Title :
Measured Antenna Response of a Proposed Microwave Tomography System Using an Efficient 3-D FDTD Model
Author :
Padhi, S.K. ; Fhager, A. ; Persson, M. ; Howard, J.
Author_Institution :
Res. Sch. of Phys. Sci. & Eng., Australian Nat. Univ., Canberra, ACT
fDate :
6/30/1905 12:00:00 AM
Abstract :
This letter presents a detailed study of a microwave tomography system using 3-D finite-difference time-domain methods (FDTDs). The algorithm, which uses a subcell model in form of the thin-wire approximation to model wire antennas, has been validated numerically using published numerical electromagnetic code (NEC) data for dipole antennas, and experimentally by comparing with measurements obtained for a monopole antenna array. The agreement between calculated and measured performances of the monopoles is close. In order to understand the fabrication tolerance, a parametric study was performed with regards to position of ground plane and grid size. It is found that the ground plane plays an important role in the performance of the monopole antennas. The excellent agreement is very promising for future deployment of the algorithm in 3-D microwave tomography applications.
Keywords :
approximation theory; dipole antenna arrays; finite difference time-domain analysis; image reconstruction; image resolution; iterative methods; medical image processing; microwave antenna arrays; microwave imaging; monopole antenna arrays; tomography; 3-D FDTD model; diagnostic imaging; dipole antenna; fabrication tolerance; finite-difference time-domain method; grid resolution; iterative image reconstruction; measured antenna response; microwave tomography system; model wire antenna; monopole antenna array; numerical electromagnetic code data; subcell model; thin-wire approximation; tumor; Finite difference time domain method; microwave imaging; microwave measurements; resistive voltage source; transient analysis;
Journal_Title :
Antennas and Wireless Propagation Letters, IEEE
DOI :
10.1109/LAWP.2008.2009888
