Ultrasonic field modeling: a comparison of analytical, semi-analytical, and numerical techniques

Modeling ultrasonic fields in front of a transducer in the presence and absence of a scatterer is a fundamental problem that has been attempted by different techniques: analytical, semi-analytical, and numerical. However, a comprehensive comparison study among these techniques is currently missing i...

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Veröffentlicht in:	IEEE transactions on ultrasonics, ferroelectrics, and frequency control ferroelectrics, and frequency control, 2010-12, Vol.57 (12), p.2795-2807
Hauptverfasser:	Kundu, T, Placko, D, Rahani, E K, Yanagita, T, Cac Minh Dao
Format:	Artikel
Sprache:	eng
Schlagworte:	Acoustics Cavity resonators Cross-disciplinary physics: materials science rheology Exact sciences and technology Ferroelectric materials Finite element analysis Finite element method Finite element methods Fresnel reflection Fundamental areas of phenomenology (including applications) Holes Integrals Materials science Materials testing Mathematical analysis Mathematical models Modeling Physics Point sources RSI Studies Transducers Transduction acoustical devices for the generation and reproduction of sound
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container_title	IEEE transactions on ultrasonics, ferroelectrics, and frequency control
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creator	Kundu, T Placko, D Rahani, E K Yanagita, T Cac Minh Dao
description	Modeling ultrasonic fields in front of a transducer in the presence and absence of a scatterer is a fundamental problem that has been attempted by different techniques: analytical, semi-analytical, and numerical. However, a comprehensive comparison study among these techniques is currently missing in the literature. The objective of this paper is to make this comparison for different ultrasonic field modeling problems with various degrees of difficulty. Four fundamental problems are considered: a flat circular transducer, a flat square transducer, a circular concave transducer, and a point focused transducer (concave lens) in the presence of a cavity. The ultrasonic field in front of a finite-sized transducer can be obtained by Huygens-Fresnel superposition principle that integrates the contributions of several point sources distributed on the transducer face. This integral which is also known as the Rayleigh integral or Rayleigh-Sommerfeld integral (RSI) can be evaluated analytically for obtaining the pressure field variation along the central axis of the transducer for simple geometries, such as a flat circular transducer. The semi-analytical solution is a newly developed mesh-free technique called the distributed point source method (DPSM). The numerical solution is obtained from finite element analysis. Note that the first three problems study the effect of the transducer size and shape, whereas the fourth problem computes the field in presence of a scatterer.
doi_str_mv	10.1109/TUFFC.2010.1753
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The semi-analytical solution is a newly developed mesh-free technique called the distributed point source method (DPSM). The numerical solution is obtained from finite element analysis. 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subjects	Acoustics Cavity resonators Cross-disciplinary physics: materials science rheology Exact sciences and technology Ferroelectric materials Finite element analysis Finite element method Finite element methods Fresnel reflection Fundamental areas of phenomenology (including applications) Holes Integrals Materials science Materials testing Mathematical analysis Mathematical models Modeling Physics Point sources RSI Studies Transducers Transduction acoustical devices for the generation and reproduction of sound
title	Ultrasonic field modeling: a comparison of analytical, semi-analytical, and numerical techniques
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