3D geomodelling combining implicit surfaces and Voronoi-based remeshing: A case study in the Lorraine Coal Basin (France)

Collon, Pauline; Steckiewicz-Laurent, Wendy; Pellerin, Jeanne; Laurent, Gautier; Caumon, Guillaume; Reichart, Guillaume; Vaute, Laurent

doi:10.1016/j.cageo.2015.01.009

Cited by 53 publications

(22 citation statements)

References 23 publications

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“…They can be classified in two main strategies (Frank et al, 2007;Caumon et al, 2009;Collon et al, 2015): (1) the classical modeling approaches, also called explicit approaches, which consist of building surfacesgenerally triangulated surfacesthat fit available data; (2) and the more recent implicit approaches that consider geologic interfaces as isovalues of a 3D scalar field f ðx; y; zÞ. They can be classified in two main strategies (Frank et al, 2007;Caumon et al, 2009;Collon et al, 2015): (1) the classical modeling approaches, also called explicit approaches, which consist of building surfacesgenerally triangulated surfacesthat fit available data; (2) and the more recent implicit approaches that consider geologic interfaces as isovalues of a 3D scalar field f ðx; y; zÞ.…”

Section: Modeling Choicesmentioning

confidence: 99%

“…Its principle is to deform an initial surface to minimize the distance between the sur-face and the data points, by the mean of various interpolation methods (Haecker, 1992;Mallet, 1992;Caumon et al, 2009;Kaven et al, 2009;Collon et al, 2015). Its principle is to deform an initial surface to minimize the distance between the sur-face and the data points, by the mean of various interpolation methods (Haecker, 1992;Mallet, 1992;Caumon et al, 2009;Kaven et al, 2009;Collon et al, 2015).…”

Section: Explicit Approachmentioning

confidence: 99%

“…In such a case, implicit modeling methods have several advantages to coherently build stratigraphic series at once as compared with explicit methods Collon et al, 2015). The traces of the strata on the topography are, however, discontinuous due to vegetation and surface processes (erosion and scree).…”

Section: Modeling the Minibasin Stratigraphymentioning

confidence: 99%

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3D modeling from outcrop data in a salt tectonic context: Example from the Inceyol minibasin, Sivas Basin, Turkey

et al. 2016

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We have developed a 3D modeling strategy of the encased minibasin of Inceyol in Sivas (Turkey). The challenge lies in the combination of sparse outcrop data and the complex interpretive geometry of geologic structures that come from salt tectonics. We have succeeded in modeling the convoluted salt surface using an explicit indirect surface patch construction method followed by a manual mesh improvement. Then, we modeled the minibasin sediments with an implicit approach. The result highlighted the remarkable geometry of the convoluted salt horizon and its associated minibasin by extending in 3D the geologist's interpretive 2D sections. This case study proved that building complex geometries is feasible with the existing tools and a good expertise in the various geomodeling techniques. Our work also underlined the need for new methods to ease the modeling of such tectonic features from sparse data. We have developed a 3D view of the model thanks to WebGL technology, as well as downloadable data to constitute a reference case study.

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Section: Modeling Choicesmentioning

confidence: 99%

Section: Explicit Approachmentioning

confidence: 99%

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3D modeling from outcrop data in a salt tectonic context: Example from the Inceyol minibasin, Sivas Basin, Turkey

et al. 2016

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“…There is no a priori knowledge on the expected iso-values . The method approximates theses values during a pre-processing stage on input data which fixes the top and bottom horizons to a chosen value and then spatially interpolates the other horizons values linearly in between [20]. The data weights are generally taken constant between all data but can vary depending on the reliability of the data (e.g., borehole data are generally more reliable than seismic data).…”

Section: Data Points Equationsmentioning

confidence: 99%

Implicit Modelling of Geological Structures: A Cartesian Grid Method Handling Discontinuities With Ghost Points

Renaudeau

Irakarama

Laurent

et al. 2018

WIT Transactions on Engineering Sciences

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In geology, implicit structural modelling constructs the geometry of geological structures (e.g. layers) by interpolating between sparse field data. A model is represented by a volumetric scalar field which is discontinuous on structural discontinuities such as faults or stratigraphic unconformities. The management of such discontinuities may involve boolean operations on several scalar fields or the creation of conformal meshes. Instead, we propose a ghost cell technique for the cartesian grid together with a set of relations between the ghost points, the regular nodes, and the discontinuities. Consequently, poor quality meshes are avoided and only the resolution of the grid has an impact on the solution. The modelling problem is posed as a least square's minimization of a bending energy penalization on data mismatch functions and approximated by finite difference. As all relationships in the grid are implicitly defined, except close to the discontinuities, this algorithm is computationally efficient. We provide some benchmarks of the method on two-dimensional examples with folds, faults, and erosions.

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“…Deformation events are modeled successively by locally characterizing the relative orientation of their structural elements (Section 3). This modeling strategy is implemented in the framework of discrete implicit interpolation techniques , Collon-Drouaillet et al, 2015, Frank et al, 2007, Mallet, 2014 through a set of specific numerical constraints (Section 4). The principles of this modeling strategy are illustrated on various examples of increasing complexity (Section 5).…”

Section: Introductionmentioning

confidence: 99%

Implicit modeling of folds and overprinting deformation

Laurent

Aillères

Grose

et al. 2016

Earth and Planetary Science Letters

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International audienceThree-dimensional structural modeling is gaining importance for a broad range of quantitative geoscientific applications. However, existing approaches are still limited by the type of structural data they are able to use and by their lack of structural meaning. Most techniques heavily rely on spatial data for modeling folded layers, but are unable to completely use cleavage and lineation information for constraining the shape of modeled folds. This lack of structural control is generally compensated by expert knowledge introduced in the form of additional interpretive data such as cross-sections and maps. With this approach, folds are explicitly designed by the user instead of being derived from data. This makes the resulting structures subjective and deterministic. This paper introduces a numerical framework for modeling folds and associated foliations from typical field data. In this framework, a parametric description of fold geometry is incorporated into the interpolation algorithm. This way the folded geometry is implicitly derived from observed data, while being controlled through structural parameters such as fold wavelength, amplitude and tightness. A fold coordinate system is used to support the numerical description of fold geometry and to modify the behavior of classical structural interpolators. This fold frame is constructed from fold-related structural elements such as axial foliations, intersection lineations, and vergence. Poly-deformed terranes are progressively modeled by successively modeling each folding event going backward through time. The proposed framework introduces a new modeling paradigm, which enables the building of three-dimensional geological models of complex poly-deformed terranes. It follows a process based on the structural geologist approach and is able to produce geomodels that honor both structural data and geological knowledge

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3D geomodelling combining implicit surfaces and Voronoi-based remeshing: A case study in the Lorraine Coal Basin (France)

Cited by 53 publications

References 23 publications

3D modeling from outcrop data in a salt tectonic context: Example from the Inceyol minibasin, Sivas Basin, Turkey

3D modeling from outcrop data in a salt tectonic context: Example from the Inceyol minibasin, Sivas Basin, Turkey

Implicit Modelling of Geological Structures: A Cartesian Grid Method Handling Discontinuities With Ghost Points

Implicit modeling of folds and overprinting deformation

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