Paper Info
Title
Robust Stability Analysis and State Feedback Synthesis for Discrete-Time Systems Characterized by Random Polytopes.
Abstract
This paper deals with discrete-time linear systems whose state transition is determined by a sequence of random matrices having uncertain distributions. In representing random matrices with uncertain distributions, we use random polytopes whose vertices are random matrices with given fixed distributions. For such systems characterized by random polytopes, we first tackle a problem of analyzing robust second-moment exponential stability. In particular, we show a linear-matrix-inequality-based robust stability condition that can be solved through sample-based evaluation of the associated expectations. The confidence level for such sample-based analysis is ensured by the central limit theorem. Then, we extend the results about analysis toward robust stabilization state feedback synthesis in such a way that the confidence level arguments can be facilitated. We also provide numerical examples illustrating our analysis and synthesis framework.
Year
DOI
Venue
2018
10.1109/TAC.2017.2730586
IEEE Trans. Automat. Contr.
Keywords
Field
DocType
Uncertainty,Robustness,Robust stability,Stochastic systems,State feedback,Closed loop systems,Linear matrix inequalities
Applied mathematics,Mathematical optimization,Central limit theorem,Linear system,Vertex (geometry),Robustness (computer science),Polytope,Exponential stability,Discrete time and continuous time,Mathematics,Calculus,Random matrix
Journal
Volume
Issue
ISSN
63
2
0018-9286
Citations 
PageRank 
References 
2
0.47
6
Authors
3
Name
Order
Citations
PageRank
Yohei Hosoe1218.24
Tomomichi Hagiwara228653.12
Dimitri Peaucelle330931.56