Iterative learning control for discrete-time systems with exponential rate of convergence

Author

Amann, N. ; Owens, D.H. ; Rogers, E.

Author_Institution

Centre for Syst. & Control Eng., Exeter Univ., UK

Volume

143

Issue

2

fYear

1996

fDate

3/1/1996 12:00:00 AM

Firstpage

217

Lastpage

224

Abstract

An algorithm for iterative learning control is proposed based on an optimisation principle used by other authors to derive gradient-type algorithms. The new algorithm is a descent algorithm and has potential benefits which include realisation in terms of Riccati feedback and feedforward components. This realisation also has the advantage of implicitly ensuring automatic step-size selection and hence guaranteeing convergence without the need for empirical choice of parameters. The algorithm achieves a geometric rate of convergence for invertible plants. One important feature of the proposed algorithm is the dependence of the speed of convergence on weight parameters appearing in the norms of the signals chosen for the optimisation problem

Keywords

convergence; discrete time systems; feedback; feedforward; intelligent control; iterative methods; matrix algebra; multidimensional systems; optimal control; optimisation; 2D systems; Riccati feedback; convergence rate; descent method; discrete-time systems; feedforward; gradient-type algorithms; iterative learning control; optimal control; optimisation; reference input tracking;

fLanguage

English

Journal_Title

Control Theory and Applications, IEE Proceedings -

Publisher

iet

ISSN

1350-2379

Type

jour

DOI

10.1049/ip-cta:19960244

Filename

487891