Title :
ELF Radar System Proposed for Localized D-Region Ionospheric Anomalies
Author :
Simpson, Jamesina J. ; Taflove, Allen
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., Northwestern Univ., Evanston, IL
Abstract :
This letter proposes a novel extremely low frequency (ELF) radar for localized D-region (altitude < 95 km) ionospheric anomalies that have been generated by natural geophysical processes. The proposed system would use the former U.S. Navy Wisconsin Transmitting Facility as a distant well-characterized impulsive ELF source. Sample calculations that demonstrate how passive vertical E-field detectors could characterize ionospheric conductivity depressions of variable diameter located above Los Angeles are provided. These calculations have been obtained using our recently developed three-dimensional whole-Earth electromagnetic wave propagation model based upon the rigorous finite-difference time-domain solution of Maxwell´s equations. A key potential application of the proposed ELF radar system is the detection of hypothesized ionospheric earthquake precursors
Keywords :
D-region; atmospheric electromagnetic wave propagation; earthquakes; finite difference time-domain analysis; ionospheric disturbances; ionospheric techniques; radiowave propagation; remote sensing by radar; 3D whole-Earth electromagnetic wave propagation model; ELF radar system; Maxwell equations; U.S. Navy Wisconsin Transmitting Facility; extremely low frequency radar; finite-difference time-domain solution; geophysical processes; hypothesized ionospheric earthquake precursors; impulsive ELF source; ionospheric conductivity depressions; ionospheric disturbances; localized D-region ionospheric anomalies; passive vertical E-field detectors; radar remote sensing; Conductivity; Detectors; Electromagnetic modeling; Electromagnetic propagation; Finite difference methods; Frequency; Geophysical measurement techniques; Ground penetrating radar; Radar detection; Time domain analysis; Earthquakes; extremely low frequency (ELF); finite difference time domain (FDTD); ionospheric disturbances; radar; remote sensing;
Journal_Title :
Geoscience and Remote Sensing Letters, IEEE
DOI :
10.1109/LGRS.2006.878443
