Adaptive filter theory (3rd ed.)
Adaptive filter theory (3rd ed.)
Abstract Optimal Linear Filtering
SIAM Journal on Control and Optimization
Adaptive Filters
Filtering and compression for infinite sets of stochastic signals
Signal Processing
Computational Methods for Modeling of Nonlinear Systems
Computational Methods for Modeling of Nonlinear Systems
Generic weighted filtering of stochastic signals
IEEE Transactions on Signal Processing
Estimating a covariance matrix from incomplete realizations of arandom vector
IEEE Transactions on Signal Processing
A Method for Recursive Least Squares Filtering Based Upon an Inverse QR Decomposition
IEEE Transactions on Signal Processing
IEEE Transactions on Signal Processing
Decoding real block codes: activity detection Wiener estimation
IEEE Transactions on Information Theory
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We propose an approach to the filtering of infinite sets of stochastic signals, K"Y and K"X. The known Wiener-type approach cannot be applied to infinite sets of signals. Even in the case when K"Y and K"X are finite sets, the computational work associated with the Wiener approach becomes unreasonably hard. To avoid such difficulties, a new theory is studied. The problem addressed is as follows. Given two infinite sets of stochastic signals, K"Y and K"X, find a single filter F:K"Y-K"X that estimates signals from K"Y with a controlled associated error. Our approach is based on exploiting a signal interpolation idea. The proposed filter F is represented in the form of a sum of p terms, F(y)=@?"j"="1^pT"jR"jQ"j(y). Each term is derived from three operations presented by matrices, Q"i, R"i and T"i with i=1,...,p. Each operation is a special stage of the filtering aimed at facilitating the associated numerical work. In particular, Q"1,...,Q"p are used to transform an observable signal y@?K"Y to p different signals. Matrices R"1,...,R"p reduce a set of related matrix equations to p independent equations. Their solution requires much less computational effort than would be required with the full set of matrix equations. Matrices T"i,...,T"p are determined from interpolation conditions. We show that the proposed filter is asymptotically optimal. Moreover, the filter model is determined in terms of pseudo-inverse matrices and, therefore, it always exists.