Using a learning controller to achieve accurate linear motor motion control

Author

Hu, Ai-Ping ; Register, Andy ; Sadegh, Nader

Author_Institution

Sch. of Mech. Eng., Georgia Inst. of Technol., Atlanta, GA, USA

fYear

1999

fDate

1999

Firstpage

611

Lastpage

616

Abstract

The development and experimental implementation of a learning controller for achieving accurate (on the order of micrometers) linear motor motion control of a rigid mass is presented. The learning controller employs (1) neural networks with local basis functions to approximate system nonlinearities, and thus compensate for them, and (2) a linear control component consisting of both feedback and feedforward terms. The significant nonlinearities present in our system are established to be friction, cogging, and torque ripple. It is assumed that detailed knowledge of these nonlinearities is not available. Experimental results demonstrate that the proposed learning controller is able to significantly reduce trajectory tracking errors when compared to a standard controller

Keywords

DC motors; feedback; feedforward; friction; learning systems; linear motors; machine control; motion control; neurocontrollers; position control; servomotors; accurate linear motor motion control; cogging; friction; learning controller; local basis functions; system nonlinearities; torque ripple; trajectory tracking errors; Control nonlinearities; Control systems; Feedforward neural networks; Linear feedback control systems; Micromotors; Motion control; Neural networks; Neurofeedback; Nonlinear control systems; Weight control;

fLanguage

English

Publisher

ieee

Conference_Titel

Advanced Intelligent Mechatronics, 1999. Proceedings. 1999 IEEE/ASME International Conference on

Conference_Location

Atlanta, GA

Print_ISBN

0-7803-5038-3

Type

conf

DOI

10.1109/AIM.1999.803238

Filename

803238