system that requires high speed, robustness and accuracy. An industrial sewing machine equipped with a Brushless DC motor is considered. It is modeled by a neural network that is configured as an output-error dynamical system. The identified model is essentially a one step ahead prediction structure in which past inputs and outputs are used to calculate the current output. Using the model, a 2 degree-of-freedom PID controller to compensate the effects of disturbance without degrading tracking performance has been de-signed. In this experiment, it is not preferable for safety reasons to tune the controller online on the actual machinery. Experimental results confirm that the model is a good approximation of sewing machine dynamics and that the proposed control methodology is effective.
Keywords 2 DOF PID controller, genetic algorithm, neural network, system identification.
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Regular Papers
International Journal of Control, Automation and Systems 2004; 2(1): 83-91
Published online March 1, 2004
Copyright © The International Journal of Control, Automation, and Systems.
Neural Network-Based System Identification and Controller Synthesis for an Industrial Sewing Machine
Il-Hwan Kim, Stanley Fok, Kingsley Fregene, Dong-Hoon Lee, Tae-Seok Oh, and David W. L. Wang
Department of Electrical and Computer Engineering, Kangwon National University
Abstract
The purpose of this paper is to obtain an accurate nonlinear system model to test various control schemes for a motion control system that requires high speed, robustness and accuracy. An industrial sewing machine equipped with a Brushless DC motor is considered. It is modeled by a neural network that is configured as an output-error dynamical system. The identified model is essentially a one step ahead prediction structure in which past inputs and outputs are used to calculate the current output. Using the model, a 2 degree-of-freedom PID controller to compensate the effects of disturbance without degrading tracking performance has been de-signed. In this experiment, it is not preferable for safety reasons to tune the controller online on the actual machinery. Experimental results confirm that the model is a good approximation of sewing machine dynamics and that the proposed control methodology is effective.
Keywords: 2 DOF PID controller, genetic algorithm, neural network, system identification.
Vol. 23, No. 3, pp. 683~972
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