Kurtosis-based criteria for adaptive blind source separation

Author

Papadias, Constantinos B.

Author_Institution

Lucent Technol., AT&T Bell Labs., Holmdel, NJ, USA

Volume

4

fYear

1998

fDate

12-15 May 1998

Firstpage

2317

Abstract

We consider the problem of separating adaptively p synchronous user signals that are received by an m-element antenna array without the use of training sequences. We establish a set of necessary and sufficient conditions for perfect recovery of all the transmitted signals. Based on these conditions we propose optimization criteria that lead to adaptive algorithms for efficient blind source separation of non-Gaussian signals. Convergence analysis shows important global convergence properties of the proposed techniques. Combined with their low complexity, these features make the proposed algorithms good candidates for adaptive source separation

Keywords

MIMO systems; adaptive antenna arrays; adaptive signal processing; array signal processing; computational complexity; convergence of numerical methods; direction-of-arrival estimation; multi-access systems; optimisation; stochastic processes; telecommunication channels; CDMA; SDMA; adaptive blind source separation; algorithms; antenna array; convergence analysis; global convergence properties; kurtosis-based criteria; linear memoryless MIMO channel; low complexity; necessary condition; nonGaussian signals; perfect transmitted signal recovery; stochastic gradient algorithm; sufficient condition; synchronous user signals separation; Adaptive arrays; Antenna arrays; Blind source separation; Convergence; Multiaccess communication; Receiving antennas; Source separation; Sufficient conditions; Technological innovation; Transmitting antennas;

fLanguage

English

Publisher

ieee

Conference_Titel

Acoustics, Speech and Signal Processing, 1998. Proceedings of the 1998 IEEE International Conference on

Conference_Location

Seattle, WA

ISSN

1520-6149

Print_ISBN

0-7803-4428-6

Type

conf

DOI

10.1109/ICASSP.1998.681613

Filename

681613