単一の不確定パラメータを有する線形時不変系のロバストH_∞性能解析: 双対LMIに基づく緩和問題の漸近的に厳密な階層的構成と非漸近的な厳密性検証

Translated title of the contribution: Robust H_∞ Performance Analysis of LTI Systems with a Single Uncertain Parameter: Asymptotically Exact Construction of a Sequence of Relaxation Problems via Dual LMIs and Non-Asymptotic Exactness Verification

松田 雄介, 田原 雅人, 蛯原 義雄, 萩原 朋道

Research output: Contribution to journalArticlepeer-review

Abstract

This paper addresses the robust <i>H</i><sub>∞</sub> performance analysis problem of linear time-invariant (LTI) systems whose state-space coefficient matrices depend polynomially on a single uncertain parameter. By means of a dual LMI that characterizes the <i>H</i><sub>∞</sub> performance of uncertainty-free LTI systems, we firstly formulate this analysis problem as a polynomial matrix inequality (PMI) optimization problem. However, this PMI problem is non-convex and hence intractable in general. Therefore, we apply linearization and construct an infinite sequence of relaxation problems, represented by SDPs, with theoretical guarantee of asymptotic exactness in the limit. In order to detect whether an arbitrary relaxation problem in the sequence is “exact” in the sense that it provides the same optimal value as that of the original problem, we derive a rank condition on the SDP solution under which we can conclude the exactness.<br>
Translated title of the contributionRobust H_∞ Performance Analysis of LTI Systems with a Single Uncertain Parameter: Asymptotically Exact Construction of a Sequence of Relaxation Problems via Dual LMIs and Non-Asymptotic Exactness Verification
Original languageJapanese
Pages (from-to)46-55
Number of pages10
Journalシステム制御情報学会論文誌
Volume23
Issue number3
DOIs
Publication statusPublished - Mar 15 2010

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