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Estimating soil electric properties from monostatic ground‐penetrating radar signal inversion in the frequency domain
Author(s) -
Lambot S.,
Slob E. C.,
van den Bosch I.,
Stockbroeckx B.,
Scheers B.,
Vanclooster M.
Publication year - 2004
Publication title -
water resources research
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.863
H-Index - 217
eISSN - 1944-7973
pISSN - 0043-1397
DOI - 10.1029/2003wr002095
Subject(s) - ground penetrating radar , permittivity , frequency domain , dielectric , radar , acoustics , antenna (radio) , materials science , time domain , inversion (geology) , remote sensing , physics , geology , computer science , optoelectronics , telecommunications , computer vision , paleontology , structural basin
A new integrated approach for identifying the shallow subsurface electric properties from ground‐penetrating radar (GPR) signal is proposed. It is based on an ultrawide band (UWB) stepped frequency continuous wave (SFCW) radar combined with a dielectric filled transverse electric and magnetic (TEM) horn antenna to be used off the ground in monostatic mode; that is, a single antenna is used as emitter and receiver. This radar configuration is appropriate for subsurface mapping and allows for an efficient and more realistic modeling of the radar‐antenna‐subsurface system. Forward modeling is based on linear system response functions and on the exact solution of the three‐dimensional Maxwell equations for wave propagation in a horizontally multilayered medium representing the subsurface. Subsurface electric properties, i.e., dielectric permittivity and electric conductivity, are estimated by model inversion using the global multilevel coordinate search optimization algorithm combined sequentially with the local Nelder‐Mead simplex algorithm (GMCS‐NMS). Inversion of synthetic data and analysis of the corresponding response surfaces proved the uniqueness of the inverse solution. Laboratory experiments on a tank filled with a homogeneous sand subject to different water content levels further demonstrated the stability and accuracy of the solution toward measurement and modeling errors, particularly those associated with the dielectric permittivity. Inversion for the electric conductivity led to less satisfactory results. This was mainly attributed to the characterization of the frequency response of the antenna and to the high frequency dependence of the electric conductivity.

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