Revisiting the Low-Frequency Dipolar Perturbation by an Impenetrable Ellipsoid in a Conductive Surrounding

Vafeas, Panayiotis

doi:10.1155/2017/9420658

Cited by 4 publications

(1 citation statement)

References 19 publications

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“…Later, similar problems were studied for a rigid and a penetrable ellipsoid for acoustic waves as well as an acoustic ellipsoidal boss [8,12], a rigid ellipsoid for elastic waves [4], an ellipsoidal perfect conductor, and an electromagnetic ellipsoidal boss [9]. Moreover, inverse scattering problems concerning ellipsoids have been studied for acoustic waves in [7], for elastic waves in [13], and for electromagnetic waves in [14]. Also, inverse scattering problems concerning spheres have been treated in [1] and [3].…”

Section: Introductionmentioning

confidence: 99%

An Inverse Electromagnetic Scattering Problem for an Ellipsoid

Athanasiadou¹,

Zoi²,

Arkoudis³

2019

PIER M

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The scattering problem of time-harmonic electromagnetic plane waves by an impedance and a dielectric ellipsoid is considered. A low-frequency formulation of the direct scattering problem using the Rayleigh approximation is described. Considering far-field data, an inverse electromagnetic scattering problem is formulated and studied. A finite number of measurements of the leading-order term of the electric far-field pattern in the low-frequency approximation leads to specify the semi-axes of the ellipsoid. The orientation of the ellipsoid is obtained by using the Euler angles. Corresponding results for the sphere, spheroid, needle, and disc can be obtained considering them as geometrically degenerate forms of the ellipsoid for suitable values of its geometrical parameters.

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Section: Introductionmentioning

confidence: 99%

An Inverse Electromagnetic Scattering Problem for an Ellipsoid

Athanasiadou¹,

Zoi²,

Arkoudis³

2019

PIER M

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An inverse electromagnetic scattering problem for a layered ellipsoid

Athanasiadou

Bardis

Arkoudis

2020

Journal of Computational and Applied Mathematics

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Low‐frequency dipolar electromagnetic scattering by a solid ellipsoid in lossless environment

Vafeas

2020

Stud Appl Math

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Electromagnetic wave scattering phenomena for target identification are important in many applications related to fundamental science and engineering. Here, we present an analytical formulation for the calculation of the magnetic and electric fields that scatter off a highly conductive ellipsoidal body, located within an otherwise homogeneous and isotropic lossless medium. The primary excitation source assumes a time‐harmonic magnetic dipole, precisely fixed and arbitrarily orientated that operates at low frequencies and produces the incident fields. The scattering problem itself is modeled with respect to rigorous expansions of the electromagnetic fields at the low‐frequency regime in terms of positive integral powers of the real wave number of the ambient. Obviously, the Rayleigh static term and a few dynamic terms are sufficient for the purpose of the present work, as the additional terms are neglected due to their minor contribution. Therein, the classical Maxwell's theory is suitably modified, leading to intertwined either Laplace's or Poisson's equations, accompanied by the impenetrable boundary conditions for the total fields and the limiting behavior at infinity. On the other hand, the complete spatial anisotropy of the three‐dimensional space is secured via the introduction of the genuine ellipsoidal coordinate system, being appropriate for tackling incrementally such scattering boundary value problems. The nonaxisymmetric fields are obtained via infinite series expansions in terms of ellipsoidal harmonic eigenfunctions, providing handy closed‐form solutions in a compact fashion, whose validity is verified by a straightforward reduction to simpler geometries of the metal object. The main idea is to demonstrate an efficient methodology, according to which the constructed analytical formulae can offer the appropriate environment for a fast numerical estimation of the scattered electromagnetic fields that could be useful for real data inversion.

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Revisiting the Low-Frequency Dipolar Perturbation by an Impenetrable Ellipsoid in a Conductive Surrounding

Cited by 4 publications

References 19 publications

An Inverse Electromagnetic Scattering Problem for an Ellipsoid

An Inverse Electromagnetic Scattering Problem for an Ellipsoid

An inverse electromagnetic scattering problem for a layered ellipsoid

Low‐frequency dipolar electromagnetic scattering by a solid ellipsoid in lossless environment

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