Abstract
Deep learning techniques are increasingly being considered for geological applications where—much like in computer vision—the challenges are characterized by high-dimensional spatial data dominated by multipoint statistics. In particular, a novel technique called generative adversarial networks has been recently studied for geological parametrization and synthesis, obtaining very impressive results that are at least qualitatively competitive with previous methods. The method obtains a neural network parametrization of the geology—so-called a generator—that is capable of reproducing very complex geological patterns with dimensionality reduction of several orders of magnitude. Subsequent works have addressed the conditioning task, i.e., using the generator to generate realizations honoring spatial observations (hard data). The current approaches, however, do not provide a parametrization of the conditional generation process. In this work, we propose a method to obtain a parametrization for direct generation of conditional realizations. The main idea is to simply extend the existing generator network by stacking a second inference network that learns to perform the conditioning. This inference network is a neural network trained to sample a posterior distribution derived using a Bayesian formulation of the conditioning task. The resulting extended neural network thus provides the conditional parametrization. Our method is assessed on a benchmark image of binary channelized subsurface, obtaining very promising results for a wide variety of conditioning configurations.
Highlights
The large scale nature of geological models makes reservoir simulation an expensive task, prompting numerous works on parametrization methods that can preserve complex geological characteristics required for accurate flow modeling
Recent works show that using the Comput Geosci (2019) 23:925–952 generator to parametrize the geology is very effective in preserving high-order flow statistics [18, 22], two-point spatial statistics [16, 19], and morphology [16], all while achieving dimensionality reduction of several orders of magnitude
We introduced a method to obtain a conditional parametrization by extending an existing unconditional parametrization, enabling reusability as well as direct and parametric sampling of conditional realizations
Summary
The large scale nature of geological models makes reservoir simulation an expensive task, prompting numerous works on parametrization methods that can preserve complex geological characteristics required for accurate flow modeling. An alternative approach was presented in [19], where the authors addressed conditioning using a Bayesian framework and performed Markov chain Monte Carlo to sample conditional realizations. The main idea is to extend the existing generator network by stacking a second inference network that performs the conditioning This inference network is a neural network trained to sample a posterior distribution, derived using a Bayesian formulation of the conditioning task. Note that previous works [16, 19, 20] study applications of GAN mainly in the context of geomodeling and multipoint geostatistical simulations, here we emphasize on the effectiveness of GAN—and neural networks in general—for parametrization and dimensionality reduction, highlighting their ability to learn efficient representations for complex and high-dimensional data.
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