Towards stochastic interpretation of faulted structures using graph theory
in: 2016 RING Meeting, ASGA
Abstract
The interpretation of faults from geological and geophysical data is often challenging, due to
observation gaps and to the complexity of geophysical processes in fault zones. As a result, geological
interpretation of faulted structures may be ambiguous and under-constrained. Stochastic structural
modeling can sample structural uncertainties and may be used in multi-scenarios studies. However,
existing stochastic structural modeling methods either neglect some sources of uncertainty or only
consider very sparse or specific data types.
In this article, we propose a theoretical framework to stochastically interpret heterogeneous
data before the construction of a 3D subsurface model. The interpretations are represented by
two graphs: the first one gathers data belonging to the same geological structure (G correlation )
and is used to correlate fault observations. The second one (G branch ) details the contacts between
these structures. These graphs could be updated during stochastic simulations to generate several
interpretations while accounting for geometric and geologic rules.
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BibTeX Reference
@inproceedings{RUNKJRM44,
abstract = { The interpretation of faults from geological and geophysical data is often challenging, due to
observation gaps and to the complexity of geophysical processes in fault zones. As a result, geological
interpretation of faulted structures may be ambiguous and under-constrained. Stochastic structural
modeling can sample structural uncertainties and may be used in multi-scenarios studies. However,
existing stochastic structural modeling methods either neglect some sources of uncertainty or only
consider very sparse or specific data types.
In this article, we propose a theoretical framework to stochastically interpret heterogeneous
data before the construction of a 3D subsurface model. The interpretations are represented by
two graphs: the first one gathers data belonging to the same geological structure (G correlation )
and is used to correlate fault observations. The second one (G branch ) details the contacts between
these structures. These graphs could be updated during stochastic simulations to generate several
interpretations while accounting for geometric and geologic rules. },
author = { Godefroy, Gabriel AND Bonneau, Francois AND Caumon, Guillaume },
booktitle = { 2016 RING Meeting },
publisher = { ASGA },
title = { Towards stochastic interpretation of faulted structures using graph theory },
year = { 2016 }
}