Looping LMS versus fast least squares algorithms: who gets there first?

Author

Alberi, M.L. ; Casas, R.A. ; Fijalkow, I. ; Johnson, C.R., Jr.

Author_Institution

ETIS, Cergy-Pontoise, France

fYear

1999

fDate

1999

Firstpage

296

Lastpage

299

Abstract

This paper analytically compares, in terms of the convergence time, fast least squares estimation algorithms for channel identification and equalization to looping LMS (LLMS), a scheme which repeatedly applies the least mean squares algorithm to a block of received data. In this study, the convergence time is defined as the actual time (in seconds) taken by an algorithm to reach a desired performance. The old theme on LMS and fast least squares algorithms convergence is revisited from a novel perspective: the comparison is made from a complexity viewpoint, which not only takes into account the statistical properties of studied algorithms but also the number of floating point operations

Keywords

Wiener filters; adaptive equalisers; computational complexity; convergence of numerical methods; filtering theory; floating point arithmetic; identification; land mobile radio; least mean squares methods; least squares approximations; statistical analysis; ISI; Wiener filtering; channel equalization; channel identification; complexity; convergence time; fast Kalman algorithm; fast least squares estimation algorithm; floating point operations; least mean squares algorithm; linear adaptive algorithms; looping LMS; looping LMS algorithm; mobile communications; statistical properties; Convergence; Distortion; Intersymbol interference; Iterative algorithms; Kalman filters; Least squares approximation; Least squares methods; Resonance light scattering; Signal processing algorithms; Wiener filter;

fLanguage

English

Publisher

ieee

Conference_Titel

Signal Processing Advances in Wireless Communications, 1999. SPAWC '99. 1999 2nd IEEE Workshop on

Conference_Location

Annapolis, MD

Print_ISBN

0-7803-5599-7

Type

conf

DOI

10.1109/SPAWC.1999.783077

Filename

783077