Title :
A statistical theory for optimal detection of moving objects in variable corruptive noise
Author :
Cheung, Julian F Y ; Wicks, Michael C. ; Genello, Gerard J. ; Kurz, Ludwik
Author_Institution :
U.S. Air Force Res. Lab., Rome, NY, USA
fDate :
12/1/1999 12:00:00 AM
Abstract :
In this paper, the classical analysis of variance is extended to three-dimensional (3-D) Graeco-Latin squares design for multiframe processing applications. Conspicuous physical features, including edges, lines, and corners, can then be expressed as contrast functions. This enables the development of a new methodology for detecting moving objects embedded in noise. The new detector exploits spatial and temporal information uniformly most powerful in a Gaussian environment with unknown and time-varying noise variance. Also found is that a moving object detector based on contrast functions coincides with a sufficient statistic of the generalized likelihood ratio test. Extensive image analysis demonstrates the practicality of the detector and compares favorably to other classes of detectors
Keywords :
Gaussian processes; edge detection; image motion analysis; image representation; maximum likelihood detection; noise; optimisation; parameter estimation; statistical analysis; 3D Graeco-Latin squares design; Gaussian environment; contrast functions; corners; edge detection; edges; generalized likelihood ratio test; image analysis; image representation; lines; moving object detector; moving objects; multiframe processing applications; optimal detection; parameter estimation; physical features; spatial information; statistical theory; sufficient statistic; temporal information; time-varying noise variance; variable corruptive noise; Analysis of variance; Detectors; Image edge detection; Image motion analysis; Least squares approximation; Object detection; Optical sensors; Polynomials; Testing; Working environment noise;
Journal_Title :
Image Processing, IEEE Transactions on
