A fast local embedded boundary method suitable for high power electromagnetic sources

A fast local embedded boundary method suitable for high power electromagnetic sources

High power sources of electromagnetic energy often require complicated structures to support electromagnetic modes and shape electromagnetic fields to maximize the coupling of the field energy to intense relativistic electron beams. Geometric fidelity is critical to the accurate simulation of these...

Full description

Bibliographic Details
Main Authors: Mathialakan Thavappiragasam, Andrew Christlieb, John Luginsland, Pierson Guthrey
Format: Article
Language:English
Published: AIP Publishing LLC 2020-11-01
Series:AIP Advances
Online Access:http://dx.doi.org/10.1063/5.0019210
id doaj-e1f59a2a4bea4d66b111bdd9410d9e3d
record_format Article
spelling doaj-e1f59a2a4bea4d66b111bdd9410d9e3d2020-12-04T12:45:21ZengAIP Publishing LLCAIP Advances2158-32262020-11-011011115318115318-1410.1063/5.0019210A fast local embedded boundary method suitable for high power electromagnetic sourcesMathialakan Thavappiragasam0Andrew Christlieb1John Luginsland2Pierson Guthrey3Department of Computational Mathematics Science and Engineering, Michigan State University, East Lansing, Michigan 48824, USADepartment of Computational Mathematics Science and Engineering, Michigan State University, East Lansing, Michigan 48824, USADepartment of Computational Mathematics Science and Engineering, Michigan State University, East Lansing, Michigan 48824, USALawrence Livermore National Laboratory, Livermore, California 94551, USAHigh power sources of electromagnetic energy often require complicated structures to support electromagnetic modes and shape electromagnetic fields to maximize the coupling of the field energy to intense relativistic electron beams. Geometric fidelity is critical to the accurate simulation of these High Power Electromagnetic (HPEM) sources. Here, we present a fast and geometrically flexible approach to calculate the solution to Maxwell’s equations in vector potential form under the Lorenz gauge. The scheme is an implicit, linear-time, high-order, A-stable method that is based on the method of lines transpose (MOLT). As presented, the method is fourth order in time and second order in space, but the A-stable formulation could be extended to both high order in time and space. An O(n) fast convolution is employed for space-integration. The main focus of this work is to develop an approach to impose perfectly electrically conducting (PEC) boundary conditions in MOLT by extending our past work on embedded boundary methods. As the method is A-stable, it does not suffer from small time step limitations that are found in explicit finite difference time domain methods when using either embedded boundary or cut-cell methods to capture geometry. This is a major advance for the simulation of HPEM devices. While there is no conceptual limitation to develop this in 3D, our initial work has centered on 2D. The extension to 3D requires validation that the proposed fixed point iteration will converge and is the subject of our follow-up work. The eventual goal is to combine this method with particle methods for the simulations of plasma. In the current work, the scheme is evaluated for EM wave propagation within an object that is bounded by PEC. The consistency and performance of the scheme are confirmed using the ping test and frequency mode analysis for rotated square cavities—a standard test in the HPEM community. We then demonstrate the diffraction Q value test and the use of this method for simulating an A6 magnetron. The ability to handle both PEC and open boundaries in a standard device test problem, such as the A6, gives confidence on the robustness of this new method.http://dx.doi.org/10.1063/5.0019210
collection DOAJ
language English
format Article
sources DOAJ
author Mathialakan Thavappiragasam
Andrew Christlieb
John Luginsland
Pierson Guthrey
spellingShingle Mathialakan Thavappiragasam
Andrew Christlieb
John Luginsland
Pierson Guthrey
A fast local embedded boundary method suitable for high power electromagnetic sources
AIP Advances
author_facet Mathialakan Thavappiragasam
Andrew Christlieb
John Luginsland
Pierson Guthrey
author_sort Mathialakan Thavappiragasam
title A fast local embedded boundary method suitable for high power electromagnetic sources
title_short A fast local embedded boundary method suitable for high power electromagnetic sources
title_full A fast local embedded boundary method suitable for high power electromagnetic sources
title_fullStr A fast local embedded boundary method suitable for high power electromagnetic sources
title_full_unstemmed A fast local embedded boundary method suitable for high power electromagnetic sources
title_sort fast local embedded boundary method suitable for high power electromagnetic sources
publisher AIP Publishing LLC
series AIP Advances
issn 2158-3226
publishDate 2020-11-01
description High power sources of electromagnetic energy often require complicated structures to support electromagnetic modes and shape electromagnetic fields to maximize the coupling of the field energy to intense relativistic electron beams. Geometric fidelity is critical to the accurate simulation of these High Power Electromagnetic (HPEM) sources. Here, we present a fast and geometrically flexible approach to calculate the solution to Maxwell’s equations in vector potential form under the Lorenz gauge. The scheme is an implicit, linear-time, high-order, A-stable method that is based on the method of lines transpose (MOLT). As presented, the method is fourth order in time and second order in space, but the A-stable formulation could be extended to both high order in time and space. An O(n) fast convolution is employed for space-integration. The main focus of this work is to develop an approach to impose perfectly electrically conducting (PEC) boundary conditions in MOLT by extending our past work on embedded boundary methods. As the method is A-stable, it does not suffer from small time step limitations that are found in explicit finite difference time domain methods when using either embedded boundary or cut-cell methods to capture geometry. This is a major advance for the simulation of HPEM devices. While there is no conceptual limitation to develop this in 3D, our initial work has centered on 2D. The extension to 3D requires validation that the proposed fixed point iteration will converge and is the subject of our follow-up work. The eventual goal is to combine this method with particle methods for the simulations of plasma. In the current work, the scheme is evaluated for EM wave propagation within an object that is bounded by PEC. The consistency and performance of the scheme are confirmed using the ping test and frequency mode analysis for rotated square cavities—a standard test in the HPEM community. We then demonstrate the diffraction Q value test and the use of this method for simulating an A6 magnetron. The ability to handle both PEC and open boundaries in a standard device test problem, such as the A6, gives confidence on the robustness of this new method.
url http://dx.doi.org/10.1063/5.0019210
work_keys_str_mv AT mathialakanthavappiragasam afastlocalembeddedboundarymethodsuitableforhighpowerelectromagneticsources
AT andrewchristlieb afastlocalembeddedboundarymethodsuitableforhighpowerelectromagneticsources
AT johnluginsland afastlocalembeddedboundarymethodsuitableforhighpowerelectromagneticsources
AT piersonguthrey afastlocalembeddedboundarymethodsuitableforhighpowerelectromagneticsources
AT mathialakanthavappiragasam fastlocalembeddedboundarymethodsuitableforhighpowerelectromagneticsources
AT andrewchristlieb fastlocalembeddedboundarymethodsuitableforhighpowerelectromagneticsources
AT johnluginsland fastlocalembeddedboundarymethodsuitableforhighpowerelectromagneticsources
AT piersonguthrey fastlocalembeddedboundarymethodsuitableforhighpowerelectromagneticsources
_version_ 1724400530967494656

Similar Items