Retrieval of the piecewise-constant mass density in the Bergman wave equation

Mapping Intimacies ◽

10.22541/au.163975810.07656742/v1 ◽

2021 ◽

Author(s):

armand wirgin

Keyword(s):

Inverse Problem ◽

Wave Equation ◽

Mass Density ◽

Perturbation Technique ◽

Separation Of Variables ◽

Scattering Problem ◽

Acoustic Scattering ◽

Density Contrast ◽

Homogeneous Fluid ◽

Domain Integral

This investigation is concerned with the 2D acoustic scattering problem of a plane wave propagating in a non-lossy, isotropic, homogeneous ﬂuid host and soliciting a linear, isotropic, macroscopically-homogeneous, generally-lossy, ﬂat-plane layer in which the mass density and wavespeed are diﬀerent from those of the host. The focus is on the inverse problem of the retrieval of the layer mass density. The data is the transmitted pressure ﬁeld, obtained by simulation (resolution of the forward problem) in exact, explicit form via the domain integral form of the Bergman wave equation. This solution is exact and more explicit in terms of the mass-density contrast (between the host and layer) than the classical solution obtained by separation of variables. A perturbation technique enables the solution (in its form obtained by the domain integral method) to be cast as a series of powers of the mass density contrast, the ﬁrst three terms of which are employed as the trial models in the treatment of the inverse problem. The aptitude of these models to retrieve the mass density contrast is demonstrated both theoretically and numerically.

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LOW-FREQUENCY ACOUSTIC SCATTERING OF A PLANE WAVE FROM A SOFT AND HARD TORUS

Journal of Computational Acoustics ◽

10.1142/s0218396x07003299 ◽

2007 ◽

Vol 15 (02) ◽

pp. 181-197 ◽

Cited By ~ 2

Author(s):

GEORGE VENKOV

Keyword(s):

Separation Of Variables ◽

Near Field ◽

Scattering Problem ◽

Acoustic Scattering ◽

Low Frequency ◽

Diagonal Form ◽

Legendre Functions ◽

Algebraic Equations ◽

Analytical Technique ◽

Linear Algebraic Equations

A plane acoustic wave is scattered by either a soft or a hard small torus. The incident wave has a wavelength which is much larger than the characteristic dimension of the scatterer and thus the low-frequency approximation method is applicable to the scattering problem. It is shown that there exists exactly one toroidal coordinate system that fits the given geometry. The R-separation of variables is utilized to obtain the series expansion of the fields in terms of toroidal harmonics (half-integer Legendre functions of first and second kind). The scattering problem for the soft torus is solved analytically for the near field, governing the leading two low-frequency coefficients, as well as for the far field, where both the amplitude and the cross-section are evaluated. The scattering problem for the hard torus appears to be much more complicated in calculations. The Neumann boundary condition on the surface of the torus leads to a three-term recurrence relation for the series coefficients corresponding to the scattered fields. Thus, the potential boundary-value problem for the leading low-frequency approximations is reduced to infinite systems of linear algebraic equations with three-diagonal matrices. An analytical technique for solving systems of diagonal form is developed.

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An Efficient and Stable Spectral-Element Method for Acoustic Scattering by an Obstacle

East Asian Journal on Applied Mathematics ◽

10.4208/eajam.060713.080813a ◽

2013 ◽

Vol 3 (3) ◽

pp. 190-208

Author(s):

Jing An ◽

Jie Shen

Keyword(s):

Spectral Element Method ◽

Perturbation Technique ◽

Scattering Problem ◽

Acoustic Scattering ◽

Spectral Element ◽

Boundary Perturbation ◽

Sound Waves ◽

Time Harmonic ◽

Accuracy And Stability ◽

Element Method

AbstractA spectral-element method is developed to solve the scattering problem for time-harmonic sound waves due to an obstacle in an homogeneous compressible fluid. The method is based on a boundary perturbation technique coupled with an efficient spectral-element solver. Extensive numerical results are presented, in order to show the accuracy and stability of the method.

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