Please use this identifier to cite or link to this item: https://scholarhub.balamand.edu.lb/handle/uob/533
Title: Estimation algorithms for quantitative tissue characterization in ultrasound images using doubly stochastic translated point processes
Authors: Daba, Jihad S. 
Affiliations: Department of Electrical Engineering 
Issue Date: 2004
Part of: Proceedings of the 2nd International Conference on Advances on Medical Signal and Information Processing (MEDSIP)
Conference: International Conference on Advances on Medical Signal and Information Processing (MEDSIP) (2nd : September 2004. : Valleta, Malta) 
Abstract: 
Quantitative biological tissue characterization is of paramount importance for computer-assisted tissue classification and medical diagnosis. This paper presents stochastic models and estimation algorithms for the average local density or concentration of scatterers in tissues using speckled ultrasound images. We treat speckle form a novel point of view: as a carrier of useful clinical information about tissue characteristics rather than as contaminating noise. The stochastic models for tissue scattering are based on a doubly stochastic compound marked Poisson point process. For each of these tissue scattering statistical models, we present estimation algorithms to determine the average tissue local scatterer density, using intensity measurements of speckled images. We show that the maximum likelihood estimator is optimal in the sense that the variance of the error is the smallest possible using any other conceivable estimate having the same bias with the same data. In addition to their important applications in biological tissue classification, these estimation algorithms serve as a powerful tool for estimating radioactive concentration and for image reconstruction in tomography.
URI: https://scholarhub.balamand.edu.lb/handle/uob/533
Type: Conference Paper
Appears in Collections:Department of Electrical Engineering

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