An Entropy-Based Bound for the Computational Complexity of a Switched System

An Entropy-Based Bound for the Computational Complexity of a Switched System

The joint spectral radius (JSR) of a set of matrices characterizes the maximal asymptotic growth rate of an infinite product of matrices of the set. This quantity appears in a number of applications including the stability of switched and hybrid systems. A popular method used for the stability analy...

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Veröffentlicht in:IEEE transactions on automatic control 2019-11, Vol.64 (11), p.4623-4628
Hauptverfasser: Legat, Benoit, Parrilo, Pablo A., Jungers, Raphael M.
Format: Artikel
Sprache:eng
Schlagworte:
Asymptotic properties
Automata
Computational geometry
Convexity
Entropy
Hybrid systems
Joint spectral radius (JSR)
language entropy
Liapunov functions
Lyapunov methods
Optimization
path-complete Lyapunov functions
Stability analysis
sum of squares (SOS) programming
Switched systems
Switches
Switching sequences
Two dimensional displays
Upper bounds
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Beschreibung
Zusammenfassung:The joint spectral radius (JSR) of a set of matrices characterizes the maximal asymptotic growth rate of an infinite product of matrices of the set. This quantity appears in a number of applications including the stability of switched and hybrid systems. A popular method used for the stability analysis of these systems searches for a Lyapunov function with convex optimization tools. We analyze the accuracy of this method for constrained switched systems, a class of systems that has attracted increasing attention recently. We provide a new guarantee for the upper bound provided by the sum of squares implementation of the method. This guarantee relies on the p-radius of the system and the entropy of the language of allowed switching sequences. We end this paper with a method to reduce the computation of the JSR of low-rank matrices to the computation of the constrained JSR of matrices of small dimension.
ISSN:0018-9286
1558-2523
DOI:10.1109/TAC.2019.2902625