Title :
Efficient body of revolution finite-difference time-domain modeling of integrated lens antennas
Author :
Van der Vorst, Maarten J M ; De Maagt, Peter J I
Author_Institution :
Eur. Space Res. & Technol. Centre (ESTEC), Eur. Space Agency, Noordwijk, Netherlands
fDate :
7/1/2002 12:00:00 AM
Abstract :
An efficient body of revolution finite-difference time-domain (BOR-FDTD) method for the analysis of the radiation properties of integrated lens antennas is presented in this paper. By neglecting most of the reactive power of the planar feed and by expanding the filtered source currents into azimuthal modes, lenses with both rotationally and nonrotationally symmetric planar feeds can be handled. It appears that three to four azimuthal modes are sufficient to adequately model the magnetic currents of a double-slot feed. Therefore, compared to a full three-dimensional (3-D) numerical method, the implementation of the proposed method is very time and memory efficient. If only the radiation properties are required, the model described here can also be applied efficiently to other axially symmetric geometries with an asymmetric feeding structure.
Keywords :
antenna feeds; antenna radiation patterns; antenna theory; finite difference time-domain analysis; lens antennas; submillimetre wave antennas; 500 GHz; asymmetric feeding structure; axially symmetric geometries; azimuthal modes; body of revolution finite-difference time-domain modeling; double-slot feed; filtered source currents; integrated lens antennas; magnetic currents; nonrotationally symmetric planar feeds; normalized far-field patterns; radiation properties; rotationally symmetric planar feeds; submillimeter-wave region; Antenna feeds; Dielectrics; Finite difference methods; Fourier transforms; Geometrical optics; Lenses; Magnetic separation; Reactive power; Space technology; Time domain analysis;
Journal_Title :
Microwave and Wireless Components Letters, IEEE
DOI :
10.1109/LMWC.2002.801138
