Adaptive Radial Basis Function Detector for Beamforming

Author

Sheng Chen ; Labib, K. ; Rong Kang ; Hanzo, Lajos

Author_Institution

Univ. of Southampton, Southampton

fYear

2007

fDate

24-28 June 2007

Firstpage

2967

Lastpage

2972

Abstract

We consider nonlinear detection in rank-deficient multiple-antenna assisted beamforming systems. By exploiting the inherent symmetry of the underlying optimal Bayesian detection solution, a symmetric radial basis function (RBF) detector is proposed and two adaptive algorithms are developed for training the proposed RBF detector. The first adaptive algorithm, referred to as the nonlinear least bit error, is a stochastic approximation to the Parzen window estimation of the detector output´s probability density function while the second algorithm is based on a clustering. The proposed adaptive solutions are capable of providing a signal to noise ratio gain in excess of 8 dB against the theoretical linear minimum bit error rate benchmarker, when supporting four users with the aid of two receive antennas or five users employing three antenna elements.

Keywords

approximation theory; array signal processing; belief networks; radial basis function networks; Parzen window estimation; adaptive algorithms; adaptive radial basis function detector; beamforming systems; inherent symmetry; nonlinear detection; nonlinear least bit error; optimal Bayesian detection solution; probability density function; rank deficient multiple antenna; stochastic approximation; symmetric radial basis function; Adaptive algorithm; Approximation algorithms; Array signal processing; Bayesian methods; Clustering algorithms; Detectors; Probability density function; Receiving antennas; Signal to noise ratio; Stochastic resonance;

fLanguage

English

Publisher

ieee

Conference_Titel

Communications, 2007. ICC '07. IEEE International Conference on

Conference_Location

Glasgow

Print_ISBN

1-4244-0353-7

Type

conf

DOI

10.1109/ICC.2007.493

Filename

4289164