Title :
Complex image model for ground-penetrating radar antennas
Author :
Leat, Christopher J. ; Shuley, Nicholas V. ; Stickley, Glen F.
Author_Institution :
Dept. of Electr. & Comput. Eng., Queensland Univ., Brisbane, Qld., Australia
fDate :
10/1/1998 12:00:00 AM
Abstract :
A method of combining the complex image method with the constant Q assumption is derived, which enables the calculation of complex image parameters once for the whole frequency range in the general half-space case. The mixed potential method of moments is then used to model horizontal wire dipoles near a lossy half-space, using pulse-basis functions and point matching. The method is demonstrated by the modeling of two types of wire dipole. A conductive half-wave dipole shows excellent agreement with NEC-S. The current distribution of a 3.4 m resistively loaded dipole across the frequency range 0-512 MHz is also calculated and transformed to the time domain. The result agrees with published measurements. The time required on a workstation was reduced to 4/s per frequency point
Keywords :
Green´s function methods; Q-factor; current distribution; dipole antennas; electric potential; method of moments; radar antennas; time-domain analysis; wire antennas; 0 to 512 MHz; 3.4 m; Green´s function; NEC-S; complex image model; complex image parameters; conductive half-wave dipole; constant Q; current distribution; frequency range; general half-space; ground-penetrating radar antennas; horizontal wire dipoles; integral equations; lossy half-space; mixed potential method of moments; point matching; published measurements; pulse-basis functions; resistively loaded dipole; time domain; wire dipole; workstation; Dipole antennas; Frequency; Ground penetrating radar; Information processing; Moment methods; Permittivity; Radar antennas; Radar scattering; Signal processing; Wire;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
