Periodically time-varying memory state-feedback controller synthesis for discrete-time linear systems

Periodically time-varying memory state-feedback controller synthesis for discrete-time linear systems

In this paper, we deal with discrete-time linear periodic/time-invariant systems with polytopic-type uncertainties and propose a new linear matrix inequality (LMI)-based method for robust state-feedback controller synthesis. In stark contrast with existing approaches that are confined to memoryless...

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Bibliographic Details
Published in:Automatica (Oxford) Vol. 47; no. 1; pp. 14 - 25
Main Authors: Ebihara, Yoshio, Peaucelle, Dimitri, Arzelier, Denis
Format: Journal Article
Language:English
Published: Kidlington Elsevier Ltd 01-01-2011
Elsevier
Subjects:
Applied sciences
Computer science; control theory; systems
Control system analysis
Control system synthesis
Control theory. Systems
Discrete-time linear systems
Exact sciences and technology
Linear matrix inequalities
Periodic controllers
Polytopic uncertainties
Robust control
Robust control
Periodic controllers
Linear matrix inequalities
Discrete-time linear systems
Polytopic uncertainties
Polytope
State feedback
Feedback regulation
Control synthesis
Periodic control
Time varying system
Linear time invariant system
Uncertain system
Discrete time
Linear matrix inequality
Invarying system
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Summary:In this paper, we deal with discrete-time linear periodic/time-invariant systems with polytopic-type uncertainties and propose a new linear matrix inequality (LMI)-based method for robust state-feedback controller synthesis. In stark contrast with existing approaches that are confined to memoryless static controller synthesis, we explore dynamical controller synthesis and reveal a particular periodically time-varying memory state-feedback controller (PTVMSFC) structure that allows LMI-based synthesis. In the context of robust controller synthesis, we prove rigorously that the proposed design method encompasses the well-known extended-LMI-based static controller synthesis methods as particular cases. Through numerical experiments, we demonstrate that the suggested design method is indeed effective in achieving less conservative results, under both periodic and time-invariant settings. We finally derive a viable test to verify that the designed robust PTVMSFC is “exact” in the sense that it attains the best achievable robust performance. This exactness verification test works fine in practice, and we will show via a numerical example that exact robust control is indeed attained by designing PTVMSFCs, even for such a problem where the standard memoryless static state-feedback fails.
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ISSN:0005-1098
1873-2836
DOI:10.1016/j.automatica.2010.10.004