Title :
Finite-element analysis of complex axisymmetric radiating structures
Author :
Greenwood, Andrew D. ; Jin, Jian-Ming
Author_Institution :
Air Force Res. Lab., Kirtland AFB, NM, USA
fDate :
8/1/1999 12:00:00 AM
Abstract :
A finite-element method (FEM) is developed for the analysis of complex axisymmetric radiating structures. The method is based on the electric field formulation with the transverse field expanded in terms of edge-based vector basis functions and the azimuth component expanded using nodal-based scalar basis functions. This mixed representation of the electric field eliminates spurious solutions and permits an easy treatment of boundary conditions on conducting surfaces as well as across material interfaces. The FEM mesh is truncated using a previously developed cylindrical perfectly matched layer (PML). The method has been successfully applied to three radiating structures: a corrugated horn antenna, a spherical Luneburg lens, and a half Maxwell fish eye. Numerical results are presented to show the validity, accuracy, and efficiency of the method
Keywords :
antenna radiation patterns; conducting bodies; electric fields; finite element analysis; horn antennas; lenses; FEM mesh; accuracy; antenna radiation problems; azimuth component; boundary conditions; complex axisymmetric radiating structures; conducting surfaces; corrugated horn antenna; cylindrical perfectly matched layer; edge-based vector basis functions; efficiency; electric field; finite-element analysis; half Maxwell fish eye; material interfaces; mixed representation; nodal-based scalar basis functions; radiating structures; spherical Luneburg lens; transverse field; Azimuth; Boundary conditions; Conducting materials; Corrugated surfaces; Finite element methods; Horn antennas; Lenses; Optical materials; Perfectly matched layers; Surface treatment;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
