Identifying the magnetic permeability in multi-frequency EM data inversion

Deidda, Gian Piero; Alba, Patricia Díaz de; Rodriguez, Giuseppe

doi:10.1553/etna_vol47s1

Cited by 16 publications

(32 citation statements)

References 23 publications

(43 reference statements)

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“…However, in principle, the regularization approach discussed here can also be extended to include the inversion for the µ components. This would require fixing an estimate for the conductivity and determining the permeability from the data [7], or computing both quantities by considering the readings defined in Eq. (2.2) as functions of 2n variables σ k and µ k , for k = 1, .…”

Section: The Inversion Schemementioning

confidence: 99%

“…The real part (in-phase component) is affected mainly by the magnetic permeability of the soil, while the imaginary part (out-of-phase or quadrature component) is affected mainly by its electrical conductivity. The in-phase or the quadrature component of the signal is typically inverted to reconstruct either the electrical conductivity or the magnetic permeability of the soil [9,7,10].…”

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confidence: 99%

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Inversion of Multiconfiguration Complex EMI Data with Minimum Gradient Support Regularization: A Case Study

et al. 2020

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Frequency-domain electromagnetic instruments allow the collection of data in different configurations, that is, varying the intercoil spacing, the frequency, and the height above the ground. Their handy size makes these tools very practical for near-surface characterization in many fields of applications, for example, precision agriculture, pollution assessments, and shallow geological investigations. To this end, the inversion of either the real (in-phase) or the imaginary (quadrature) component of the signal has already been studied. Furthermore, in many situations, a regularization scheme retrieving smooth solutions is blindly applied, without taking into account the prior available knowledge. The present work discusses an algorithm for the inversion of the complex signal in its entirety, as well as a regularization method that promotes the sparsity of the reconstructed electrical conductivity distribution. This regularization strategy incorporates a minimum gradient support stabilizer into a truncated generalized singular value decomposition scheme. The results of the implementation of this sparsity-enhancing regularization at each step of a damped Gauss-Newton inversion algorithm (based on a nonlinear forward model) are compared with the solutions obtained via a standard smooth stabilizer. An approach for estimating the depth of investigation, that is, the maximum depth that can be investigated by a chosen instrument configuration in a particular experimental setting, is also discussed. The effectiveness and limitations of the whole inversion algorithm are demonstrated on synthetic and real data sets.

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Section: The Inversion Schemementioning

confidence: 99%

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confidence: 99%

Inversion of Multiconfiguration Complex EMI Data with Minimum Gradient Support Regularization: A Case Study

et al. 2020

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“…Then, the 1D models obtained were stitched together to build a pseudo-3D volume of the investigated area. Inversion was performed using the FDEMtools [83], a free MATLAB software package implementing the numerical algorithms mainly discussed by Deidda et al [84][85][86]. A layered starting model consisting of 30 layers, to a depth of 3.5 m, was used to invert the electromagnetic data.…”

Section: Frequency Domain Electromagnetic (Fdem)mentioning

confidence: 99%

“…where λ is a variable of integration with no particular physical meaning, h is the height of the instrument above the ground, r the coil separation, J0 the Bessel function of order 0, and R0(λ) the response kernel, which is a complex value function of the parameters that describe the layered subsurface (i.e., for the k-th layer: the electrical conductivity σk, the magnetic permeability μk, and the layer thickness dk) besides the frequency and λ. The nonlinear inversion procedure proposed by Deidda et al [84][85][86] is a general procedure that allows the estimation of the electrical properties (electrical conductivity and magnetic permeability) of the subsurface by inverting the complex multi-depth response of different electromagnetic devices designed to record data at multiple coil spacings, using a single frequency, or at multiple frequencies with a fixed coil spacing. Let us suppose that the aim of the survey is estimating the vertical distribution of the electrical conductivity, using a multifrequency electromagnetic dataset (e.g., data recorded with the GEM-2 device).…”

Section: The Nonlinear Forward Problem and The Inversion Proceduresmentioning

confidence: 99%

Remote Sensing, Archaeological, and Geophysical Data to Study the Terramare Settlements: The Case Study of Fondo Paviani (Northern Italy)

et al. 2020

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During the Middle and Recent Bronze Age, the Po Plain and, more broadly Northern Italy were populated by the so-called “Terramare”, embanked settlements, surrounded by a moat. The buried remains of these archaeological settlements are characterized by the presence of a system of palaeo-environments and a consequent natural gradient in soil moisture content. These differences in the soil are often firstly detectable on the surface during the seasonal variations, with aerial, satellite, and Laser Imaging Detection and Ranging (LIDAR) images, without any information on the lateral and in-depth extension of the related buried structures. The variation in the moisture content of soils is directly related to their differences in electrical conductivity. Electrical resistivity tomography (ERT) and frequency domain electromagnetic (FDEM), also known as electromagnetic induction (EMI) measurements, provide non-direct measurements of electrical conductivity in the soils, helping in the reconstruction of the geometry of different buried structures. This study presents the results of the multidisciplinary approach adopted to the study of the Terramare settlement of Fondo Paviani in Northern Italy. Remote sensing and archaeological data, collected over about 10 years, combined with more recent ERT and FDEM measurements, contributed to the analysis of this particular, not yet wholly investigated, archaeological site. The results obtained by the integrated multidisciplinary study here adopted, provide new useful, interesting information for the archaeologists also suggesting future strategies for new studies still to be conducted around this important settlement.

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“…where J † k is the Moore-Penrose pseudoinverse of J k and α k is a damping parameter which ensures the convergence. It is determined by coupling the Armijo-Goldstein principle [2] to the positivity constraint (σ k+1 , µ k+1 ) > 0 (componentwise) [6,9].…”

Section: Inversion Procedurementioning

confidence: 99%

FDEMtools: a MATLAB package for FDEM data inversion

et al. 2019

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Electromagnetic induction surveys are among the most popular techniques for non-destructive investigation of soil properties, in order to detect the presence of both ground inhomogeneities and particular substances. This paper introduces a MATLAB package, called FDEMtools, for the inversion of frequency domain electromagnetic data collected by a ground conductivity meter, which includes a graphical user interface to interactively modify the parameters of the computation and visualize the results. Based on a nonlinear forward model used to describe the interaction between an electromagnetic field and the soil, the software reconstructs the distribution of either the electrical conductivity or the magnetic permeability with respect to depth, by a regularized damped Gauss-Newton method. The regularization part of the algorithm is based on a low-rank approximation of the Jacobian of the nonlinear model. The package allows the user to experiment with synthetic and experimental data sets, and different regularization strategies, in order to compare them and draw conclusions.

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Identifying the magnetic permeability in multi-frequency EM data inversion

Cited by 16 publications

References 23 publications

Inversion of Multiconfiguration Complex EMI Data with Minimum Gradient Support Regularization: A Case Study

Inversion of Multiconfiguration Complex EMI Data with Minimum Gradient Support Regularization: A Case Study

Remote Sensing, Archaeological, and Geophysical Data to Study the Terramare Settlements: The Case Study of Fondo Paviani (Northern Italy)

FDEMtools: a MATLAB package for FDEM data inversion

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