Finite Difference Implicit Structural Modeling of Geological Structures

Irakarama, Modeste; Laurent, Gautier; Renaudeau, Julien; Caumon, Guillaume

doi:10.1007/s11004-020-09887-w

Cited by 21 publications

(11 citation statements)

References 39 publications

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“…This problem is similar to implicit surface reconstruction techniques [13], but it very often represents several non-intersecting horizons with one single scalar field, and it additionally needs to consider multiple discontinuities (faults) within the modeling domain. Implicit structural modeling has traditionally been separated into two main classes [7,1]: (1) mesh-free methods [2,3,14,6,15,16,17,18] , and (2) mesh-based methods [4,19,5,7,8,20,21,22]. We also acknowledge an increasing interest in methods based on machine learning [23].…”

Section: Introductionmentioning

confidence: 99%

“…Minimization of curvature is achieved by imposing Equation 3 where the matrix R is assembled by discretizing one of the regularization operators above. Following [20,22], we consider the function ϕ(x) to have zero curvature at the point x if, by definition, the second directional derivative ∂ 2 k ϕ(x) (and hence the curvature) along all directions d k vanishes at that point. In particular, given the Hessian matrix…”

Section: Introductionmentioning

confidence: 99%

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Finite Element Implicit 3D Subsurface Structural Modeling

Irakarama

Thierry-Coudon

Zakari

et al. 2022

Computer-Aided Design

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Finite Element Implicit 3D Subsurface Structural Modeling

Irakarama

Thierry-Coudon

Zakari

et al. 2022

Computer-Aided Design

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“…An accurate RGT volume is thus helpful to well understand geologic structures of interest and qualify reservoir properties of continuity and morphology to interpret all associated geologic structures, and to build a subsurface model of a particular environment. It has shown great promise in many applications to improve horizon extraction (Stark, 2004; Fomel, 2010; X. Wu & Zhong, 2012), sedimentologic interpretation (Hongliu et al., 2012), stratigraphic interpretation (Alliez et al., 2007; Karimi & Fomel, 2015; Lacaze et al., 2017), geologic body detection (Prazuck et al., 2015), and structural implicit modeling (Grose et al., 2017; Irakarama et al., 2020; Laurent et al., 2016; Renaudeau et al., 2019).…”

Section: Introductionmentioning

confidence: 99%

“…It has shown great promise in many applications to improve horizon extraction (Stark, 2004;Fomel, 2010;X. Wu & Zhong, 2012), sedimentologic interpretation (Hongliu et al, 2012), stratigraphic interpretation (Alliez et al, 2007;Lacaze et al, 2017), geologic body detection (Prazuck et al, 2015), and structural implicit modeling (Grose et al, 2017;Irakarama et al, 2020;Laurent et al, 2016;Renaudeau et al, 2019).…”

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confidence: 99%

Deep Relative Geologic Time: A Deep Learning Method for Simultaneously Interpreting 3‐D Seismic Horizons and Faults

Geng

et al. 2021

JGR Solid Earth

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Extracting horizons and detecting faults in a seismic image are basic steps for structural interpretation and important for many seismic processing schemes. A common ground of the two tasks is to analyze seismic structures and they are related to each other. However, previously proposed methods deal with the tasks independently, and challenge remains in each of them. We propose a volume‐to‐volume neural network to estimate a relative geologic time (RGT) volume from a seismic volume, and this RGT volume is further used to simultaneously interpret horizons and faults. The network uses U‐shaped framework with attention mechanism to systematically aggregate multi‐scale information and automatically highlight informative features, and achieves high prediction accuracy with affordable computational costs. To train the network, we build thousands of 3‐D noisy synthetic seismic volumes and corresponding RGT volumes with realistic and various structures. We introduce a loss function based on structure similarity to capture spatial dependencies among seismic samples for better optimizing the network, and use multiple reasonable assessments to evaluate the predicted results. Trained by using synthetic data, our network outperforms the conventional approaches in recognizing structural features in field data examples. Once obtaining an RGT volume, we can not only obtain seismic horizons by simply extracting RGT constant surfaces but also detect faults that are indicated by lateral RGT discontinuities. To be able to deal with large seismic volumes, we further propose a workflow to first estimate sub‐volumes of RGT and merge them to obtain a full RGT volume without boundary artifacts.

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“…This challenge exists because many of the observations and structural geology rules are not directly integrated into the mathematical description of the geological models. Structural geologists typically use their knowledge and expertise to formulate a working hypothesis in a digital format, which often derives from a biased conceptual mental picture (Jessell et al, 2014). The modelled geometries will always converge towards the geologist's bias and conceptual model, meaning that model building cannot be used to test different geological hypotheses.…”

Section: Introductionmentioning

confidence: 99%

Modelling of faults in LoopStructural 1.0

et al. 2021

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Abstract. Without properly accounting for both fault kinematics and observations of a faulted surface, it is challenging to create 3D geological models of faulted geological units. Geometries where multiple faults interact, where the faulted surface geometry significantly deviate from a flat plane and where the geological interfaces are poorly characterised by sparse datasets are particular challenges. There are two existing approaches for incorporating faults into geological surface modelling. One approach incorporates the fault displacement into the surface description but does not incorporate fault kinematics and in most cases will produce geologically unexpected results such as shrinking intrusions, fold hinges without offset and layer thickness growth in flat oblique faults. The second approach builds a continuous surface without faulting and then applies a kinematic fault operator to the continuous surface to create the displacement. Both approaches have their strengths; however, neither approach can capture the interaction of faults within complicated fault networks, e.g. fault duplexes, flower structures and listric faults because they either (1) impose an incorrect (not defined by data) fault slip direction or (2) require an over-sampled dataset that describes the faulted surface location. In this study, we integrate the fault kinematics into the implicit surface, by using the fault kinematics to restore observations, and the model domain prior to interpolating the faulted surface. This new approach can build models that are consistent with observations of the faulted surface and fault kinematics. Integrating fault kinematics directly into the implicit surface description allows for complexly faulted stratigraphy and fault–fault interactions to be modelled. Our approach shows significant improvement in capturing faulted surface geometries, especially where the intersection angle between the faulted surface and the fault surface varies (e.g. intrusions, fold series) and when modelling interacting faults (fault duplex).

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Finite Difference Implicit Structural Modeling of Geological Structures

Cited by 21 publications

References 39 publications

Finite Element Implicit 3D Subsurface Structural Modeling

Finite Element Implicit 3D Subsurface Structural Modeling

Deep Relative Geologic Time: A Deep Learning Method for Simultaneously Interpreting 3‐D Seismic Horizons and Faults

Modelling of faults in LoopStructural 1.0

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