Interior Elastic Scattering by a Non-Penetrable Partially Coated Obstacle and Its Shape Recovering

Kaiafa, Angeliki; Sevroglou, V.

doi:10.3390/math9192485

Mathematics

2021

DOI: 10.3390/math9192485

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Interior Elastic Scattering by a Non-Penetrable Partially Coated Obstacle and Its Shape Recovering

Angeliki Kaiafa

V. Sevroglou

Abstract: In this paper, the interior elastic direct and inverse scattering problem of time-harmonic waves for a non-penetrable partially coated obstacle placed in a homogeneous and isotropic medium is studied. The scattering problem is formulated via the Navier equation, considering incident circular waves due to point-source fields, where the corresponding scattered data are measured on a closed curve inside the obstacle. Our model, from the mathematical point of view, is described by a mixed boundary value problem in… Show more

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Cited by 1 publication

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Direct connection between Navier and spherical harmonic kernels in elasticity

Labropoulou¹,

Vafeas²,

Dassios

2023

MATH

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<abstract> <p>Linear isotropic elasticity is an interesting branch of continuum mechanics, described by the fundamental laws of Hooke and Newton, which are combined in order to construct the governing generalized Navier equation of the displacement within any material. Implying time-independence and in the absence of external body forces, the latter is reduced to the corresponding form of a homogeneous second-order partial differential equation, whose solution is given via the Papkovich differential representation, which expresses the displacement field in terms of harmonic functions. On the other hand, spherical geometry provides the most widely used framework in real-life applications, concerning interior and exterior problems in elasticity. The present work aims to provide a little progress, by producing ready-to-use basic functions for linear isotropic elasticity in spherical coordinates. Hence, we calculate the Papkovich eigensolutions, generated by the spherical harmonic eigenfunctions, obtaining connections between Navier and spherical harmonic kernels. A set of useful results are provided at the end of the paper in the form of examples, regarding the evaluation of displacement field inside and outside a sphere.</p> </abstract>

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Direct connection between Navier and spherical harmonic kernels in elasticity

Labropoulou¹,

Vafeas²,

Dassios

2023

MATH

View full text Add to dashboard Cite

show abstract

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Interior Elastic Scattering by a Non-Penetrable Partially Coated Obstacle and Its Shape Recovering

Cited by 1 publication

References 21 publications

Direct connection between Navier and spherical harmonic kernels in elasticity

Direct connection between Navier and spherical harmonic kernels in elasticity

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