Title :
A robust algorithm for blind space-time equalization
Author :
Silva, Magno T M ; Miranda, Maria D. ; Licciardi, Antonio N., Jr.
Author_Institution :
EPUSP-PTC, Sao Paulo Univ., Brazil
Abstract :
The efficient separation of signals is a frequent problem in multiuser communication systems. Among many algorithms for blind deconvolution of a multiple-input multiple-output (MIMO) system, the one that utilizes higher-order cumulants has advantages in regards to convergence rate. Inspired by this algorithm, and on a stochastic gradient approach, we propose an algorithm with the capacity of recovering simultaneously all sources, denoted as MU-SWA (multiuser Shalvi-Weinstein algorithm). Based on the steady-state analysis, recently presented by Luo and Chambers for the multiuser constant modulus algorithm, we derive the expression for the mean-square error of MU-SWA. Simulation results show that MU-SWA presents a more robust behavior with respect to convergence rate and tracking capability when compared to others known algorithms for blind multiuser equalization.
Keywords :
MIMO systems; blind equalisers; blind source separation; convergence of numerical methods; deconvolution; gradient methods; higher order statistics; mean square error methods; multiuser channels; MIMO system blind deconvolution; MU-SWA mean-square error; blind multiuser equalization; blind space-time equalization; convergence rate; higher-order cumulants; multiuser Shalvi-Weinstein algorithm; multiuser constant modulus algorithm; multiuser signal separation; signal recovery; source recovery; stochastic gradient method; tracking capability; Algorithm design and analysis; Blind equalizers; Convergence; Deconvolution; Finite impulse response filter; MIMO; Mobile communication; Robustness; Steady-state; Stochastic processes;
Conference_Titel :
Acoustics, Speech, and Signal Processing, 2004. Proceedings. (ICASSP '04). IEEE International Conference on
Print_ISBN :
0-7803-8484-9
DOI :
10.1109/ICASSP.2004.1326962
