Linear Uncertain Discrete Time Delay System : A Survey (original) (raw)

Robust Stabilization of Discrete-Time Systems with Time-Varying Delay: An LMI Approach

Mathematical Problems in Engineering, 2008

Sufficient linear matrix inequality LMI conditions to verify the robust stability and to design robust state feedback gains for the class of linear discrete-time systems with time-varying delay and polytopic uncertainties are presented. The conditions are obtained through parameter-dependent Lyapunov-Krasovskii functionals and use some extra variables, which yield less conservative LMI conditions. Both problems, robust stability analysis and robust synthesis, are formulated as convex problems where all system matrices can be affected by uncertainty. Some numerical examples are presented to illustrate the advantages of the proposed LMI conditions.

LMI based control design for linear systems with distributed time delays

Archives of Control Sciences, 2012

The paper concerns the problem of stabilization of continuous-time linear systems with distributed time delays. Using extended form of the Lyapunov-Krasovskii functional candidate, the controller design conditions are derived and formulated with respect to the incidence of structured matrix variables in the linear matrix inequality formulation. The result give sufficient condition for stabilization of the system with distributed time delays. It is illustrated with a numerical example to note reduced conservatism in the system structure.

LMI approach to delay-dependent robust stability and stabilization of uncertain linear delay systems

1995

This paper considers the problems of robust stability analysis and robust control design for a class of uncertain linear systems with a constant time-delay. The uncertainty is assumed to be norm-bounded and appears in all the matrices of the state space model. We develop methods for robust stability analysis and robust stabilization. The proposed methods are dependent on the size of the delay and are given in terms of linear matrix inequalities

Robust ℋ℞ filter design for polytopic linear discrete-time delay systems via LMIs and polynomial matrices

IEEE Conference on Decision and Control and European Control Conference, 2011

This paper presents new robust linear matrix inequality conditions for full order robust H ∞ filter design of discrete-time polytopic linear systems affected by a timevarying delay. Thanks to the use of a larger number of slack variables, the proposed conditions are less conservative than the existing methods. Numerical experiments illustrate the better performance of the proposed filter design procedure when compared to other approaches available in the literature.

Robust H ∞ filter design for polytopic linear discrete-time delay systems via LMIs and polynomial matrices

2011

This paper presents new robust linear matrix inequality conditions for full order robust H ∞ filter design of discrete-time polytopic linear systems affected by a timevarying delay. Thanks to the use of a larger number of slack variables, the proposed conditions are less conservative than the existing methods. Numerical experiments illustrate the better performance of the proposed filter design procedure when compared to other approaches available in the literature.

Lmi Approach for Robust Controlof System with Uncertainty Intime Delay

International Journal of Advanced Research in Electrical, Electronics and Instrumentation Energy, 2013

Control of time delay systems has been a challenging problem for the control engineers. The issues have been inviting attention of many researchers, especially in the context of robust control. This is further motivated by the fact that many processes have the time delay present in the corresponding models and thus the design of controller becomes computationally rather involved. Time-delayed systems are pervasive in many engineering systems such as tele-robotic systems, vehicle platoons, biological systems, chemical processes etc. The presence of delay in these systems makes closed-loop stabilization difficult and degrades tracking performance. The problem becomes extremely difficult when uncertainties are present in the model as well as in the delay parameter. It is known that, in general, the delays appear in the system models due to various factors like transport phenomena, computational time needed for generation of control command, time delay in the smart measurement devices, ...

An LMI approach to stability of systems with severe time-delay

IEEE Transactions on Automatic Control, 2004

This note describes the stability problems of uncertain systems with arbitrarily time-varying and severe time-delay. Using new Lyapunov-Krasovskii functionals, less conservative stability conditions are obtained for such systems. The results are illustrated using the numerical examples based on simple linear matrix inequalities.