Improved detection in correlated impulsive noise using wavelet denoising

Author

Burley, S. ; Darnell, M. ; Prowse, C. ; Chandler, R.

Author_Institution

Dept. of Electron. & Electr. Eng., Leeds Univ., UK

Volume

1

fYear

1997

Firstpage

54

Abstract

It is widely acknowledged that the effect of impulsive noise is a major source of performance degradation within a wide range of communication systems. This is due to the fact that non-Gaussian interference is neglected within the system design philosophy for reasons of complexity and tractability. Performance degradation is exacerbated further when the impulsive component is no longer independent identically distributed, but correlated. When this situation arises, the impulsive component can be masked by the underlying background noise process, and reside over many data samples, which in turn renders classical suppression techniques ineffective. We directly address the problem of signal detection in correlated impulsive noise using a novel `denoising´ technique in which significant performance gains are achieved with low-complexity

Keywords

Rayleigh channels; adaptive signal detection; adaptive signal processing; correlation methods; demodulation; digital communication; fading; interference suppression; phase shift keying; receivers; wavelet transforms; MPSK digital receiver; Rayleigh fading channel; adaptive wavelet denoising; background noise process; communication systems; correlated impulsive noise detection; data samples; demodulation; interference suppression; low-complexity; nonGaussian interference; performance degradation; signal detection; AWGN; Additive white noise; Background noise; Degradation; Gaussian noise; Interference; Matched filters; Noise reduction; Signal detection; Working environment noise;

fLanguage

English

Publisher

ieee

Conference_Titel

MILCOM 97 Proceedings

Conference_Location

Monterey, CA

Print_ISBN

0-7803-4249-6

Type

conf

DOI

10.1109/MILCOM.1997.648664

Filename

648664