A workflow to facilitate three-dimensional geometrical modelling of complex poly-deformed geological units

Maxelon, Michael; Renard, Philippe; Courrioux, Gabriel; Brändli, Martin; Mancktelow, Neil S.

doi:10.1016/j.cageo.2008.06.005

Cited by 56 publications

(42 citation statements)

References 29 publications

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“…(4) Many geological implicit surface modelling methods allow the user to incorporate structural anisotropy, the spa- Fig. 1 Structural constraint types used for implicit surface modelling in sparse data environments tial characteristic of a geological surface to exhibit a preferred direction of continuity, into the interpolation (Maxelon et al 2009;Massiot and Caumon 2010). However, none of the existing methods model anisotropy by computing orientation matrices (Sect.…”

Section: Introductionmentioning

confidence: 99%

Three-Dimensional Modelling of Geological Surfaces Using Generalized Interpolation with Radial Basis Functions

et al. 2014

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A generalized interpolation framework using radial basis functions (RBF) is presented that implicitly models three-dimensional continuous geological surfaces from scattered multivariate structural data. Generalized interpolants can use multiple types of independent geological constraints by deriving for each, linearly independent functionals. This framework does not suffer from the limitations of previous RBF approaches developed for geological surface modelling that requires additional offset points to ensure uniqueness of the interpolant. A particularly useful application of generalized interpolants is that they allow augmenting on-contact constraints with gradient constraints as defined by strike-dip data with assigned polarity. This interpolation problem yields a linear system that is analogous in form to the previously developed potential field implicit interpolation method based on co-kriging of contact increments using parametric isotropic covariance functions. The general form of the mathematical framework presented herein allows us to further expand on solutions by: (1) including stratigraphic data from above and below the target surface as inequality constraints (2) modelling anisotropy by data-driven eigen analysis of gradient constraints and (3) incorporating additional constraints by adding linear functionals to the system, such as fold axis constraints. Case studies are presented that demonstrate the advantages and general performance of the surface modelling method in sparse data environments where the contacts that constrain geological surfaces are rarely exposed but structural and off-contact stratigraphic data can be plentiful. Electronic supplementary materialThe online version of this article (

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Section: Introductionmentioning

confidence: 99%

Three-Dimensional Modelling of Geological Surfaces Using Generalized Interpolation with Radial Basis Functions

et al. 2014

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“…The support member can be built by the actual size through the function of Revit. The 3D geological model and support model can be integrated to form a complete 3D visualization space using different modeling methods to solve the practical problems (Maxelon et al, 2009).…”

Section: Application Of Bim Technology In Geotechnical Engineeringmentioning

confidence: 99%

The development mechanism and control technology visualization of the vault cracks in the ancient underground cavern of Longyou

et al. 2019

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“…3D structural modeling techniques are essentially data-driven processes honoring spatial observations [Jessell et al, 2014]. In most cases, these techniques rely on expert knowledge for overcoming the sparsity and uncertainty of available observations [Maxelon et al, 2009]. Structural geology concepts are generally incorporated in the process through interpretive elements in the form of maps, cross-sections or control points [Caumon et al, 2009].…”

Section: Introductionmentioning

confidence: 99%

“…Moreover, structural modeling techniques are generally limited to stratigraphic contact location and bedding orientation [Calgagno et al, 2008. Some types of structural data are often ignored [Maxelon et al, 2009, Jessell et al, 2010, 2014, and part of the knowledge collected in the field is actually lost in the process of creating a geological model. A significant challenge is to formalize conceptual information and combine these with all observations.…”

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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A workflow to facilitate three-dimensional geometrical modelling of complex poly-deformed geological units

Cited by 56 publications

References 29 publications

Three-Dimensional Modelling of Geological Surfaces Using Generalized Interpolation with Radial Basis Functions

Three-Dimensional Modelling of Geological Surfaces Using Generalized Interpolation with Radial Basis Functions

The development mechanism and control technology visualization of the vault cracks in the ancient underground cavern of Longyou

Implicit modeling of folds and overprinting deformation

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