TY - JOUR
T1 - Remote estimation of the hydraulic properties of a sand using full-waveform integrated hydrogeophysical inversion of time-lapse, off-ground GPR data
AU - Lambot, Sébastien
AU - Slob, Evert
AU - Rhebergen, Jan
AU - Lopera, Olga
AU - Jadoon, Khan Zaib
AU - Vereecken, Harry
PY - 2009/8
Y1 - 2009/8
N2 - We used integrated hydrogeophysical inversion of time-lapse, proximal ground penetrating radar (GPR) data to remotely infer the unsaturated soil hydraulic properties of a laboratory sand during an infiltration event. The inversion procedure involved full-waveform modeling of the radar signal and one-dimensional, vertical flow modeling. We combined the radar model with HYDRUS-1D. The radar system was set up using standard, handheld vector network analyzer technology. Significant effects of water dynamics were observed on the time-lapse radar data. The estimated hydraulic parameters were relatively consistent with direct characterization of undisturbed sand samples. Significant differences were particularly observed for the saturated hydraulic conductivity, which was underestimated by two orders of magnitude. Nevertheless, the use of soil hydraulic parameters derived from reference measurements failed to correctly predict water dynamics, whereas GPR-based predictions captured some of the major features of time domain reflectometry measurements and better agreed with visual observations. These results suggest that the proposed method is promising for noninvasive, effective hydraulic characterization of the shallow subsurface and hence, monitoring of water dynamics at the field scale.
AB - We used integrated hydrogeophysical inversion of time-lapse, proximal ground penetrating radar (GPR) data to remotely infer the unsaturated soil hydraulic properties of a laboratory sand during an infiltration event. The inversion procedure involved full-waveform modeling of the radar signal and one-dimensional, vertical flow modeling. We combined the radar model with HYDRUS-1D. The radar system was set up using standard, handheld vector network analyzer technology. Significant effects of water dynamics were observed on the time-lapse radar data. The estimated hydraulic parameters were relatively consistent with direct characterization of undisturbed sand samples. Significant differences were particularly observed for the saturated hydraulic conductivity, which was underestimated by two orders of magnitude. Nevertheless, the use of soil hydraulic parameters derived from reference measurements failed to correctly predict water dynamics, whereas GPR-based predictions captured some of the major features of time domain reflectometry measurements and better agreed with visual observations. These results suggest that the proposed method is promising for noninvasive, effective hydraulic characterization of the shallow subsurface and hence, monitoring of water dynamics at the field scale.
KW - GMCS
KW - Global multilevel coordinate search, GPR
KW - Ground-penetrating radar, NMS
KW - Nelder-Mead simplex, PEC
KW - Perfect electrical conductor, SFCW
KW - Stepped-frequency continuous-wave, TDR
KW - Time-domain reflectometry, UWB
KW - Ultra-wideband
UR - http://www.scopus.com/inward/record.url?scp=70349325575&partnerID=8YFLogxK
U2 - 10.2136/vzj2008.0058
DO - 10.2136/vzj2008.0058
M3 - Article
AN - SCOPUS:70349325575
SN - 1539-1663
VL - 8
SP - 743
EP - 754
JO - Vadose Zone Journal
JF - Vadose Zone Journal
IS - 3
ER -