Multitemporal monitoring of sites using spectral imagery is addressed. A comprehensive architecture is presented for the detection of significant changes in scene composition described at the object level of spatial scale. An object-level scene description is obtained by applying a statistical spectral anomaly detector followed by a competitive region growth object extractor. The competitive region growth algorithm is derived as the solution to an approximate maximum likelihood image segmentation problem. Gaussian spectral clustering is used to model the scene background. A digital site model is constructed that contains image segmentation maps and extracted object features. Object-level change detection (OLCD) is accomplished by comparing objects extracted from a new image to objects recorded in the site model. A restricted implementation of the architecture is described and tested on long-wave infrared hyperspectral imagery. It is demonstrated that spectral OLCD can eliminate false alarms based on their multitemporal persistence. Incorporating multiple images in the site model is observed to improve OLCD performance.
[1]
Xiaoli Yu,et al.
Adaptive multiple-band CFAR detection of an optical pattern with unknown spectral distribution
,
1990,
IEEE Trans. Acoust. Speech Signal Process..
[2]
Xiaoli Yu,et al.
Comparative performance analysis of adaptive multispectral detectors
,
1993,
IEEE Trans. Signal Process..
[3]
Geoffrey G. Hazel,et al.
Multivariate Gaussian MRF for multispectral scene segmentation and anomaly detection
,
2000,
IEEE Trans. Geosci. Remote. Sens..
[4]
J. Besag.
On the Statistical Analysis of Dirty Pictures
,
1986
.
[5]
Tamar Peli,et al.
Multispectral change detection
,
1997,
Defense, Security, and Sensing.
[6]
Edward A. Ashton,et al.
Detection of subpixel anomalies in multispectral infrared imagery using an adaptive Bayesian classifier
,
1998,
IEEE Trans. Geosci. Remote. Sens..
[7]
Stan Z. Li,et al.
Markov Random Field Modeling in Computer Vision
,
1995,
Computer Science Workbench.