Title :
Modeling nonlinear ultrasound propagation in tissue from array transducers and application to tissue harmonic imaging
Author :
Zemp, Roger J. ; Tavakkoli, Jahangir ; Cobbold, Richard S C
Author_Institution :
Dept. of Biomed. Eng., California Univ., Davis, CA, USA
Abstract :
A computational model is presented to simulate nonlinear propagation of ultrasound in tissue from array transducers. The model is based on an operator splitting approach with a fractional step marching scheme, whereby the effects of diffraction, attenuation and nonlinearity can be considered independent over small steps. This algorithm avoids the use of the parabolic approximation used by the KZK model, and may be more accurate for focused sources. Simulated transmitted pressure profiles and pulse-echo second-harmonic point spread functions are presented as examples of the capabilities of the algorithm for design and optimization of tissue harmonic imaging systems. Dynamic focusing and pulse inversion are shown to be advantageous for increasing second harmonic levels, and for improving spatial resolution.
Keywords :
biomedical measurement; biomedical transducers; biomedical ultrasonics; nonlinear acoustics; ultrasonic absorption; ultrasonic propagation; ultrasonic transducer arrays; array transducers; attenuation; diffraction; dynamic focusing; fractional step marching scheme; improving spatial resolution; modeling nonlinear ultrasound propagation; nonlinearity; operator splitting approach; parabolic approximation; pulse inversion; pulse-echo second-harmonic point spread functions; simulated transmitted pressure profiles; small steps; tissue; tissue harmonic imaging; tissue harmonic imaging systems; Algorithm design and analysis; Approximation algorithms; Attenuation; Computational modeling; Design optimization; Diffraction; Focusing; Ultrasonic imaging; Ultrasonic transducer arrays; Ultrasonic transducers;
Conference_Titel :
Ultrasonics Symposium, 2002. Proceedings. 2002 IEEE
Print_ISBN :
0-7803-7582-3
DOI :
10.1109/ULTSYM.2002.1192634
