Energy norm error estimates and convergence analysis for a stabilized Maxwell's equations in conductive media
Preprint, 2024
The aim of this article is to investigate the well-posedness, stability and convergence of solutions to the time-dependent Maxwell's equations for electric field in conductive media in continuous and discrete settings. The situation we consider would represent a physical problem where a subdomain is emerged in a homogeneous medium, characterized by constant dielectric permittivity and conductivity functions. It is well known that in these homogeneous regions the solution to the Maxwell's equations also solves the wave equation which makes calculations very efficient. In this way our problem can be considered as a coupling problem for which we derive stability and convergence analysis. A number of numerical examples validate theoretical convergence rates of the proposed stabilized explicit finite element scheme.
energy error estimate
finite element method
convergence analysis
stability
a priori error analysis
Maxwell's equations
Author
Eric Lindström
Chalmers, Mathematical Sciences, Applied Mathematics and Statistics
Larisa Beilina
Chalmers, Mathematical Sciences, Applied Mathematics and Statistics
Subject Categories
Computational Mathematics
Mathematical Analysis
Driving Forces
Innovation and entrepreneurship
Areas of Advance
Health Engineering
DOI
10.48550/arXiv.2312.13049
Related datasets
Online repository of 3D Grid Based Numerical Phantoms for use in Computational Electromagnetics Simulations [dataset]
URI: https://uwcem.ece.wisc.edu/MRIdatabase/