Title :
A frequency-dependent finite-difference time-domain formulation for dispersive materials
Author :
Luebbers, Raymond ; Hunsberger, Forrest P. ; Kunz, Karl S. ; Standler, Ronald B. ; Schneider, Michael
Author_Institution :
Dept. of Electr. Eng., Pennsylvania State Univ., University Park, PA, USA
fDate :
8/1/1990 12:00:00 AM
Abstract :
The traditional finite-difference time-domain (FDTD) formulation is extended to include a discrete time-domain convolution, which is efficiently evaluated using recursion. The accuracy of the extension is demonstrated by computing the reflection coefficient at an air-water interface over a wide frequency band including the effects of the frequency-dependent permittivity of water. Extension to frequency-dependent permeability and to three dimensions is straightforward. The frequency dependent FDTD formulation allows computation of electromagnetic interaction with virtually any material and geometry (subject only to computer resource limitations) with pulse excitation. Materials that are highly dispersive, such as snow, ice, plasma, and radar-absorbing material, can be considered efficiently by using this formulation.
Keywords :
electromagnetic wave scattering; finite element analysis; time-domain analysis; air-water interface; discrete time-domain convolution; dispersive materials; electromagnetic interaction; finite-difference time-domain formulation; frequency band; frequency dependent formulation; frequency-dependent permittivity; geometry; ice; plasma; pulse excitation; radar-absorbing material; reflection coefficient; snow; water; Computer interfaces; Convolution; Dispersion; Electromagnetic reflection; Finite difference methods; Frequency; Permeability; Permittivity; Time domain analysis; Water resources;
Journal_Title :
Electromagnetic Compatibility, IEEE Transactions on
