Error Analysis of Clay-Rock Water Content Estimation with Broadband High-Frequency Electromagnetic Sensors—Air Gap Effect

Boré, Thierry; Wagner, Norman; Lesoille, Sylvie Delepine; Taillade, Frédéric; Six, G.; Daout, Franck; Placko, Dominique

doi:10.3390/s16040554

Cited by 21 publications

(12 citation statements)

References 27 publications

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“…The broadband three-phase CRIM model used includes water relaxation, interfacial relaxation, as well as losses due to direct-current conductivity. From a practical point of view, the supposed model is sufficient for most soils and rocks in the considered frequency range from 1 MHz–10 GHz [ 25 , 26 , 44 , 47 ].…”

Section: Methodsmentioning

confidence: 99%

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Spatial Retrieval of Broadband Dielectric Spectra

Bumberger

Mai

Schmidt

et al. 2018

Sensors

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A broadband soil dielectric spectra retrieval approach (1 MHz–2 GHz) has been implemented for a layered half space. The inversion kernel consists of a two-port transmission line forward model in the frequency domain and a constitutive material equation based on a power law soil mixture rule (Complex Refractive Index Model—CRIM). The spatially-distributed retrieval of broadband dielectric spectra was achieved with a global optimization approach based on a Shuffled Complex Evolution (SCE) algorithm using the full set of the scattering parameters. For each layer, the broadband dielectric spectra were retrieved with the corresponding parameters thickness, porosity, water saturation and electrical conductivity of the aqueous pore solution. For the validation of the approach, a coaxial transmission line cell measured with a network analyzer was used. The possibilities and limitations of the inverse parameter estimation were numerically analyzed in four scenarios. Expected and retrieved layer thicknesses, soil properties and broadband dielectric spectra in each scenario were in reasonable agreement. Hence, the model is suitable for an estimation of in-homogeneous material parameter distributions. Moreover, the proposed frequency domain approach allows an automatic adaptation of layer number and thickness or regular grids in time and/or space.

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Section: Methodsmentioning

confidence: 99%

“…This issue is not considered in available TD solvers. In contrast, FD solvers overcome this inconsistency by solving the set of equations at a specific frequency, which allows the incorporation of the appropriate material properties without any restriction [ 44 , 45 ].…”

Section: Introductionmentioning

confidence: 99%

Spatial Retrieval of Broadband Dielectric Spectra

Bumberger

Mai

Schmidt

et al. 2018

Sensors

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“…Thus, the relative EM field distribution of the TDR array (Fig. 3) was investigated by means of a commercial finite element method solver for EM structures—Ansys HFSS high‐frequency EM field simulator (Ansys Inc.) as applied in several previous studies (Wagner et al, 2007, 2014; Bore et al, 2016). For simplification, the rod length in the model was set to 12 cm without considering the air gap.…”

Section: Methodsmentioning

confidence: 99%

A TDR Array Probe for Monitoring Near‐Surface Soil Moisture Distribution

Sheng

Rong

Sadeghi

et al. 2017

Vadose Zone Journal

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Core Ideas A TDR array has been developed for soil moisture profiling. The sensor provides eight incremental measurements at centimeter‐depth resolution. Permittivity, evaporation rate, and soil moisture profile were determined. Near‐surface soil conditions (i.e., moisture and temperature) moderate mass and energy exchange at the soil–atmosphere interface. While remote sensing offers an effective means for mapping near‐surface moisture content across large areas, in situ measurements, targeting those specific remotely sensed soil depths, are poorly understood and high‐resolution near‐surface measurement capabilities are lacking. Time domain reflectometry (TDR) is a well‐established, accurate measurement method for soil dielectric permittivity and moisture content. A TDR array was designed to provide centimeter‐resolution measurements of near‐surface soil moisture. The array consists of nine stainless steel TDR rods spaced 1 cm apart, acting as waveguide pairs to form eight two‐rod TDR probes in series. A critical aspect of the design was matching the spacing of the coaxial cable–TDR rod transition to avoid unwanted reflections in the waveforms. The accuracy of the TDR array permittivity measurement (±1 permittivity unit) was similar to that of conventional TDR as verified in dielectric liquids. Electric field numerical simulations showed minimal influence of adjacent rods during a given rod‐pair measurement. The evaporation rate determined by the TDR array compared well with mass balance data in a laboratory test. Near‐surface soil moisture profile dynamics were monitored at centimeter‐depth resolution using the TDR array in a field experiment where volumetric moisture content estimates (0–8 cm) were within 2% of conventional three‐rod TDR probes averaging across 0 to 8 cm and from 1‐ to 3‐cm depths.

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“…Moreover, the correction of temperature on apparent permittivity computed from TDR waveform with empirical calibration remains challenging[57,58]. Relaxation models have been widely used for soils[59,60] or suspensions[61] to model the spectrum as a sum of relaxation processes along the frequency bandwidth. The parameters for each process are computed by matching the spectrum and the model.…”

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confidence: 99%

Dielectric spectroscopy measurements on kaolin suspensions for sediment concentration monitoring

et al. 2018

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Sedimentation along with consolidation processes dictate the in situ engineering and hydraulic behavior of a particulate system such as soil. With this in view, the present investigation discusses about the application of dielectric measurements in relation to sediment concentration measurements for fine grained soils. An in-house set up comprising of open ended coaxial probes and vector network analyzer has been used to measure the dielectric behavior of kaolin suspensions in tap and deionized water. These have been further analyzed to furnish suspended sediment concentration, pore water conductivity and shape factors utilizing Complex Refractive Index Model (CRIM) and Bruggeman-Hanai-Sen (BHS) model, through the implementation of an optimization scheme. Furthermore, measured and estimated suspended sediment concentrations showed good agreement with each other in terms of statistical parameters, and a ranking of models approach reliant on three statistical criteria revealed that, CRIM outperforms BHS model for estimating sediment concentrations.

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Error Analysis of Clay-Rock Water Content Estimation with Broadband High-Frequency Electromagnetic Sensors—Air Gap Effect

Cited by 21 publications

References 27 publications

Spatial Retrieval of Broadband Dielectric Spectra

Spatial Retrieval of Broadband Dielectric Spectra

A TDR Array Probe for Monitoring Near‐Surface Soil Moisture Distribution

Dielectric spectroscopy measurements on kaolin suspensions for sediment concentration monitoring

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