Stochastic Analysis of the LMS Algorithm for System Identification With Subspace Inputs

Author

Bershad, Neil J. ; Bermudez, José Carlos M ; Tourneret, Jean-Yves

Author_Institution

Univ. of California, Irvine

Volume

56

Issue

3

fYear

2008

fDate

3/1/2008 12:00:00 AM

Firstpage

1018

Lastpage

1027

Abstract

This paper studies the behavior of the low-rank least mean squares (LMS) adaptive algorithm for the general case in which the input transformation may not capture the exact input subspace. It is shown that the Independence Theory and the independent additive noise model are not applicable to this case. A new theoretical model for the weight mean and fluctuation behaviors is developed which incorporates the correlation between successive data vectors (as opposed to the Independence Theory model). The new theory is applied to a network echo cancellation scheme which uses partial-Haar input vector transformations. Comparison of the new model predictions with Monte Carlo simulations shows good-to-excellent agreement, certainly much better than predicted by the Independence Theory based model available in the literature.

Keywords

Monte Carlo methods; adaptive filters; echo suppression; least mean squares methods; LMS algorithm; Monte Carlo simulations; data vectors; independence theory; independent additive noise model; low-rank least mean squares adaptive algorithm; network echo cancellation scheme; partial-Haar input vector transformations; stochastic analysis; system identification; Adaptive algorithm; Adaptive filters; Algorithm design and analysis; Echo cancellers; Fluctuations; Least squares approximation; National electric code; Predictive models; Stochastic systems; System identification; Adaptive filters; least mean square methods; sparse impulse response; system identification;

fLanguage

English

Journal_Title

Signal Processing, IEEE Transactions on

Publisher

ieee

ISSN

1053-587X

Type

jour

DOI

10.1109/TSP.2007.908967

Filename

4451276