GPU-Accelerated Efficient Implementation of FDTD Methods With Optimum Time-Step Selection

Author

Zygiridis, T.T. ; Kantartzis, N.V. ; Tsiboukis, T.D.

Author_Institution

Dept. of Inf. & Telecommun. Eng., Univ. of Western Macedonia, Kozani, Greece

Volume

50

Issue

2

fYear

2014

fDate

Feb. 2014

Firstpage

477

Lastpage

480

Abstract

The consistent combination of uneven space-time orders in finite-difference time-domain (FDTD) algorithms is the subject of this paper. When low-order time integration is used in conjunction with high-order spatial expressions, the operation of the numerical scheme close to the stability limit causes degraded performance and slow convergence. By exploiting accuracy considerations, we derive an estimate of the optimum-much smaller-time-step size that ameliorates errors in a mean-value sense and leads to improved precision. To deal with the augmentation of the required iterations, the parallel implementation of the FDTD techniques on graphics processing units is pursued, ensuring faster code executions and more efficient models.

Keywords

finite difference time-domain analysis; graphics processing units; FDTD method; GPU; finite-difference time-domain; graphics processing units; high-order spatial expression; low-order time integration; optimum time-step selection; space-time order; stability limit; Accuracy; Convergence; Finite difference methods; Graphics processing units; Instruction sets; Stability analysis; Time-domain analysis; FDTD method; GPU computing; high-order algorithms; time stepping;

fLanguage

English

Journal_Title

Magnetics, IEEE Transactions on

Publisher

ieee

ISSN

0018-9464

Type

jour

DOI

10.1109/TMAG.2013.2282531

Filename

6749084