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Journal ArticleDOI

3D controlled-source electromagnetic modeling in anisotropic medium using edge-based finite element method

Hongzhu Cai1, Bin Xiong2, Muran Han1, Michael S. Zhdanov3
University of Utah1, Guilin University of Technology2, Moscow Institute of Physics and Technology3
01 Dec 2014-Computers & Geosciences (Pergamon Press, Inc.PUB1185Elmsford, NY, USA)-Vol. 73, pp 164-176
TL;DR: The method uses the edge-based vector basis functions, which automatically enforce the divergence free conditions for electric and magnetic fields, which is effective in modeling the seafloor bathymetry using hexahedral mesh.
About: This article is published in Computers & Geosciences.The article was published on 2014-12-01 and is currently open access. It has received 85 citations till now. The article focuses on the topics: Mixed finite element method & Extended finite element method.

Summary (3 min read)

Jump to: [1. Introduction][4. Comparison with semi-analytical solution for a horizontally layered geoelectrical model][5. Model of an off-shore hydrocarbon reservoir][5.1. Model 1: isotropic background and isotropic reservoir][5.2. Model 2: anisotropic background with isotropic reservoir][5.3. Model 3: isotropic background with anisotropic reservoir][5.4. Model 4: anisotropic background with anisotropic reservoir][6. Modeling the effect of the bathymetry on the EM data] and [7. Conclusions]

1. Introduction

  • For accurate interpretation of the subsurface structure using the MCSEM method, the bathymetry effect should be accurately simulated.
  • The edge-based finite element method uses vector basis functions defined on the edges of the corresponding elements.
  • More advanced preconditioners based on the approximated inverse of the stiffness matrix can be used to speed up the solvers.

4. Comparison with semi-analytical solution for a horizontally layered geoelectrical model

  • The frequency of the harmonic electric source is 0.5 Hz.
  • The grid is refined nearby the source, target layer and the surface of observation (see Fig. 3).
  • Fig. 4 shows a comparison of the anomalous electric field between the finite element solution and the 1D semi-analytical solution.
  • One can see that the finite element results are in a good agreement with the semi-analytical solution.
  • For this model with the specified source configuration, the y component of secondary electric field, the x and z components of secondary magnetic field are equal to 0 at y¼0.

5. Model of an off-shore hydrocarbon reservoir

  • Hz, which is a typical frequency for marine CSEM.
  • The EM receivers are located on the seafloor.
  • The sparsity pattern for the finite element stiffness matrix is shown in panel (a) of Fig.
  • From this figure, one can see that the matrix is very sparse, although the problem size is huge.
  • In the second model, the authors consider an anisotropic background conductivity and isotropic anomalous conductivity for the reservoir.

5.1. Model 1: isotropic background and isotropic reservoir

  • The numerical result obtained by the edge-based finite element method was compared with the integral equation solution.
  • One can clearly see an anomaly around x¼2 km where the offset is about 5 km.
  • Due to the page limits, the authors will only show the numerical modeling result for the frequency of 1 Hz in the following sections.
  • Due to the page limits, the authors only show a comparison of the convergences of QMR, GMRES and BiCGSTAB solvers for Model 1.
  • It took about 20 min to solve this model using the finite element method and about 3 min for the integral equation method on a PC with 2.6 GHz CPU.

5.2. Model 2: anisotropic background with isotropic reservoir

  • In a marine environment, the conductivity of sediments shows a strong transverse anisotropy due to the process of sedimentation with the longitudinal conductivity being larger than the transverse conductivity (Ellis et al., 2010; Ramananjaona et al., 2011).
  • The macroanisotropy is mainly caused by thin layering when bulk resistivity is measured so that the electric current prefers to travel parallel to the bedding planes (Ellis et al., 2010).
  • This transverse anisotropy could have a strong effect on the primary field and the anomalous field could also be distorted significantly.
  • The conductivity of seawater and air stays unchanged compared to the previous model.
  • As in the previous model, the authors compare the finite element result with the integral equation solution.

