Fast Computational Modeling Based on the Boundary Element Method Towards the Design of an Ultrasonic Biomedical Applicator

Raquel Martínez-Valdez; Ivonne Bazán

doi:10.17488/RMIB.46.1.1

Authors

Raquel Martínez-Valdez Universidad Autónoma de Aguascalientes, México https://orcid.org/0000-0002-6426-0640
Ivonne Bazán Universidad Autónoma de Aguascalientes, México https://orcid.org/0000-0002-8654-8426

DOI:

https://doi.org/10.17488/RMIB.46.1.1

Keywords:

acoustic field modeling, boundary element method, finite element method, focused ultrasound, ultrasonic biomedical applicators

Abstract

The aim of this work is to analyze the usage of the boundary element method (BEM) as a fast computational tool for solving large ultrasonic field problems, i.e. 3D models. A proposed tridimensional radiating surface S_R was modeled by means of BEM and the finite element method (FEM). Four time-harmonics models were developed: two containing the entire S_R and two considering a symmetrical plane at half-length of the radiator. BEM solutions were validated with FEM models by contours at -3 dB and -6 dB pressure decays, areas within the contours, elliptical shape ratio E_r and ellipsoidal focal volume approximations. The average differences in pressure and distance at the focus were 39.875 Pa and 0.4515 mm, respectively; the areas within the contours show differences between 0.6 mm² and 2.3 mm². The E_r of the focal zone was over 92 %, while the ellipsoidal volume approximation showed differences between 0.0817 mm³ to 1.4632 mm³ at -3 dB, and 1.2354 mm³ to 4.1144 mm³at -6 dB. Analyzed data suggest the use of BEM to model the ultrasonic beam pattern in a lossless medium during ultrasonic biomedical applicators design, reducing the solution time from 22 h with FEM to 2 min with BEM.

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