Title :
An improved near- to far-zone transformation for the finite-difference time-domain method
Author_Institution :
Defence Res. Establ., Linkoping, Sweden
fDate :
9/1/1998 12:00:00 AM
Abstract :
Near- to far-zone transformation for the finite-difference time-domain (FDTD) method can be performed by integration of the equivalent electric and magnetic currents originating from scattered electric and magnetic fields on a surface enclosing the object. Normally, when calculating the surface integrals, either the electric or magnetic fields are averaged since the electric and magnetic fields are spatially shifted in the FDTD grid. It is shown that this interpolation is unnecessary and also less accurate than if an integration is performed on two different surfaces. It is also shown that the accuracy of the far-zone transformation can be further improved if the phase is compensated with respect to a second-order dispersion corrected wavenumber. For validation, scattering results for an empty volume, a circular disk, and a sphere are compared with analytical solutions
Keywords :
dispersion (wave); electric current; electric fields; electromagnetic wave polarisation; electromagnetic wave scattering; finite difference time-domain analysis; integration; magnetic fields; radar cross-sections; FDTD; Green´s function; RCS; TE-polarisation; circular disk; electric current; empty volume; finite-difference time-domain method; integration; magnetic current; near to far-zone transformation; phase compensation; scattered electric field; scattered magnetic field; scattering results; second-order approximation; second-order dispersion corrected wavenumber; surface integrals; Dielectric losses; Discrete Fourier transforms; Finite difference methods; Frequency domain analysis; Interpolation; Magnetic analysis; Magnetic fields; Radar scattering; Surface treatment; Time domain analysis;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
