Adaptive neural tracking control of pure-feedback nonlinear systems

Author

Zhang, Tianping ; Zhu, Baicheng ; Shi, Xiaocheng

Author_Institution

Dept. of Autom., Yangzhou Univ., Yangzhou, China

fYear

2012

fDate

23-25 May 2012

Firstpage

2122

Lastpage

2127

Abstract

In this paper, an novel adaptive tracking control is developed for a class of completely non-affine pure-feedback nonlinear systems using radial basis function neural networks (RBFNNs). Combining the dynamic surface control (DSC) technique and backstepping method, the explosion of complexity in the traditional backstepping design is avoided. Using mean value theorem and Young´s inequality, only one learning parameter need to be tuned online in the whole controller design, and the computational burden is effectively alleviated. It is proved that the proposed design method is able to guarantee semi-global uniform ultimate boundedness (SGUUB) of all signals in the closed-loop system. Simulation results verify the effectiveness of the proposed approach.

Keywords

adaptive control; closed loop systems; control system synthesis; feedback; neurocontrollers; nonlinear control systems; radial basis function networks; RBFNN; Young´s inequality; adaptive neural tracking control; backstepping method; closed-loop system; complexity explosion; controller design; dynamic surface control technique; mean value theorem; nonaffine pure-feedback nonlinear systems; radial basis function neural networks; semiglobal uniform ultimate boundedness; Adaptive control; Backstepping; Closed loop systems; Nonlinear systems; Radial basis function networks; Adaptive Control; Dynamic Surface Control; Neural Networks; Pure-Feedback Nonlinear Systems;

fLanguage

English

Publisher

ieee

Conference_Titel

Control and Decision Conference (CCDC), 2012 24th Chinese

Conference_Location

Taiyuan

Print_ISBN

978-1-4577-2073-4

Type

conf

DOI

10.1109/CCDC.2012.6244340

Filename

6244340