5.3. Model 3: isotropic background with anisotropic reservoir

  • In practical applications of the MCSEM method, not only the conductivity of the sea-bottom sediments, but also the reservoir conductivity can be anisotropic.
  • The reservoir anisotropy is usually weak in comparison to the background conductivity anisotropy (Brown et al., 2012).
  • The authors can see that the result obtained by the integral equation method is practically the same as the finite element solution for the anisotropic reservoir model.
  • Ex components of the background and total electric field with the frequency of 1 Hz.
  • The total memory requirement for solving this problem using finite element and integral equation methods were practically the same as for Model 1.

5.4. Model 4: anisotropic background with anisotropic reservoir

  • Finally, the authors study Model 4 having transverse anisotropy of both the background and reservoir conductivities.
  • Hz, with the anomaly observed around a point x¼3 km, which corresponds to the 6 km offset.
  • The total memory requirement of this problem for finite element and integral equation methods are the same as Model 1.
  • The effect of the anisotropy of background conductivity is manifested by shifting the anomaly to larger offset, while the increase of the anisotropy coefficient of the reservoir increases the amplitude of the anomaly without shifting the anomaly significantly.
  • Thus, their numerical modeling results confirm ones again that quantitative interpretation of the MCSEM data requires taking into account the effect of anisotropy on the observed data.

6. Modeling the effect of the bathymetry on the EM data

  • One of the advantages of the edge-based finite element method is its ability to model the bathymetry effect on the EM data.
  • Fig. 23 shows the hexahedral grid for the bathymetry model without a reservoir in the X–Z section at y¼0.
  • Fig. 26 shows a comparison of the anomalous field at y¼0 along the bathymetry, with the frequency of 1 Hz, computed using both the edge-based finite element and integral equation methods.
  • One can see that the results produced by these two methods show a good agreement.
  • Some minor difference may be related to the staircase approximation used in the integral equation method.

7. Conclusions

  • The authors have developed an edge-based finite element algorithm to solve the diffusive electromagnetic problem in the 3D anisotropic medium.
  • The authors use the edge-based vector basis functions, which automatically enforce the divergence free conditions for electric and magnetic fields.
  • The sparse finite element system is solved using the quasiminimum residual method with a Jacobian preconditioner.
  • The results of numerical study confirm the accuracy and the efficiency of a new code.

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Figures (29)
Citations
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Journal ArticleDOI
Towards an open-source landscape for 3-D CSEM modelling

[...]

Dieter Werthmüller1, Raphael Rochlitz2, Octavio Castillo-Reyes3, Lindsey J. Heagy4
Delft University of Technology1, Leibniz Association2, Barcelona Supercomputing Center3, University of California, Berkeley4
12 Jul 2021-Geophysical Journal International
TL;DR: Weckmann et al. as discussed by the authors proposed a tetrahedra mesh in matplotlib through PyVista, Seogi Kang for the input and octree mesh design for the SimPEGlayer and block models, and Joseph Capriotti for the octree meshes implementation and volume averaging.
Abstract: We would like to thank Bane Sullivan for plotting of tetrahedra meshes in matplotlib through PyVista, Seogi Kang for the input and octree mesh design for the SimPEGlayer and block models and Joseph Capriotti for the octree mesh implementation and volume averaging in SimPEG. We would also like to thank Paulo Menezes for the help and explanations with regard to the Marlim R3D model and corresponding CSEM data, and for making their actual computation model available under an open-source license. We would further like to thank the editor Ute Weckmann and assistant editor Fern Story as well as the reviewers Colin Farquharson and Rune Mittet for many helpful comments, which improved this manuscript considerably. The work of DW was conducted within the Gitaro.JIM project funded through MarTERA, a European Union’s Horizon 2020 Framework Programme, grant agreement No. 728053. The development of custEM by RR as part of the DESMEX/DESMEX II projects was funded by the Germany Ministry for Education and Research (BMBF) in the framework of the research and development program Fona-r4 under grants 033R130D/033R130DN. The work of OC-R has received funding from the European Union’s Horizon 2020 Framework Programme under the Marie Sklodowska-Curie grant agreement No. 777778. Further, the development of PETGEM has received funding from the European Union’s Horizon 2020 Framework Programme, grant agreement No. 828947, and from the Mexican Department of Energy, CONACYT-SENER Hidrocarburos grant agreement No. B-S-69926. Furthermore, OC-R has been 65% cofinanced by the European Regional Development Fund (ERDF) through the Interreg V-A Spain-France-Andorra program (POCTEFA2014-2020). POCTEFA aims to reinforce the economic and social integration of the French–Spanish–Andorran border. Its support is focused on developing economic, social and environmental cross-border activities through joint strategies favouring sustainable territorial development. The work of LH received funding from the National Science Foundation EarthCube program under award 1928406

8 citations

Journal ArticleDOI
Simulation of Electromagnetic Scattering of 3-D Inhomogeneous Biaxial Anisotropic Magnetodielectric Objects Embedded in Uniaxial Anisotropic Media by the Mixed-Order BCGS-FFT Method

[...]

