Title :
FD-TD-modeling of propagation of high energy sound pulses in lithotripter-tissue-arrangements
Author_Institution :
Inst. fur Hochstfrequenztech. und Elektronik/Akustic, Karlsruhe Univ., Germany
Abstract :
The numerical modeling of lithotripter pressure pulse propagation is considered. The dependence of the field parameters in the focal region on the properties of the wave propagation path is of special interest. To obtain full-wave solutions an high-order FD-TD-discretization of a set of nonlinear acoustical equations is performed. The attenuating influence of tissue layers is represented by an explicit discrete time domain operator. For the presented research the acoustical field of the Storz MODULITH SL 10 shock wave lithotripter is considered. To validate the pure lithotripter model measured wave profiles in the focal region are used. They are obtained using a fiber-optic probe hydrophone. An exemplary simulation of the propagation of the SL 10 pulse through a fluid layer with tissue-like attenuation is presented and compared with the unaffected case
Keywords :
biological tissues; biomedical ultrasonics; finite difference time-domain analysis; physiological models; radiation therapy; shock wave effects; ultrasonic absorption; ultrasonic propagation; FD-TD-modeling; Storz MODULITH SL 10 shock wave lithotripter; attenuating influence; explicit discrete time domain operator; fiber-optic probe hydrophone; field parameters; fluid layer; focal region; high energy sound pulses propagation; lithotripter-tissue-arrangements; nonlinear acoustical equations; numerical modeling; tissue layers; tissue-like attenuation; Acoustic measurements; Acoustic propagation; Acoustic pulses; Lithotripsy; Nonlinear equations; Numerical models; Probes; Shock waves; Sonar equipment; Stereolithography;
Conference_Titel :
Ultrasonics Symposium, 1997. Proceedings., 1997 IEEE
Conference_Location :
Toronto, Ont.
Print_ISBN :
0-7803-4153-8
DOI :
10.1109/ULTSYM.1997.661829
