Reducing the computational demands of continually online trained artificial neural networks for system identification and control of fast processes

Author

Burton, Bruce ; Harley, Ronald G.

Author_Institution

Dept. of Electr. Eng., Natal Univ., Durban, South Africa

fYear

1994

fDate

2-6 Oct 1994

Firstpage

1836

Abstract

This paper describes many of the generic factors which influence the computational demands of continually online trained backpropagation artificial neural networks (ANNs) used to identify and control fast processes. The limitations of even parallel hardware in meeting these demands is discussed. An adaptive online trained artificial neural network induction machine stator current controller is considered as a typical fast process. Various modifications are made to the ANN structure to lower computational demands and increase ANN parallelism. The effects of these modifications on the overall controller stability and performance are illustrated by means of simulation results

Keywords

adaptive control; backpropagation; electric current control; feedforward neural nets; identification; induction motors; machine control; power system analysis computing; stability; stators; ANN; adaptive stator current controller; backpropagation; computational demands reduction; continually online trained artificial neural networks; controller performance; controller stability; fast processes control; induction machine stator current controller; parallel hardware limitations; system identification; Adaptive control; Artificial neural networks; Backpropagation; Computer networks; Concurrent computing; Hardware; Induction machines; Process control; Programmable control; Stators;

fLanguage

English

Publisher

ieee

Conference_Titel

Industry Applications Society Annual Meeting, 1994., Conference Record of the 1994 IEEE

Conference_Location

Denver, CO

Print_ISBN

0-7803-1993-1

Type

conf

DOI

10.1109/IAS.1994.377679

Filename

377679