The Hermite-Taylor correction function method for embedded boundary and Maxwell’s interface problems
Copyright policy )The Hermite-Taylor correction function method for embedded boundary and Maxwell’s interface problems
We propose a novel Hermite-Taylor correction function method to handle embedded boundary and interface conditions for Maxwell's equations. The Hermite-Taylor method evolves the electromagnetic fields and their derivatives through order $m$ in each Cartesian coordinate. This makes the development of a systematic approach to enforce boundary and interface conditions difficult. Here we use the correction function method to update the numerical solution where the Hermite-Taylor method cannot be applied directly. Time derivatives of boundary and interface conditions, converted into spatial derivatives, are enforced to obtain a stable method and relax the time-step size restriction of the Hermite-Taylor correction function method. The proposed high-order method offers a flexible systematic approach to handle embedded boundary and interface problems, including problems with discontinuous solutions at the interface. This method is also easily adaptable to other first order hyperbolic systems.
30 pages, 33 figures
- Michigan State University United States
- Polytechnique Montréal Canada
- Southern Arkansas University Tech United States
Advanced Numerical Methods in Computational Mathematics, 35Q61, 65M70, 78A45, Mechanics of Materials, Computational Mechanics, FOS: Mathematics, Numerical methods in engineering, Mathematics - Numerical Analysis, Numerical Analysis (math.NA), Electrical and Electronic Engineering, Electromagnetic Simulation and Numerical Methods
Advanced Numerical Methods in Computational Mathematics, 35Q61, 65M70, 78A45, Mechanics of Materials, Computational Mechanics, FOS: Mathematics, Numerical methods in engineering, Mathematics - Numerical Analysis, Numerical Analysis (math.NA), Electrical and Electronic Engineering, Electromagnetic Simulation and Numerical Methods
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