Title :
Time-dependent surface impedance from sferics
Author :
O´Keefe, Yvette ; Thiel, David V. ; O´Keefe, Steven G.
Author_Institution :
Centre for Wireless Monitoring & Applic., Griffith Univ., Nathan, Qld., Australia
fDate :
4/1/2005 12:00:00 AM
Abstract :
Attempts to use discrete sferics for low-frequency impedance mapping have relied on Fourier analysis to derive time-independent frequency profiles of the earth. A one-dimensional transmission line model of the earth above a perfectly conducting layer is used to demonstrate that the impedance is time dependent. Assuming a sferic-type transient for the applied magnetic field, the electric field is changed significantly corresponding to the time of flight of the radiation in the lossy earth. In an attempt to maintain this timing information and its link with the frequency components, the wavelet transform was implemented to analyze the data. The associated surface impedance may be approximated as the input impedance of the earth during excitation but reverts to the impedance of free space once the source field returns to zero.
Keywords :
Fourier analysis; atmospheric electromagnetic wave propagation; atmospherics; ionosphere; remote sensing; wavelet transforms; 1D transmission fine model; Fourier analysis; atmospherics; conducting layer; low-frequency impedance mapping; natural source electromagnetic waves; sferics; time-dependent surface impedance; time-independent frequency profiles; wavelet transform; Earth; Frequency; Magnetic analysis; Magnetic fields; Power system transients; Surface impedance; Timing; Transmission lines; Wavelet analysis; Wavelet transforms; Sferics; surface impedance; transmission line model; wavelets;
Journal_Title :
Geoscience and Remote Sensing Letters, IEEE
DOI :
10.1109/LGRS.2004.843206
