The very strict positive real lemma is further developed for nonminimal 1-D continuous-time systems and is used to study the 2-D continuous-time Lyapunov equation. Based on it, an extended condition for the bivariate characteristic polynomial of a matrix to be very strict Hurwitz is proposed for general 2-D analog systems with characteristic polynomials involving 1-D factor polynomials. It is also shown that in such a case the bivariate polynomial can be decomposed into a 2-D bivariate polynomial with the corresponding matrix satisfying certain controllability and observability conditions and into up to two 1-D polynomials. Further, two algorithms for computing the positive definite solutions to the 2-D Lyapunov equation are presented.link_...
We give necessary and sufficient conditions, based on the existence of a Lyapunov functional, for th...
International audienceThis paper is concerned with the analysis and synthesis of linear positive sys...
Abstract. We consider the generalized continuous-time Lyapunov equation: A∗XB + B∗XA = −Q, where Q i...
The discrete-time bounded-real lemma is further developed for nonminimal digital systems. Based on t...
An alwaysvalid upper matrix bound for the solution of the continuous Lyapunov equation is proposed. ...
This paper addresses the problem of establishing stability of 2D mixed continuous-discrete-time syst...
For a given linear continuous-time dynamic system x equals Ax plus Bu, sufficient conditions are det...
Two models of positive 2D discrete-time linear Lyapunov systems are introduced. For both the models ...
In this paper, exponential stabilizability of continuous-time positive switched systems is investiga...
Continuous-time positive systems, switching among p subsystems whose matrices differ by a rank one m...
Motivated by the fact that upper solution bounds of the continuous Lyapunov equation are valid under...
In this paper, exponential stabilizability of continuous-time positive switched systems is investiga...
This paper proposes necessary and sufficient conditions for stability and performance analysis of 2-...
Periodic Lyapunov differential equations can be used to formulate robust optimal periodic control pr...
Continuous-time positive systems, switching among p subsystems whose matrices differ by a rank one m...
We give necessary and sufficient conditions, based on the existence of a Lyapunov functional, for th...
International audienceThis paper is concerned with the analysis and synthesis of linear positive sys...
Abstract. We consider the generalized continuous-time Lyapunov equation: A∗XB + B∗XA = −Q, where Q i...
The discrete-time bounded-real lemma is further developed for nonminimal digital systems. Based on t...
An alwaysvalid upper matrix bound for the solution of the continuous Lyapunov equation is proposed. ...
This paper addresses the problem of establishing stability of 2D mixed continuous-discrete-time syst...
For a given linear continuous-time dynamic system x equals Ax plus Bu, sufficient conditions are det...
Two models of positive 2D discrete-time linear Lyapunov systems are introduced. For both the models ...
In this paper, exponential stabilizability of continuous-time positive switched systems is investiga...
Continuous-time positive systems, switching among p subsystems whose matrices differ by a rank one m...
Motivated by the fact that upper solution bounds of the continuous Lyapunov equation are valid under...
In this paper, exponential stabilizability of continuous-time positive switched systems is investiga...
This paper proposes necessary and sufficient conditions for stability and performance analysis of 2-...
Periodic Lyapunov differential equations can be used to formulate robust optimal periodic control pr...
Continuous-time positive systems, switching among p subsystems whose matrices differ by a rank one m...
We give necessary and sufficient conditions, based on the existence of a Lyapunov functional, for th...
International audienceThis paper is concerned with the analysis and synthesis of linear positive sys...
Abstract. We consider the generalized continuous-time Lyapunov equation: A∗XB + B∗XA = −Q, where Q i...