Title :
Wiener filter design using polynomial equations
Author :
Ahlén, Anders ; Sternad, Mikael
Author_Institution :
Dept. of Technol., Uppsala Univ., Sweden
fDate :
11/1/1991 12:00:00 AM
Abstract :
A simplified way of deriving realizable and explicit Wiener filters is presented. Discrete-time problems are discussed in a polynomial equation framework. Optimal filters, predictors, and smoothers are calculated by means of spectral factorizations and linear polynomial equations. A tool for obtaining these equations, for a given problem structure, is described. It is based on the evaluation of orthogonality in the frequency domain, by means of canceling stable poles with zeros. Comparisons are made to previously known derivation methodologies such as completing the squares for the polynomial systems approach and the classical Wiener solution. The simplicity of the proposed derivation method is particularly evident in multistage filtering problems. To illustrate, two examples are discussed: a filtering and a generalized deconvolution problem. A new solvability condition for linear polynomial equation appearing in scalar problems is also presented
Keywords :
discrete time systems; filtering and prediction theory; frequency-domain analysis; poles and zeros; polynomials; signal processing; Wiener filters; discrete time problems; frequency domain; generalized deconvolution problem; multistage filtering problems; orthogonality; poles; polynomial equations; predictors; signal processing; smoothers; spectral factorizations; zeros; Control systems; Equations; Filtering; IIR filters; Kalman filters; Nonlinear filters; Polynomials; Smoothing methods; Transfer functions; Wiener filter;
Journal_Title :
Signal Processing, IEEE Transactions on
