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Main Authors: Katsanikakis, Andreas, Bekiaris-Liberis, Nikolaos, Bresch-Pietri, Delphine
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2410.22044
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author Katsanikakis, Andreas
Bekiaris-Liberis, Nikolaos
Bresch-Pietri, Delphine
author_facet Katsanikakis, Andreas
Bekiaris-Liberis, Nikolaos
Bresch-Pietri, Delphine
contents We develop an input delay-compensating feedback law for linear switched systems with time-dependent switching. Because the future values of the switching signal, which are needed for constructing an exact predictor-feedback law, may be unavailable at current time, the key design challenge is how to construct a proper predictor state. We resolve this challenge constructing an average predictor-based feedback law, which may be viewed as an exact predictor-feedback law for a particular average system without switching. We establish that, under the predictor-based control law introduced, the closed-loop system is exponentially stable, provided that the plant's parameters are sufficiently close to the corresponding parameters of the average system. In particular, the allowable difference is inversely proportional to the size of delay and proportional to the dwell time of the switching signal. Since no restriction is imposed on the size of delay or dwell time themselves, such a limitation on the parameters of each mode is inherent to the problem considered (in which no a priori information on the switching signal is available), and thus, it cannot be removed. The stability proof relies on two main ingredients-a Lyapunov functional constructed via backstepping and derivation of solutions' estimates for the difference between the average and the exact predictor states. We present consistent, numerical simulation results, which illustrate the necessity of employing the average predictor-based law for achieving stabilization and desired performance of the closed-loop system.
format Preprint
id arxiv_https___arxiv_org_abs_2410_22044
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Average Predictor-Feedback Control Design for Switched Linear Systems
Katsanikakis, Andreas
Bekiaris-Liberis, Nikolaos
Bresch-Pietri, Delphine
Systems and Control
We develop an input delay-compensating feedback law for linear switched systems with time-dependent switching. Because the future values of the switching signal, which are needed for constructing an exact predictor-feedback law, may be unavailable at current time, the key design challenge is how to construct a proper predictor state. We resolve this challenge constructing an average predictor-based feedback law, which may be viewed as an exact predictor-feedback law for a particular average system without switching. We establish that, under the predictor-based control law introduced, the closed-loop system is exponentially stable, provided that the plant's parameters are sufficiently close to the corresponding parameters of the average system. In particular, the allowable difference is inversely proportional to the size of delay and proportional to the dwell time of the switching signal. Since no restriction is imposed on the size of delay or dwell time themselves, such a limitation on the parameters of each mode is inherent to the problem considered (in which no a priori information on the switching signal is available), and thus, it cannot be removed. The stability proof relies on two main ingredients-a Lyapunov functional constructed via backstepping and derivation of solutions' estimates for the difference between the average and the exact predictor states. We present consistent, numerical simulation results, which illustrate the necessity of employing the average predictor-based law for achieving stabilization and desired performance of the closed-loop system.
title Average Predictor-Feedback Control Design for Switched Linear Systems
topic Systems and Control
url https://arxiv.org/abs/2410.22044