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A Chebyshev-Based High-Order-Accurate Integral Equation Solver for Maxwell’s Equations

Jin Hu, Emmanuel Garza, Constantine Sideris

2021IEEE Transactions on Antennas and Propagation19 citationsDOIOpen Access PDF

Abstract

This article introduces a new method for discretizing and solving integral equation formulations of Maxwell's equations, which achieves spectral accuracy for smooth surfaces. The approach is based on a hybrid Nyström-collocation method using Chebyshev polynomials to expand the unknown current densities over curvilinear quadrilateral surface patches. As an example, the proposed strategy is applied to the magnetic field integral equation (MFIE) and the N-Müller formulation for scattering from metallic and dielectric objects, respectively. The convergence is studied for several different geometries, including spheres, cubes, and complex NURBS geometries imported from CAD software, and the results are compared against a commercial Method-of-Moments solver using RWG basis functions.

Topics & Concepts

Curvilinear coordinatesSolverIntegral equationDiscretizationBasis functionQuadrilateralMathematicsElectric-field integral equationMathematical analysisConvergence (economics)Method of moments (probability theory)Chebyshev polynomialsApplied mathematicsInterpolation (computer graphics)Field (mathematics)Surface (topology)Basis (linear algebra)Chebyshev filterNumerical analysisScatteringCurrent (fluid)Computational electromagneticsApproximation theoryMessage oriented middlewareMagnetic fieldChebyshev equationElectromagnetic Scattering and AnalysisElectromagnetic Simulation and Numerical MethodsAdvanced Numerical Methods in Computational Mathematics
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