Jianliang Zhuo1, Feng Han1, Longfang Ye1, Zhiru Yu2, Qing Huo Liu2 
Xiamen University1, Duke University2
14 Jun 2018-IEEE Transactions on Microwave Theory and Techniques
TL;DR: In this article, a volume integral equation (VIE) solver for the forward electromagnetic scattering of 3D inhomogeneous biaxial anisotropic objects embedded in uni-dimensional unisotropic media is presented.
Abstract: This paper presents a volume integral equation (VIE) solver for the forward electromagnetic scattering of 3-D inhomogeneous biaxial anisotropic objects embedded in uniaxial anisotropic media. The optical axes of the objects can be rotated with arbitrary angles. The mixed-order basis functions are employed to discretize the VIE, i.e., the flux densities $(D, B)$ are expanded by the volumetric rooftop basis functions and the vector potentials $(A, F)$ are expanded by the second-order curl conforming basis functions. The weak form of the VIE is formulated by testing it using the same volumetric rooftop basis function and solved by the biconjugate gradient stabilized fast Fourier transform (BCGS-FFT) method. Several numerical simulations of different shapes anisotropic objects are performed and the results are compared with commercial software simulations to validate the accuracy and efficiency of the proposed solver based on different discretization schemes. The major new contribution of this paper is that not only the scatterer but also the background medium is magnetodielectrically anisotropic. Therefore, the dyadic Green’s function for the uniaxial anisotropic background medium is evaluated before solving the VIE.

7 citations

Cites background or methods from "3D controlled-source electromagneti..."

  • ...[26] present a linear edge-based finite element method (FEM) for numerical modeling of 3-D controlledsource EM data in an anisotropic conductive medium....

    [...]

  • ...Actually, since the Lorentz–Mie theory that gives the analytical solution of the EM scattering by a uniform anisotropic dielectric sphere [17]–[19], a lot of research work has been done to solve the scattering problems using both analytical and numerical methods [20]–[26]....

    [...]

Proceedings ArticleDOI
Edge-based electric field formulation in 3D CSEM simulations: A parallel approach

[...]

Octavio Castillo Reyes1, Josep de la Puente1, Vladimir Puzyrev1, José María Cela1
Barcelona Supercomputing Center1
03 Dec 2015
TL;DR: A parallel computing scheme for the data computation that arise when applying one of the most popular electromagnetic methods in exploration geophysics, namely, controlled-source electromagnetic (CSEM), based on linear edge finite element method in 3D isotropic domains is presented.
Abstract: This paper presents a parallel computing scheme for the data computation that arise when applying one of the most popular electromagnetic methods in exploration geophysics, namely, controlled-source electromagnetic (CSEM). The computational approach is based on linear edge finite element method in 3D isotropic domains. The total electromagnetic field is decomposed into primary and secondary electromagnetic field. The primary field is calculated analytically using an horizontal layered-earth model and the secondary field is discretized by linear edge finite element method. We pre-calculated the primary field through of an embarrassingly-parallel framework in order to exploit the parallelism and the advantages of geometric flexibility. The numerical-computational formulation presented here is able to work with three different orientations for the dipole or excitation source. Our code is implemented on unstructured tetrahedral meshes because are able to represent complex geological structures and they allow local refinement in order to improve the solution's accuracy. The code's performance is studied through a test of scalability.

7 citations

Journal ArticleDOI
Finite-element modeling of 3d mcsem in arbitrarily anisotropic medium using potentials on unstructured grids

[...]

Chen Han-Bo1, LI Tong-lin1, Xiong Bin, Chen Shuai1, Liu Yong-Liang1 
Jilin University1
01 Nov 2017-Chinese Journal of Geophysics

7 citations

Journal ArticleDOI
3D finite difference modeling of controlled-source electromagnetic response in frequency domain based on a modified curl-curl equation

[...]

