Title :
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
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;
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
DOI :
10.1109/SPAWC.1999.783077
