Title :
Modeling and investigation of a geometrically complex UWB GPR antenna using FDTD
Author :
Kwan-ho Lee ; Chen, Chi-Chih ; Teixeira, Fernando L. ; Lee, Kwan-Ho
Author_Institution :
Dept. of Electr. Eng., Ohio State Univ., Columbus, OH, USA
Abstract :
A detailed analysis of ultrawide-band (UWB), dual-polarized, dielectric-loaded horn-fed bow-tie (HFB) antennas is carried out using the finite-difference time-domain (FDTD) method. The FDTD model includes realistic features of the antenna structure such as the feeding cables, wave launchers, dielectric loading, and resistive-film loading. Important antenna characteristics that are usually difficult to obtain via measurements can be obtained more directly from this FDTD model. Since the HFB antennas under consideration are intended for ground penetrating radar (GPR) applications, the effects of the half-space medium are also investigated. The simulated results serve to verify the performance of the HFB antenna design, and to optimize various antenna parameters.
Keywords :
antenna feeds; broadband antennas; dielectric polarisation; dielectric-loaded antennas; electric impedance; electromagnetic wave polarisation; finite difference time-domain analysis; ground penetrating radar; horn antennas; multifrequency antennas; radar polarimetry; FDTD; antenna characteristic; antenna design; antenna impedance; antenna parameter; antenna structure; feeding coaxial cable; finite-difference time-domain method; geometrically complex UWB GPR antenna; ground penetrating radar application; resistive-film loading; ultrawide-band dual-polarized dielectric-loaded horn-fed bow-tie antenna; wave launcher; Antenna feeds; Cables; Dielectrics; Finite difference methods; Ground penetrating radar; Horn antennas; Loaded antennas; Solid modeling; Time domain analysis; Ultra wideband antennas; Bow-tie antenna; FDTD; GPR; UWB; coaxial cable; dielectric loading; finite-difference time-domain; ground penetrating radar; impedance; resistive; ultrawide-band;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
DOI :
10.1109/TAP.2004.832501
