Your search keyword '"TIME-INVARIANT UNCERTAINTY"' showing total 5 results

1. Stability of uncertain systems using Lyapunov functions with non-monotonic terms.

Author

Lacerda, Márcio J. and Seiler, Peter

Subjects

*UNCERTAIN systems, *LYAPUNOV functions, *MONOTONIC functions, *INVARIANT subspaces, *POLYTOPES

Abstract

This paper is concerned with the problem of robust stability of uncertain linear time-invariant systems in polytopic domains. The main contribution is to present a systematic procedure to check the stability of the uncertain systems by using an arbitrary number of quadratic functions within higher order derivatives of the vector field in the continuous-time case and higher order differences of the vector field in the discrete-time case. The matrices of the Lyapunov function appear decoupled from the dynamic matrix of the system in the conditions. This fact leads to sufficient conditions that are given in terms of Linear Matrix Inequalities defined at the vertices of the polytope. The proposed method does not impose sign condition constraints in the quadratic functions that compose the Lyapunov function individually. Moreover, some of the quadratic functions do not decrease monotonically along trajectories. However, if the sufficient conditions are satisfied, then a monotonic standard Lyapunov function that depends on the dynamics of the uncertain system can be constructed a posteriori . Numerical examples from the literature are provided to illustrate the proposed approach. [ABSTRACT FROM AUTHOR]

Published

2017

2. Delay‐dependent robust ℋ∞ filter design for state‐delayed discrete‐time linear systems via homogeneous polynomial matrices.

Author

Lacerda, Márcio J., Leite, Valter J.S., Oliveira, Ricardo C.L.F., and Peres, Pedro L.D.

Abstract

This study presents new robust linear matrix inequality (LMI) conditions for robust ℋ∞ full‐order filter design of discrete‐time linear systems affected by time‐invariant uncertainty and a time‐varying state delay. Thanks to the use of a larger number of slack variables, the proposed robust LMI conditions contain and generalise other results from the literature. LMI relaxations based on homogeneous polynomial matrices of arbitrary degree are used to determine the state‐space realisation of the full‐order filter, that can also be implemented with delayed state terms whenever the time‐delay is available in real time. As another contribution, an iterative LMI‐based procedure involving the decision variables is proposed to improve the ℋ∞ filter performance. Numerical experiments illustrate the better performance of the proposed filter when compared to other approaches available in the literature. [ABSTRACT FROM AUTHOR]

Published

2013

3. LMI conditions for robust stability analysis based on polynomially parameter-dependent Lyapunov functions

Author

Oliveira, Ricardo C.L.F. and Peres, Pedro L.D.

Subjects

*MATRICES (Mathematics), *DIFFERENTIAL equations, *LYAPUNOV functions, *LINEAR systems

Abstract

Abstract: The robust stability of uncertain linear systems in polytopic domains is investigated in this paper. The main contribution is to provide a systematic procedure for generating sufficient robust stability linear matrix inequality conditions based on homogeneous polynomially parameter-dependent Lyapunov matrix functions of arbitrary degree on the uncertain parameters. The conditions exploit the positivity of the uncertain parameters, being constructed in such a way that: as the degree of the polynomial increases, the number of linear matrix inequalities and free variables increases and the test becomes less conservative; if a feasible solution exists for a certain degree, the conditions will also be verified for larger degrees. For any given degree, the feasibility of a set of linear matrix inequalities defined at the vertices of the polytope assures the robust stability. Both continuous and discrete-time uncertain systems are addressed, as illustrated by numerical examples. [Copyright &y& Elsevier]

Published

2006

4. Static Output Feedback Control Synthesis for Linear Systems With Time-Invariant Parametric Uncertainties.

Author

Jiuxiang Dong and Guang-Hong Yang

Subjects

*ROBUST control, *AUTOMATIC control systems, *FEEDBACK control systems, *DISCRETE-time systems, *STATICS, *LINEAR systems, *MATRICES (Mathematics), *MATHEMATICAL inequalities, *ELECTRONICS

Abstract

This technical note is concerned with the problem of designing robust static output feedback controllers for linear discrete and continuous-time systems with time-invariant polytopic uncertainties. Sufficient conditions for static output feedback stabilizing controller designs are given in terms of solutions to a set of linear matrix inequalities. Furthermore, the results are also extended to H2 static output feedback controller designs. Numerical examples are given to illustrate the effectiveness of the proposed design methods. [ABSTRACT FROM AUTHOR]

Published

2007

5. Parameter-Dependent LMIs in Robust Analysis: Characterization of Homogeneous Polynomially Parameter-Dependent Solutions Via LMI Relaxations.

Author

Oliveira, Ricardo C. L. F. and Peres, Pedro L. D.

Subjects

*LINEAR time invariant systems, *LINEAR systems, *DISCRETE-time systems, *RELAXATION for health, *LYAPUNOV functions, *DIFFERENTIAL equations

Abstract

This note investigates the robust stability of uncertain linear time-invariant systems in polytopic domains by means of parameter-dependent linear matrix inequality (PD-LMI) conditions, exploiting some algebraic properties provided by the uncertainty representation. A systematic procedure to construct a family of finite-dimensional LMI relaxations is provided. The robust stability is assessed by means of the existence of a Lyapunov function, more specifically, a homogeneous polynomially parameter-dependent Lyapunov (HPPDL) function of arbitrary degree. For a given degree g, if an HPPDL solution exists, a sequence of relaxations based on real algebraic properties provides sufficient LMI conditions of increasing precision and constant number of decision variables for the existence of an HPPDL function which tend to the necessity. Alternatively, if an HPPDL solution of degree g exists, a sequence of relaxations which increases the number of variables and the number of LMIs will provide an HPPDL solution of larger degree. The method proposed can be applied to determine homogeneous parameter-dependent matrix solutions to a wide variety of PD-LMIs by transforming the infinite-dimensional LMI problem described in terms of uncertain parameters belonging to the unit simplex in a sequence of finite-dimensional LMI conditions which converges to the necessary conditions for the existence of a homogeneous polynomially parameter-dependent solution of arbitrary degree. Illustrative examples show the efficacy of the proposed conditions when compared with other methods from the literature. [ABSTRACT FROM AUTHOR]

Published

2007