# Development and Application of Compatible Discretizations of Maxwell's Equations

## Abstract

We present the development and application of compatible finite element discretizations of electromagnetics problems derived from the time dependent, full wave Maxwell equations. We review the H(curl)-conforming finite element method, using the concepts and notations of differential forms as a theoretical framework. We chose this approach because it can handle complex geometries, it is free of spurious modes, it is numerically stable without the need for filtering or artificial diffusion, it correctly models the discontinuity of fields across material boundaries, and it can be very high order. Higher-order H(curl) and H(div) conforming basis functions are not unique and we have designed an extensible C++ framework that supports a variety of specific instantiations of these such as standard interpolatory bases, spectral bases, hierarchical bases, and semi-orthogonal bases. Virtually any electromagnetics problem that can be cast in the language of differential forms can be solved using our framework. For time dependent problems a method-of-lines scheme is used where the Galerkin method reduces the PDE to a semi-discrete system of ODE's, which are then integrated in time using finite difference methods. For time integration of wave equations we employ the unconditionally stable implicit Newmark-Beta method, as well as the high order energy conservingmore »

- Authors:

- Publication Date:

- Research Org.:
- Lawrence Livermore National Lab. (LLNL), Livermore, CA (United States)

- Sponsoring Org.:
- USDOE

- OSTI Identifier:
- 897994

- Report Number(s):
- UCRL-BOOK-212729

TRN: US200706%%180

- DOE Contract Number:
- W-7405-ENG-48

- Resource Type:
- Book

- Country of Publication:
- United States

- Language:
- English

- Subject:
- 42 ENGINEERING; 99 GENERAL AND MISCELLANEOUS//MATHEMATICS, COMPUTING, AND INFORMATION SCIENCE; DIFFUSION; DIFFUSION EQUATIONS; EDDY CURRENTS; FINITE DIFFERENCE METHOD; FINITE ELEMENT METHOD; MAXWELL EQUATIONS; TRANSIENTS; WAVE EQUATIONS; WAVE PROPAGATION

### Citation Formats

```
White, D, Koning, J, and Rieben, R.
```*Development and Application of Compatible Discretizations of Maxwell's Equations*. United States: N. p., 2005.
Web.

```
White, D, Koning, J, & Rieben, R.
```*Development and Application of Compatible Discretizations of Maxwell's Equations*. United States.

```
White, D, Koning, J, and Rieben, R. Fri .
"Development and Application of Compatible Discretizations of Maxwell's Equations". United States. https://www.osti.gov/servlets/purl/897994.
```

```
@article{osti_897994,
```

title = {Development and Application of Compatible Discretizations of Maxwell's Equations},

author = {White, D and Koning, J and Rieben, R},

abstractNote = {We present the development and application of compatible finite element discretizations of electromagnetics problems derived from the time dependent, full wave Maxwell equations. We review the H(curl)-conforming finite element method, using the concepts and notations of differential forms as a theoretical framework. We chose this approach because it can handle complex geometries, it is free of spurious modes, it is numerically stable without the need for filtering or artificial diffusion, it correctly models the discontinuity of fields across material boundaries, and it can be very high order. Higher-order H(curl) and H(div) conforming basis functions are not unique and we have designed an extensible C++ framework that supports a variety of specific instantiations of these such as standard interpolatory bases, spectral bases, hierarchical bases, and semi-orthogonal bases. Virtually any electromagnetics problem that can be cast in the language of differential forms can be solved using our framework. For time dependent problems a method-of-lines scheme is used where the Galerkin method reduces the PDE to a semi-discrete system of ODE's, which are then integrated in time using finite difference methods. For time integration of wave equations we employ the unconditionally stable implicit Newmark-Beta method, as well as the high order energy conserving explicit Maxwell Symplectic method; for diffusion equations, we employ a generalized Crank-Nicholson method. We conclude with computational examples from resonant cavity problems, time-dependent wave propagation problems, and transient eddy current problems, all obtained using the authors massively parallel computational electromagnetics code EMSolve.},

doi = {},

journal = {},

number = ,

volume = ,

place = {United States},

year = {2005},

month = {5}

}