Title :
An analysis of a staked dipole probe on a lossy Earth plane using the finite-difference time-domain method
Author :
Thiel, David V. ; Mittra, Raj
Author_Institution :
Sch. of Microelectron. Eng., Griffith Univ., Brisbane, Qld., Australia
fDate :
9/1/1997 12:00:00 AM
Abstract :
Using the finite-difference time-domain (FDTD) method, an electrically short, staked, grounded horizontal probe is shown to have an open circuit voltage directly related to the horizontal electric field at the Earth´s surface providing the surface coupling is subtracted from the output. This result is valid not only for an infinitely deep Earth plane but also for one which is horizontally layered. The effective length of a staked probe is found to be dependent on the conductivity of the upper layer of the Earth, its depth, the length of the stakes, and also the frequency of measurement. The effect is significant at very low frequency (VLF) for ice, permafrost and dry sand-covered regions
Keywords :
difference equations; finite element analysis; geophysical prospecting; geophysical techniques; glaciology; hydrological techniques; ice; terrestrial electricity; 3 to 30 kHz; EM induction; EM method; FDTD; VLF; difference equations; dry sand; effective length; electromagnetic induction; finite element analysis; finite-difference time-domain method; geoelectric; geophysical measurement technique; grounded horizontal probe; horizontal electric field; horizontal layers; horizontally layered; hydrology; ice; lossy Earth plane; open circuit voltage; permafrost; prospecting method; staked dipole probe; staked probe length; surface coupling; terrestrial electricity; very low frequency; Conductivity measurement; Coupling circuits; Earth; Finite difference methods; Frequency measurement; Ice; Length measurement; Probes; Time domain analysis; Voltage;
Journal_Title :
Geoscience and Remote Sensing, IEEE Transactions on