Jian Li1, Rong Liu1, Rongwen Guo1, Yongfei Wang1, Xulong Wang1 
Central South University1
01 Dec 2020-Journal of Applied Geophysics
TL;DR: A 3D finite difference CSEM modeling algorithm based on a modified version of the curl-curl equations with scaled grad-div operator (CCGD) in frequency domain and the results indicate that the proposed CCGD approach is efficient and stable over different frequencies.

7 citations

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TL;DR: This chapter discusses methods related to the normal equations of linear algebra, and some of the techniques used in this chapter were derived from previous chapters of this book.
Abstract: Preface 1. Background in linear algebra 2. Discretization of partial differential equations 3. Sparse matrices 4. Basic iterative methods 5. Projection methods 6. Krylov subspace methods Part I 7. Krylov subspace methods Part II 8. Methods related to the normal equations 9. Preconditioned iterations 10. Preconditioning techniques 11. Parallel implementations 12. Parallel preconditioners 13. Multigrid methods 14. Domain decomposition methods Bibliography Index.

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Abstract: Recently the Conjugate Gradients-Squared (CG-S) method has been proposed as an attractive variant of the Bi-Conjugate Gradients (Bi-CG) method. However, it has been observed that CG-S may lead to a rather irregular convergence behaviour, so that in some cases rounding errors can even result in severe cancellation effects in the solution. In this paper, another variant of Bi-CG is proposed which does not seem to suffer from these negative effects. Numerical experiments indicate also that the new variant, named Bi-CGSTAB, is often much more efficient than CG-S.

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TL;DR: The Finite Element Method in Electromagnetics, Third Edition as discussed by the authors is a leading textbook on the finite element method, incorporating major advancements and further applications in the field of electromagnetic engineering.
Abstract: A new edition of the leading textbook on the finite element method, incorporating major advancements and further applications in the field of electromagneticsThe finite element method (FEM) is a powerful simulation technique used to solve boundary-value problems in a variety of engineering circumstances. It has been widely used for analysis of electromagnetic fields in antennas, radar scattering, RF and microwave engineering, high-speed/high-frequency circuits, wireless communication, electromagnetic compatibility, photonics, remote sensing, biomedical engineering, and space exploration.The Finite Element Method in Electromagnetics, Third Edition explains the methods processes and techniques in careful, meticulous prose and covers not only essential finite element method theory, but also its latest developments and applicationsgiving engineers a methodical way to quickly master this very powerful numerical technique for solving practical, often complicated, electromagnetic problems.Featuring over thirty percent new material, the third edition of this essential and comprehensive text now includes:A wider range of applications, including antennas, phased arrays, electric machines, high-frequency circuits, and crystal photonicsThe finite element analysis of wave propagation, scattering, and radiation in periodic structuresThe time-domain finite element method for analysis of wideband antennas and transient electromagnetic phenomenaNovel domain decomposition techniques for parallel computation and efficient simulation of large-scale problems, such as phased-array antennas and photonic crystalsAlong with a great many examples, The Finite Element Method in Electromagnetics is an ideal book for engineering students as well as for professionals in the field.

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"3D controlled-source electromagneti..." refers background or methods in this paper

  • ...…E N E E N E, , , (9) x e i xi e xi e y e i yi e yi e z e i zi e zi e 1 4 1 4 1 4 where the edge basis functions are defined by the following expressions (Jin, 2002): = + − + −N l l y l y z l z 1 2 2 , (10) x e y e z e c e y e c e z e 1 ⎛ ⎝ ⎜⎜ ⎞ ⎠ ⎟⎟ ⎛ ⎝ ⎜⎜ ⎞ ⎠ ⎟⎟ = − + + −N l l y y l z l z 1 2 2 ,…...

    [...]

  • ...The integrals in (27) and (28) can be calculated analytically for the rectangular elements (Jin, 2002)....

    [...]

  • ...Following the work of Jin (2002) and Silva et al. (2012), we consider the homogeneous Dirichlet boundary conditions in the edge element formulation | =Ω∂e 0 (30) which holds approximately for the anomalous electric field at a distance from the domain with the anomalous conductivity....

    [...]

