This article introduces a time-domain combined field integral equation (TD-CFIE) for electromagnetic scattering by a perfect electric conductor (PEC). The new equation is obtained by leveraging the quasi-Helmholtz projectors, which separate both the unknown and the source fields into solenoidal and irrotational components. These two components are then appropriately rescaled to cure the solution from a loss of accuracy occurring when the time step is large. Yukawa-type integral operators of a purely imaginary wavenumber are also used as a Calderon preconditioner to eliminate the ill-conditioning of matrix systems. The stabilized time-domain electric and magnetic field integral equations are linearly combined in a Calderon-like fashion, then temporally discretized using an appropriate pair of trial functions, resulting in a marching-on-in-time (MOT) linear system. The novel formulation is immune to spurious resonances, dense discretization breakdown, large-time step breakdown, and dc instabilities stemming from non-trivial kernels. Numerical results for both simply-connected and multiply-connected scatterers corroborate the theoretical analysis.
A Stabilized Time-Domain Combined Field Integral Equation Using the Quasi-Helmholtz Projectors / Le, Van Chien; Cordel, Pierrick; Andriulli, Francesco P.; Cools, Kristof. - In: IEEE TRANSACTIONS ON ANTENNAS AND PROPAGATION. - ISSN 0018-926X. - STAMPA. - 72:7(2024), pp. 5852-5864. [10.1109/tap.2024.3410709]
A Stabilized Time-Domain Combined Field Integral Equation Using the Quasi-Helmholtz Projectors
Cordel, Pierrick;Andriulli, Francesco P.;
2024
Abstract
This article introduces a time-domain combined field integral equation (TD-CFIE) for electromagnetic scattering by a perfect electric conductor (PEC). The new equation is obtained by leveraging the quasi-Helmholtz projectors, which separate both the unknown and the source fields into solenoidal and irrotational components. These two components are then appropriately rescaled to cure the solution from a loss of accuracy occurring when the time step is large. Yukawa-type integral operators of a purely imaginary wavenumber are also used as a Calderon preconditioner to eliminate the ill-conditioning of matrix systems. The stabilized time-domain electric and magnetic field integral equations are linearly combined in a Calderon-like fashion, then temporally discretized using an appropriate pair of trial functions, resulting in a marching-on-in-time (MOT) linear system. The novel formulation is immune to spurious resonances, dense discretization breakdown, large-time step breakdown, and dc instabilities stemming from non-trivial kernels. Numerical results for both simply-connected and multiply-connected scatterers corroborate the theoretical analysis.File | Dimensione | Formato | |
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https://hdl.handle.net/11583/2992540