An explicit, adaptive, hybrid finite element/finite difference method is proposed for the numerical solution of Maxwell's equations in the time domain. The method is hybrid in the sense that different numerical methods, finite elements and finite differences, are used in different parts of the computational domain. Thus, we combine the flexibility of finite elements with the efficiency of finite differences. Furthermore, an a posteriori error estimate is derived for local adaptivity and error control inside the subregion, where finite elements are used. Numerical experiments illustrate the usefulness of computational adaptive error control of proposed new method
In this paper we present a posteriori error estimates, and stability estimates for the time-dependen...
We consider an implicit a posteriori error estimation technique for the adaptive solution of the Max...
This thesis is concerned with efficient and accurate numerical methods for the solution of Maxwell's...
An explicit, adaptive, hybrid finite element/finite difference method is proposed for the numerical ...
An explicit, adaptive, hybrid finite element/finite difference method is proposed forthe numerical s...
A fully explicit, discontinuous hybrid finite element/finite difference method is proposed for the n...
A fully explicit, discontinuous hybrid finite element/finite difference method is proposed for the n...
In this thesis edge elements are applied to solve several problems in computational electromagnetics...
The most commonly used method for the time-domain Maxwell equations is the Finite-Difference Time-Do...
In this thesis edge elements are applied to solve several problems in computational electromagnetics...
A posteriori error estimates in each subdomain of a finite element tessellation provide the main ing...
In this paper, we discuss a time domain finite element method for the approximate solution of Maxwel...
Stability and convergence analyses for the domain decomposition finite element/finite difference (FE...
A stable hybridization of the finite-element method (FEM) and the finite-difference time-domain (FDT...
A stable hybridization of the finite-element method (FEM) and the finite-difference time-domain (FDT...
In this paper we present a posteriori error estimates, and stability estimates for the time-dependen...
We consider an implicit a posteriori error estimation technique for the adaptive solution of the Max...
This thesis is concerned with efficient and accurate numerical methods for the solution of Maxwell's...
An explicit, adaptive, hybrid finite element/finite difference method is proposed for the numerical ...
An explicit, adaptive, hybrid finite element/finite difference method is proposed forthe numerical s...
A fully explicit, discontinuous hybrid finite element/finite difference method is proposed for the n...
A fully explicit, discontinuous hybrid finite element/finite difference method is proposed for the n...
In this thesis edge elements are applied to solve several problems in computational electromagnetics...
The most commonly used method for the time-domain Maxwell equations is the Finite-Difference Time-Do...
In this thesis edge elements are applied to solve several problems in computational electromagnetics...
A posteriori error estimates in each subdomain of a finite element tessellation provide the main ing...
In this paper, we discuss a time domain finite element method for the approximate solution of Maxwel...
Stability and convergence analyses for the domain decomposition finite element/finite difference (FE...
A stable hybridization of the finite-element method (FEM) and the finite-difference time-domain (FDT...
A stable hybridization of the finite-element method (FEM) and the finite-difference time-domain (FDT...
In this paper we present a posteriori error estimates, and stability estimates for the time-dependen...
We consider an implicit a posteriori error estimation technique for the adaptive solution of the Max...
This thesis is concerned with efficient and accurate numerical methods for the solution of Maxwell's...