  • ...Similar to the conventional node-based finite element method, the modeling domain can be discretized using rectangular, tetrahedron, hexahedron or other complex elements (Jin, 2002)....

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  • ...The tangential continuity of either electric or magnetic field is imposed automatically on the element's interfaces while the normal components are still can be discontinuous (Jin, 2002)....

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Mixed finite elements in ℝ 3

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Jean-Claude Nédélec1
École Polytechnique1
01 Sep 1980-Numerische Mathematik
TL;DR: In this article, the authors present two families of non-conforming finite elements, built on tetrahedrons or on cubes, which are respectively conforming in the spacesH(curl) and H(div).
Abstract: We present here some new families of non conforming finite elements in ?3. These two families of finite elements, built on tetrahedrons or on cubes are respectively conforming in the spacesH(curl) andH(div). We give some applications of these elements for the approximation of Maxwell's equations and equations of elasticity.

3,049 citations

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The finite element method in electromagnetics

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Magdalena Salazar-Palma1, Luis-Emilio García-Castillo1, Tapan K. Sarkar, Carretera de Valencia
Technical University of Madrid1
01 Jan 2000
TL;DR: In this article, a self-adaptive mesh scheme is presented in the context of the quasi-static and full-wave analysis of general anisotropic multiconductor arbitrary shaped waveguiding structures.
Abstract: This Key Note presents a summary of the development of the Finite Element Method in the field of Electromagnet ic Engineering, together with a description of several contributions of the authors to the Finite Element Method and its application to the solution of electromagnetic problems. First, a self-adaptive mesh scheme is presented in the context of the quasi-static and full-wave analysis of general anisotropic multiconductor arbitrary shaped waveguiding structures. A comparison between two a posteriori error estimates is done. The first one is based on the complete residual of the differential equations defining the problem. The second one is based on a recovery or smoothing technique of the electromagnetic field. Next, an implementation of the first family of Nedelec's curl-conforming elements done by the authors is outlined. Its features are highlighted and compared with other curl-conforming elements. A presentation of an iterative procedure using a numerically exact radiation condition for the analysis of open (scattering and radiation) problems follows. Other contributions of the authors, like the use of wavelet like basis functions and an implementation of a Time Domain Finite Element Method in the context of two-dimensional scattering problems are only mentioned due to the lack of space.

2,311 citations

"3D controlled-source electromagneti..." refers background or methods in this paper

  • ...…E N E E N E, , , (9) x e i xi e xi e y e i yi e yi e z e i zi e zi e 1 4 1 4 1 4 where the edge basis functions are defined by the following expressions (Jin, 2002): = + − + −N l l y l y z l z 1 2 2 , (10) x e y e z e c e y e c e z e 1 ⎛ ⎝ ⎜⎜ ⎞ ⎠ ⎟⎟ ⎛ ⎝ ⎜⎜ ⎞ ⎠ ⎟⎟ = − + + −N l l y y l z l z 1 2 2 ,…...

    [...]

  • ...The integrals in (27) and (28) can be calculated analytically for the rectangular elements (Jin, 2002)....

    [...]

  • ...The transformation can be described by the following formulas (Jin, 2002):...

    [...]

  • ...Following the work of Jin (2002) and Silva et al. (2012), we consider the homogeneous Dirichlet boundary conditions in the edge element formulation | =Ω∂e 0 (30) which holds approximately for the anomalous electric field at a distance from the domain with the anomalous conductivity....

    [...]

  • ...Similar to the conventional node-based finite element method, the modeling domain can be discretized using rectangular, tetrahedron, hexahedron or other complex elements (Jin, 2002)....

    [...]

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Frequently Asked Questions (2)
Q1. What have the authors contributed in "3d controlled-source electromagnetic modeling in anisotropic medium using edge-based finite element method" ?

This paper presents a linear edge-based finite element method for numerical modeling of 3D controlledsource electromagnetic data in an anisotropic conductive medium. The authors use a nonuniform rectangular mesh in order to capture the rapid change of diffusive electromagnetic field within the regions of anomalous conductivity and close to the location of the source. 

Future work will be aimed at the implementation of the high order finite elements and at the use of the unstructured tetrahedral and hexahedron meshes to include seafloor bathymetry and complex geoelectrical structures in the modeling of the MCSEM data.