A convex framework for the design of dynamic anti-windup for state-delayed systems

Author

Bender, F.A. ; Gomes da Silva, J.M. ; Tarbouriech, S.

Author_Institution

Dept. of Electr. Eng., UFRGS, Porto Alegre, Brazil

fYear

2010

fDate

June 30 2010-July 2 2010

Firstpage

6763

Lastpage

6768

Abstract

This work considers the design of dynamic anti-windup compensators for state-delayed systems subject to saturating actuators. Based on the use of a Lyapunov-Krasovskii approach, a generalized sector condition and some congruence transformations, an unified LMI-based framework for the synthesis of both rational and non-rational dynamic anti-windup compensators is proposed. Theoretical results to ensure the asymptotic and the input-to-state stabilities of the closed-loop system are presented both in local as well as global contexts. The proposed conditions are cast in convex optimization problems to compute anti-windup compensators aiming at maximizing the bound of admissible ℒ₂ disturbances or maximizing the ℒ₂-gain from the disturbance to the regulated output. A numerical example illustrates the application of the methodology.

Keywords

Lyapunov methods; asymptotic stability; closed loop systems; compensation; control system synthesis; convex programming; delay systems; linear matrix inequalities; LMI-based framework; Lyapunov-Krasovskii approach; asymptotic stability; closed-loop system; congruence transformation; convex optimization; input-to-state stability; nonrational dynamic antiwindup compensator; saturating actuator; state-delayed system; system design; Actuators; Asymptotic stability; Attenuation; Control system synthesis; Control systems; Degradation; Delay; Design optimization; Feedback control; Open loop systems;

fLanguage

English

Publisher

ieee

Conference_Titel

American Control Conference (ACC), 2010

Conference_Location

Baltimore, MD

ISSN

0743-1619

Print_ISBN

978-1-4244-7426-4

Type

conf

DOI

10.1109/ACC.2010.5531620

Filename

5531620