Modelling of stochastic faults and fault networks in a structural uncertainty study

Lecour, Magali; Cognot, Richard; Duvinage, Isabelle; Thore, P.; Dulac, Jean‐Claude

doi:10.1144/petgeo.7.s.s31

Cited by 44 publications

(33 citation statements)

References 13 publications

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“…Caumon et al [4] use a set of techniques to model structural uncertainty by perturbing stochastically the geometry of a reference structural interpretation. This extends the work presented in Lecour et al [11] where stochastic modelling of fault locations in reservoir grids is used to perform sensitivity studies on volume calculations in the 3D earth model. Thore et al [19] underline the importance of assessing the sources of uncertainty in the structural modelling and show how this has impact on gross rock-volume calculations, well planning, flow simulation and history matching.…”

Section: Introductionsupporting

confidence: 64%

“…The joint effect from faults close to each other is taken care of by truncation rules applied on the fault operator defined from the displacement fields. Caumon et al [4], Lecour et al [11] and Holden et al [9] focus on stochastic perturbation of fault geometries and fault throw, but in a history matching workflow a deterministic way of perturbing the fault geometry and throw is desired. Effects of changing fault throw on reservoir flow can implicitly be represented by changing the throw used in the fault seal calculations as shown by Manzocchi et al [13], however, an explicit change of fault throw is needed for volume calculations and for well planning.…”

Section: Introductionmentioning

confidence: 99%

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Fault displacement modelling using 3D vector fields

et al. 2012

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In history matching and sensitivity analysis, flexibility in the structural modelling is of great importance. The ability to easily generate multiple realizations of the model will have impact both on the updating workflow in history matching and uncertainty studies based on Monte Carlo simulations. The main contribution to fault modelling by the work presented in this paper is a new algorithm for calculating a 3D displacement field applicable to a wide range of faults due to a flexible representation. This gives the possibility to apply this field to change the displacement and thereby moving horizons and fault lines. The fault is modelled by a parametric format where the fault has a reference plane defined by a centre point, dip and strike angles. The fault itself is represented as a surface defined by a function z = f (x, y), where x, y and z are coordinates local to the reference plane, with the z-axis being normal to the plane. The displacement associated with the fault outside the fault surface is described by a 3D vector field. The displacement on the fault surface can be found by identifying the intersection lines between horizons and the fault surface (fault lines), and using kriging techniques to fill in values at all points on the surface. Away from the fault surface the displacement field is defined by a monotonic decreasing function which ensures zero displacement at a specified distance from the fault. An algorithm is developed where the displacement can be increased or decreased according to user-defined parameters. This means that the whole displacement field is changed and points on horizons around the fault can be moved accordingly by applying the modified displacement field on them. The interaction between several faults influencing the same points is taken care of by truncation rules and the ordering of the faults. The method is demonstrated on a realistic synthetic case based on a real reservoir.

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Section: Introductionsupporting

confidence: 64%

Section: Introductionmentioning

confidence: 99%

Fault displacement modelling using 3D vector fields

et al. 2012

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“…The method is designed to perturb the position of horizons and faults from the "best" structural model obtained by expert's interpretation, accounting for uncertainties from different sources. Lecour et al [2] applied this method to complex fault network modeling, focusing only on the uncertainty resulting from interpretation. Similar applications are also found in Samson et al [3], Corre et al [4], Charles et al [5], and Holden et al [6].…”

Section: Introductionmentioning

confidence: 99%

Dynamic data integration for structural modeling: model screening approach using a distance-based model parameterization

2008

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This paper proposes a novel history-matching method where reservoir structure is inverted from dynamic fluid flow response. The proposed workflow consists of searching for models that match production history from a large set of prior structural model realizations. This prior set represents the reservoir structural uncertainty because of interpretation uncertainty on seismic sections. To make such a search effective, we introduce a parameter space defined with a "similarity distance" for accommodating this large set of realizations. The inverse solutions are found using a stochastic search method. Realistic reservoir examples are presented to prove the applicability of the proposed method.

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“…In explicit modeling, geological interfaces are represented as polygonal surfaces. Lecour et al [16] propose to modify the geometry of a surface by perturbing its nodes along an uncertainty bar defined at each node. The perturbation is correlated along the surface using the probability field method [17], in order to obtain realistic geometries.…”

Section: Explicit Geometrical Perturbation Techniques and Limitationsmentioning

confidence: 99%

“…For a whole model, each surface is perturbed according to its structural uncertainties and all connections (horizon to horizon, horizon to fault and fault to fault) are stored. Once all geological objects have been perturbed, connections are honored so that the topology is preserved [16]. In practice, this raises a number of challenges to maintain model consistency in the case of large uncertainties, for interferences between surfaces and large mesh distorsions may occur.…”

Section: Explicit Geometrical Perturbation Techniques and Limitationsmentioning

confidence: 99%

Stochastic simulations of fault networks in 3D structural modeling

Cherpeau

Caumon

Lévy

2010

Comptes Rendus. Géoscience

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Abstract3D Structural modeling is a major instrument in geosciences, e.g. for the assessment of groundwater and energy resources or nuclear waste underground storage. Fault network modeling is a particularly crucial step during this task, for faults compartmentalize rock units and play a key role in subsurface flow, whether faults are sealing barriers or drains.Whereas most structural uncertainty modeling techniques only allow for geometrical changes and keep the topology fixed, we propose a new method for creating realistic stochastic fault networks with different topologies. The idea is to combine an implicit representation of geological surfaces which provides new perspectives for handling topological changes with a stochastic binary tree to represent the spatial regions. Each node of the tree is a fault, separating the space in two fault blocks. Changes in this binary tree modify the fault relations and therefore the topology of the model. RésuméSimulations stochastiques de réseaux de failles en modélisation structurale 3D. La modélisation structurale est largement utilisée en géoscience, notamment pour l'évaluation des ressourcesénergétiques et hydriques du sous-sol. La caractérisation des failles est l'une desétapes clés du processus de modélisationétant donné leur importance dans lesécoulements de subsurface.Alors que la plupart des techniques de modélisation d'incertitudes structurales existantes perturbent seulement la géométrie des objets, nous proposons une nouvelle méthode de simulation stochastique de réseaux de failles, incluant des changements topologiques. Cette méthode associe une modélisation implicite des surfaces géologiques, avec un arbre binaire permettant d'agencer les régions spatiales du modèle. Chaque noeud de l'arbre représente une faille, séparant l'espace en deux blocs. Des changements dans l'arbre binaire modifient les relations entre failles et par conséquent la topologie du modèle.

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Modelling of stochastic faults and fault networks in a structural uncertainty study

Cited by 44 publications

References 13 publications

Fault displacement modelling using 3D vector fields

Fault displacement modelling using 3D vector fields

Dynamic data integration for structural modeling: model screening approach using a distance-based model parameterization

Stochastic simulations of fault networks in 3D structural modeling

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