A comprehensive study of including structural orientation information in geophysical inversions

Lelièvre, Peter G.; Oldenburg, Douglas W.

doi:10.1111/j.1365-246x.2009.04188.x

Cited by 89 publications

(38 citation statements)

References 16 publications

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“…Li and Oldenburg (2000) propose an inversion algorithm that allows geologic dip and strike information to be incorporated into inversions by rotating the local orthogonal coordinate system of smoothness operators for inversion. Lelièvre and Oldenburg (2009) extend this approach so that structural orientation information can be specified pointwise for the entire model domain. Lelièvre (2009) categorizes the geologic information as either located or nonlocated and develops new algorithms for incorporating into geophysical inversions useful geologic information such as physical property values, physical property trend information, and structural orientation information.…”

Section: Introductionmentioning

confidence: 99%

Multidomain petrophysically constrained inversion and geology differentiation using guided fuzzy c-means clustering

Sun

2015

GEOPHYSICS

120

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Geophysical inversion methods are used as part of an interpretation process that seeks to differentiate geologic units. To improve the reliability of geologic differentiation based on recovered images from geophysical inversions, we have developed a multidomain clustering inversion algorithm that can incorporate statistical petrophysical data into a deterministic geophysical inversion framework through the use of the fuzzy c-means clustering technique. Petrophysical data are treated in the parameter domain in the same way that geophysical data are treated in the spatial domain, and these two different types of data are simultaneously inverted in their respective domains through the minimization of a single common objective function. The resulting physical property model honors the geophysical and petrophysical data and therefore can represent the earth better than geophysical inversion models that solely honor the geophysical data. Geophysical inversion and geology differentiation are generally treated as two independent procedures and applied in a serial manner. In our inversion method, we integrate these two components into a unified scheme, within which they interact with each other and are mutually enhanced. We produce a geologic map showing the distribution of geologic units as a direct and integral part of the geophysical inversion. We tested the algorithm using two synthetic examples and a field data example.

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Section: Introductionmentioning

confidence: 99%

Multidomain petrophysically constrained inversion and geology differentiation using guided fuzzy c-means clustering

Sun

2015

GEOPHYSICS

120

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“…The idea of the image-guided inversion proposed by Ma et al (2012) and later by Zhou et al (2014) is to extract the structural information contained in the geologic cross section and to impose this structural information to the model covariance matrix in smoothing in preferential directions at different locations. This approach is, therefore, more general than the classical Tikhonov regularization in which an isotropic and spatially invariant smoothing is applied (or by applying the same smoothing in the vertical and horizontal directions for the entire tomogram; see the discussion in Lelièvre and Farquharson, 2013). We use a part-based representation approach (Lee and Seung, 1999) in which the structural information is neither completely stationary, as in Tikhonov regularization, nor completely nonstationary, as in the image-guided inversion (Zhou et al, 2014).…”

Section: Combining Petrophysical and Geologic Cross-section Informationmentioning

confidence: 98%

2D joint inversion of geophysical data using petrophysical clustering and facies deformation

Zhang

Revil

2015

GEOPHYSICS

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Geologic expertise and petrophysical relationships can be brought together to provide prior information while inverting multiple geophysical data sets. The merging of such information can result in more realistic solution in the distribution of the model parameters. We have evaluated the geophysical inverse problem in terms of Gaussian random fields with mean functions controlled by petrophysical relationships and covariance functions controlled by a prior geologic cross section, including the definition of spatial boundaries for the geologic facies. The petrophysical relationship problem is formulated as a regression problem upon each facies. The inversion of the geophysical data is performed in a Bayesian framework. We have developed the usefulness of this strategy using a first synthetic case for which we have performed a joint inversion of gravity and galvanometric resistivity data with the stations located at the ground surface. The joint inversion was used to recover the density and resistivity distributions of the subsurface. In a second step, we considered the possibility that the facies boundaries were deformable and their shapes were inverted as well. We used the level-set approach to perform such deformation preserving a priori topological properties of the facies throughout the inversion. With the help of a priori facies petrophysical relationships and the topological characteristics of each facies, we made a posteriori inference about multiple geophysical tomograms based on their corresponding geophysical data misfits. We have applied this method to a second synthetic case showing that we can recover the heterogeneities inside the facies, the mean values for the petrophysical properties, and, to some extent, the facies boundaries using the 2D joint inversion of gravity and galvanometric resistivity data.

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“…In a deterministic framework, Li and Oldenburg (2000) and Lelièvre and Oldenburg (2009) investigated options for incorporating structural orientation data into underdetermined inversions by minimization of an objective function. Barbosa and Silva (2006) introduced a technique in a user-friendly environment for helping forward modeling and testing geological hypotheses.…”

Section: Introductionmentioning

confidence: 99%

3D stochastic inversion of potential field data using structural geologic constraints

Shamsipour

Schetselaar

Bellefleur

et al. 2014

Journal of Applied Geophysics

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A comprehensive study of including structural orientation information in geophysical inversions

Cited by 89 publications

References 16 publications

Multidomain petrophysically constrained inversion and geology differentiation using guided fuzzy c-means clustering

Multidomain petrophysically constrained inversion and geology differentiation using guided fuzzy c-means clustering

2D joint inversion of geophysical data using petrophysical clustering and facies deformation

3D stochastic inversion of potential field data using structural geologic constraints

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