by C.J. Rozell and D. Manolakis
Abstract:
Detection of military and civilian targets from airborne platforms using hyperspectral imaging (HSI) sensors is of great interest. Relative to multispectral sensing, hyperspectral sensing can increase the detectability of targets by exploiting finer detail in spectral signatures. A multitude of adaptive detection algorithms have appeared in the literature or have found their way into software packages and end-user systems. The most widely known among them is the linear matched filter. However, despite its popularity, the fact that the matched filter is used under conditions that deviate from the implicit optimality assumptions has not been investigated.
Reference:
Matched filter performance for unequal target and background covariance matricesC.J. Rozell and D. Manolakis. pp. 109–117, April 2004.
Bibtex Entry:
@CONFERENCE{rozell.04b,
author = {Rozell, C.J. and Manolakis, D.},
title = {Matched filter performance for unequal target and background covariance matrices},
booktitle = {Proceedings of the SPIE Defense and Security Symposium: Algorithms and Technologies for Multispectral, Hyperspectral, and Ultraspectral Imagery X},
year = {2004},
address = {Orlando, FL},
month = {April},
pages = {109--117},
abstract = {Detection of military and civilian targets from
airborne platforms using hyperspectral imaging (HSI) sensors is of
great interest. Relative to multispectral sensing, hyperspectral
sensing can increase the detectability of targets by exploiting finer
detail in spectral signatures. A multitude of adaptive detection
algorithms have appeared in the literature or have found their way into
software packages and end-user systems. The most widely known among them
is the linear matched filter. However, despite its popularity, the
fact that the matched filter is used under conditions that deviate
from the implicit optimality assumptions has not been investigated.},
}