Title :
Two-dimensional finite-difference modeling of media with inclined uniaxial conductivity with an equivalent biaxial conductivity tensor for homogeneous TM-type wave propagation problems
Author :
Wilson, Glenn A. ; Thiel, David V.
Author_Institution :
Sch. of Microelectron. Eng., Griffith Univ., Brisbane, Qld., Australia
fDate :
7/1/2003 12:00:00 AM
Abstract :
The principle of numerically modeling the surface impedance of a homogeneous transverse magnetic (TM)-type plane wave incident upon an inhomogeneous half-space with inclined uniaxial electrical anisotropy as an equivalent half-space with fundamental electrical biaxial anisotropy is demonstrated. The self-consistent impedance method is introduced and shown to accurately model the surface impedance response of these two-dimensional (2-D) induction problems at low frequencies relevant to surface impedance geophysics, though there is inaccuracy in the surface impedance phase as the frequency is increased. While the impedance method has been introduced to demonstrate this modeling concept, the modeling principles introduced can be applied to other 2-D numerical methods.
Keywords :
backscatter; finite difference methods; geophysical techniques; radar cross-sections; radar theory; remote sensing by radar; terrain mapping; terrestrial electricity; EM wave scattering; TM type wave; TM wave; backscatter; equivalent biaxial conductivity tensor; finite difference model; geoelectric; geology; geophysical measurement technique; homogeneous propagation problem; inclined uniaxial conductivity; land surface; numerical model; radar remote sensing; radar scattering; radar theory; sedimentary rock; terrain mapping; terrestrial electricity; two dimensional model; Anisotropic magnetoresistance; Conductivity; Finite difference methods; Frequency; Impedance measurement; Magnetic anisotropy; Numerical models; Surface impedance; Surface waves; Tensile stress;
Journal_Title :
Geoscience and Remote Sensing, IEEE Transactions on
DOI :
10.1109/TGRS.2003.814915
