Title :
Optimal design of IIR digital filters with robust stability using conic-quadratic-programming updates
Author :
Lu, Wu-Sheng ; Hinamoto, Takao
Author_Institution :
Dept. of Electr. & Comput. Eng., Victoria Univ., BC, Canada
fDate :
6/1/2003 12:00:00 AM
Abstract :
In this paper, minimax design of infinite-impulse-response (IIR) filters with prescribed stability margin is formulated as a conic quadratic programming (CQP) problem. CQP is known as a class of well-structured convex programming problems for which efficient interior-point solvers are available. By considering factorized denominators, the proposed formulation incorporates a set of linear constraints that are sufficient and near necessary for the IIR filter to have a prescribed stability margin. A second-order cone condition on the magnitude of each update that ensures the validity of a key linear approximation used in the design is also included in the formulation and eliminates a line-search step. Collectively, these features lead to improved designs relative to several established methods. The paper then moves on to extend the proposed design methodology to quadrantally symmetric two-dimensional (2-D) digital filters. Simulation results for both one-dimensional (1-D) and 2-D cases are presented to illustrate the new design algorithms and demonstrate their performance in comparison with several existing methods.
Keywords :
IIR filters; convex programming; quadratic programming; stability; two-dimensional digital filters; 2-D cases; CQP problem; IIR digital filters; IIR filter; conic-quadratic-programming updates; infinite-impulse-response filters; interior-point solvers; line-search step; linear approximation; linear constraints; minimax design; one-dimensional cases; optimal design; quadrantally symmetric two-dimensional digital filters; robust stability; second-order cone condition; well-structured convex programming problems; Constraint optimization; Design methodology; Design optimization; Digital filters; IIR filters; Minimax techniques; Quadratic programming; Robust stability; Transfer functions; Two dimensional displays;
Journal_Title :
Signal Processing, IEEE Transactions on
DOI :
10.1109/TSP.2003.811229
