Identifying chaotic systems via a Wiener-type cascade model

Author

Chen, Guanrong ; Chen, Ying ; Ogmen, Haluk

Author_Institution

Dept. of Electr. & Comput. Eng., Houston Univ., TX, USA

Volume

17

Issue

5

fYear

1997

fDate

10/1/1997 12:00:00 AM

Firstpage

29

Lastpage

36

Abstract

In this article we first show a theory that the Wiener-type cascade dynamical model, in which a simple linear plant is used as the dynamic subsystem and a three-layer feedforward artificial neural network is employed as the nonlinear static subsystem, can uniformly approximate a continuous trajectory of a general nonlinear dynamical system with arbitrarily high precision on a compact time domain. We then report some successful simulation results, by training the neural network using a model-reference adaptive control method, for identification of continuous-time and discrete-time chaotic systems, including the typical Duffing, Henon, and Lozi systems. This Wiener-type cascade structure is believed to have great potential for chaotic dynamics identification, control and synchronization

Keywords

adaptive control; cascade systems; chaos; continuous time systems; discrete time systems; feedforward neural nets; identification; model reference adaptive control systems; neurocontrollers; nonlinear dynamical systems; time-domain analysis; Duffing system; Henon system; Lozi systems; MIMO model; Wiener-type cascade model; chaotic systems; continuous-time system; discrete-time system; dynamic subsystem; feedforward neural network; identification; model-reference adaptive control; nonlinear dynamical system; nonlinear static subsystem; time domain; Adaptive control; Artificial neural networks; Chaos; Feedback loop; Feedforward systems; Jacobian matrices; Kernel; Neural networks; Nonlinear dynamical systems; Recurrent neural networks;

fLanguage

English

Journal_Title

Control Systems, IEEE

Publisher

ieee

ISSN

1066-033X

Type

jour

DOI

10.1109/37.621467

Filename

621467