A Calderón multiplicative preconditioner for the electromagnetic Poincaré–Steklov operator of a heterogeneous domain with scattering applications

Dobbelaere, Dieter; Zutter, D. De; Hese, J. Van; Sercu, J.; Boonen, Tim J.; Rogier, Hendrik

doi:10.1016/j.jcp.2015.09.052

Cited by 13 publications

(5 citation statements)

References 60 publications

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“…(28) This equation is the magnetic field counterpart of the (localized) Calderón preconditioned electric operator in [37]. We propose to discretize (28) as…”

Section: B a Robust Mfie Formulationmentioning

confidence: 99%

Magnetic and Combined Field Integral Equations Based on the Quasi-Helmholtz Projectors

Merlini¹,

Beghein²,

Cools³

et al. 2020

IEEE Trans. Antennas Propagat.

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Boundary integral equation methods for analyzing electromagnetic scattering phenomena typically suffer from several of the following problems: (i) ill-conditioning when the frequency is low; (ii) ill-conditioning when the discretization density is high; (iii) ill-conditioning when the structure contains global loops (which are computationally expensive to detect); (iv) incorrect solution at low frequencies due to current cancellations; (v) presence of spurious resonances. In this paper, quasi-Helmholtz projectors are leveraged to obtain a magnetic field integral equation (MFIE) formulation that is immune to drawbacks (i)-(iv). Moreover, when this new MFIE is combined with a regularized electric field integral equation (EFIE), a new quasi-Helmholtz projector combined field integral equation (CFIE) is obtained that also is immune to (v). Numerical results corroborate the theory and show the practical impact of the newly proposed formulations.

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“…(28) This equation is the magnetic field counterpart of the (localized) Calderón preconditioned electric operator in [37]. We propose to discretize (28) as…”

Section: B a Robust Mfie Formulationmentioning

confidence: 99%

Magnetic and Combined Field Integral Equations Based on the Quasi-Helmholtz Projectors

Merlini¹,

Beghein²,

Cools³

et al. 2020

IEEE Trans. Antennas Propagat.

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“…Volume integral equations, instead, can model objects with a high degree of inhomogeneity. Unfortunately, as their surface counterparts, they suffer from the HC breakdown [19], [23]- [28] and fail to converge rapidly in applications with high-permittivity contrast scatterers. Another limitation of traditional VIE is that, even though they are immune from the low-frequency breakdown in purely dielectric objects [29], a frequency illscaling between the different parts of the VIE can occur when the object under study has a complex permittivity which depends on the frequency [30].…”

Section: Introductionmentioning

confidence: 99%

On a Low-Frequency and Contrast Stabilized Full-Wave Volume Integral Equation Solver for Lossy Media

Henry¹,

Merlini²,

Rahmouni³

et al. 2021

Preprint

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In this paper we present a new regularized electric flux volume integral equation (D-VIE) for modeling high-contrast conductive dielectric objects in a broad frequency range. This new formulation is particularly suitable for modeling biological tissues at low frequencies, as it is required by brain epileptogenic area imaging, but also at higher ones, as it is required by several applications including, but not limited to, transcranial magnetic and deep brain stimulation (TMS and DBS, respectively). When modeling inhomogeneous objects with high complex permittivities at low frequencies, the traditional D-VIE is illconditioned and suffers from numerical instabilities that result in slower convergence and in less accurate solutions. In this work we address these shortcomings by leveraging a new set of volume quasi-Helmholtz projectors. Their scaling by the material permittivity matrix allows for the re-balancing of the equation when applied to inhomogeneous scatterers and thereby makes the proposed method accurate and stable even for high complex permittivity objects until arbitrarily low frequencies. Numerical results, canonical and realistic, corroborate the theory and confirm the stability and the accuracy of this new method both in the quasi-static regime and at higher frequencies.

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“…In general, a faster convergence of the iterative solution is obtained when compared to alternative methods such as the finite element (FE) method, since only the surfaces of the scattering objects are discretized, leading to fewer unknowns. In case the problem includes heterogeneous regions, hybrid FE-BIE formulations may be adopted to take advantage of the efficiency of the BIE, and the ability of the FE method to model heterogeneous media [1].…”

Section: Introductionmentioning

confidence: 99%

“…The NtD operator maps the trace of the magnetic field on the boundary of a scattering object onto the tangential electric field on this boundary. The ill-conditioning of the discretization of Y will be resolved by making use of the regularizing property of the electric field integral operator T on the NtD operator [1]. The numerical solution of this novel formulation involves RWG and BC basis functions, which allows for integration in existing numerical solvers that make use of the conventional RWG basis functions.…”

Section: Introductionmentioning

confidence: 99%

Electromagnetic modeling of high magnetic contrast media using Calderón preconditioning

Gossye

Ginste

Rogier

2019

Computers & Mathematics with Applications

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In this contribution, we present a Calderón preconditioner for a novel singlesource equation to efficiently model electromagnetic scattering problems involving high magnetic contrasts. Through analysis of the spectral properties of the system matrix after discretization, it is shown that this formulation does not break down when high permeabilities are present, which was an unresolved problem of the Calderón preconditioned Poggio-Miller-Chan-Harrington-Wu-Tsai method. The adopted discretization scheme, which involves Rao-Wilton-Glisson and Buffa-Christiansen basis functions, allows for an easy integration in existing commercial Method of Moments software. The efficiency and accuracy of the presented method is corroborated by numerical examples.

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A Calderón multiplicative preconditioner for the electromagnetic Poincaré–Steklov operator of a heterogeneous domain with scattering applications

Cited by 13 publications

References 60 publications

Magnetic and Combined Field Integral Equations Based on the Quasi-Helmholtz Projectors

Magnetic and Combined Field Integral Equations Based on the Quasi-Helmholtz Projectors

On a Low-Frequency and Contrast Stabilized Full-Wave Volume Integral Equation Solver for Lossy Media

Electromagnetic modeling of high magnetic contrast media using Calderón preconditioning

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