Title :
Mixed L2-L∞/H∞ filtering for uncertain linear systems: An LMI approach
Author :
Palhares, Reinaldo M. ; Peres, Pedro L D
Author_Institution :
Pontificia Univ. Catolica de Minas Gerais, Belo Horizonte, Brazil
Abstract :
The problem of full-order mixed L2-L∞/H∞ performance filtering design for uncertain linear systems is addressed in this paper. The uncertain parameters are assumed to belong to convex bounded domains (i.e., polytope type uncertainty). The main purpose is to design a stable linear filter such that the filtering error output signal remains bounded, using a mixed L2-L∞/H∞ performance index as criterion. In the mixed L2-L∞/H∞ filtering design, an upper bound to the peak value of the filtering error over all the energy bounded noise signals is minimized while an H∞ constraint is assured. The conditions for the existence of such a robust filter are provided in terms of linear matrix inequalities-LMIs, allowing the use of standard convex optimization procedures to solve the problem. Both continuous- and discrete-time systems are considered. The formulation presented is illustrated by one example
Keywords :
H∞ control; continuous time systems; control system synthesis; convex programming; discrete time systems; filtering theory; linear systems; matrix algebra; performance index; robust control; uncertain systems; continuous-time systems; convex bounded domains; discrete-time systems; filtering error; filtering error output signal; linear matrix inequalities approach; mixed L2-L∞/H∞ filtering; mixed L2-L∞/H∞ performance index; performance filtering design; standard convex optimization procedures; uncertain linear systems; uncertain parameters; Electronic mail; Filtering; Linear matrix inequalities; Linear systems; Noise level; Noise robustness; Nonlinear filters; Performance analysis; Uncertain systems; Upper bound;
Conference_Titel :
Industrial Electronics, 1999. ISIE '99. Proceedings of the IEEE International Symposium on
Conference_Location :
Bled
Print_ISBN :
0-7803-5662-4
DOI :
10.1109/ISIE.1999.796781
