Title :
Deconvolution for transient classification using fourth order statistics
Author :
Broadhead, Michael K. ; Pflug, Lisa A.
Author_Institution :
Naval Res. Lab., Stennis Space Center, MS, USA
Abstract :
Considered are numerical experiments involving an exponentially damped harmonic source signature, and underwater acoustics Green´s functions (GFs) representing bottom-limited propagation in a wave guide. It has been shown that the fourth order blind deconvolution functional proposed by Wiggins (1978) can be used to generate a class of signals from the propagation distorted signature such that one or more members of the class are “close” to the original signature. There are obvious applications to improving sonar target classification in the presence of multipath distortion. In this paper it is demonstrated that the algorithm based on the Cabrelli (1984) functional (D-norm) can be implemented in a similar fashion, and that it performs significantly better in the presence of additive noise than does the Wiggins V-norm
Keywords :
Green´s function methods; deconvolution; geophysical signal processing; geophysical techniques; image classification; oceanographic techniques; seafloor phenomena; sonar; sonar imaging; sonar target recognition; Cabrelli functional; D-norm; Green´s function method; additive noise; bottom-limited propagation; deconvolution; distorted signature; exponentially damped harmonic source signature; fourth order blind deconvolution functional; fourth order statistics; geophysical measurement technique; image classification; multipath distortion; numerical model; ocean; seafloor; sonar imaging; sonar target classification; transient classification; underwater acoustics; Acoustic distortion; Acoustic propagation; Acoustic reflection; Deconvolution; Filters; Green´s function methods; Oceans; Signal processing algorithms; Statistics; Underwater acoustics;
Conference_Titel :
OCEANS '97. MTS/IEEE Conference Proceedings
Conference_Location :
Halifax, NS
Print_ISBN :
0-7803-4108-2
DOI :
10.1109/OCEANS.1997.634404
