Ultrasound Echo Envelope Analysis Using a Homodyned K Distribution Signal Model
- 1 October 1994
- journal article
- research article
- Published by SAGE Publications in Ultrasonic Imaging
- Vol. 16 (4) , 265-287
- https://doi.org/10.1177/016173469401600404
Abstract
The statistics of ultrasound echo envelope signals can be used to characterize scattering media. The Rayleigh distribution and its generalized forms, the K and Rice distributions, have been previously used to model the echo signal. A more generalized statistical model, the homodyned K distribution, combines the K and Rice distribution features to better account for the statistics of the echo signal. We show that this model can give two parameters that are useful for media characterization: k, the ratio of coherent to diffuse signals, and, β, which characterizes the clustering of scatterers in the medium.Keywords
This publication has 14 references indexed in Scilit:
- Use of non-Rayleigh statistics for the identification of tumors in ultrasonic B-scans of the breastIEEE Transactions on Medical Imaging, 1993
- A Simulation Study of Echographic Imaging of Diffuse and Structurally Scattering MediaUltrasonic Imaging, 1991
- Ultrasound speckle analysis based on the K distributionThe Journal of the Acoustical Society of America, 1991
- Deviations from Rayleigh Statistics in Ultrasonic SpeckleUltrasonic Imaging, 1988
- Statistical properties of radio-frequency and envelope-detected signals with applications to medical ultrasoundJournal of the Optical Society of America A, 1987
- Analysis Of Ultrasound Image Texture Via Generalized Rician StatisticsOptical Engineering, 1986
- Unified Approach To The Detection And Classification Of Speckle Texture In Diagnostic UltrasoundOptical Engineering, 1986
- Speckle Statistics With A Small Number Of ScatterersOptical Engineering, 1984
- Theoretical framework for spectrum analysis in ultrasonic tissue characterizationThe Journal of the Acoustical Society of America, 1983
- On the statistics of K-distributed noiseJournal of Physics A: General Physics, 1980