Title :
Another new FDTD method for linear dispersive media-but this one´s the best yet
Author_Institution :
Space, Telecommun. & Radiosci. Lab., Stanford Univ., CA, USA
Abstract :
A number of different FDTD methods used to model electromagnetic propagation in linear dispersive media have been published. We introduce a new FDTD method for general linear dispersive media (dielectrics and non-magnetized cold plasmas) based on exponential fitting of the auxiliary difference equation. We show that the recursive convolution method, developed by Luebbers et al. (1990, 1991) is exactly equivalent to a particular discretization in the context of our new method. Using this alternate formulation of the recursive convolution method, we apply a new analysis technique to compare the accuracy of the recursive convolution method and the exponential fitting method, as well as other formulations based on straightforward difference approximations of the governing differential equations.
Keywords :
approximation theory; convolution; differential equations; dispersion (wave); electromagnetic wave propagation; finite difference time-domain analysis; FDTD method; accuracy; analysis technique; auxiliary difference equation; dielectrics; difference approximations; differential equations; electromagnetic propagation; exponential fitting method; linear dispersive media; nonmagnetized cold plasmas; recursive convolution method; Convolution; Dielectrics; Difference equations; Differential equations; Dispersion; Electromagnetic modeling; Electromagnetic propagation; Finite difference methods; Fitting; Plasmas;
Conference_Titel :
Antennas and Propagation Society International Symposium, 1995. AP-S. Digest
Conference_Location :
Newport Beach, CA, USA
Print_ISBN :
0-7803-2719-5
DOI :
10.1109/APS.1995.529997
