Title :
A stochastic model for propagation through tissue
Author_Institution :
Telecommun. Spatiales et Aeronautiques (TeSA), Toulouse, France
fDate :
10/1/2009 12:00:00 AM
Abstract :
Attenuation of ultrasonic waves is often assumed linear with respect to frequency in biological applications whereas it is considered quadratic when the propagation occurs in the atmosphere or the water. In the latter case, other studies show that a Gaussian propagation duration can explain this attenuation behavior and provide a model for the energy loss in the stationary limit. The present paper defines an equivalent random propagation duration with Cauchy distribution, which is appropriate for the propagation of ultrasound through tissue. The model adds an unobserved noise that represents the signal deterioration. In addition, the model agrees with the mode downshift in the case of a narrowband signal.
Keywords :
acoustic noise; bioacoustics; biological tissues; stochastic processes; ultrasonic propagation; Cauchy distribution; Gaussian propagation; energy loss; equivalent random propagation duration; narrowband signal; signal deterioration; stochastic model; tissue; ultrasonic wave attenuation; unobserved noise; Atmosphere; Atmospheric modeling; Attenuation; Biological system modeling; Energy loss; Frequency; Narrowband; Stochastic processes; Ultrasonic imaging; Algorithms; Models, Theoretical; Signal Processing, Computer-Assisted; Statistical Distributions; Stochastic Processes; Ultrasonography;
Journal_Title :
Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on
DOI :
10.1109/TUFFC.2009.1300
