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State-feedback control of systems with multiplicative noise via linear matrix inequalities. (English) Zbl 0877.93076

Summary: We consider LTI systems perturbed by parametric uncertainties, modeled as white noise disturbances. We show how to maximize, via state-feedback control, the smallest norm of the noise intensity vector producing instability in the mean square sense, using convex optimization over linear matrix inequalities. We also show how to maximize performance robustness, where performance is measured by expected output energy, with either bounded initial conditions and zero inputs (classical LQG cost), or zero initial conditions and deterministic inputs of bounded energy (a generalization of the \(H_{\infty}\) norm).

MSC:

93C99 Model systems in control theory
93B52 Feedback control
15A39 Linear inequalities of matrices
93B35 Sensitivity (robustness)
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