Abstract
Training image (TI) has a great influence on reservoir modeling as a spatial correlation in the multipoint geostatistics. Unlike the variogram of the two-point geostatistics that is mathematically defined, there is a high degree of geological uncertainty to determine a proper TI. The goal of this study is to develop a classification model for determining the proper geological scenario among plausible TIs by using machine learning methods: (a) support vector machine (SVM), (b) artificial neural network (ANN), and (c) convolutional neural network (CNN). After simulated production data are used to train the classification model, the most possible TI can be selected when the observed production responses are put into the trained model. This study, as far as we know, is the first application of CNN in which production history data are composed as a matrix form for use as an input image. The training data are set to cover various production trends to make the machine learning models more reliable. Therefore, a total of 800 channelized reservoirs were generated from four TIs, which have different channel directions to consider geological uncertainty. We divided them into training, validation, and test sets of 576, 144, and 80, respectively. The input layer comprised 800 production data, i.e., oil production rates and water cuts for eight production wells over 50 time steps, and the output layer consisted of a probability vector for each TI. The SVM and CNN models reasonably reduced the uncertainty in modeling the facies distribution based on the reliable probability for each TI. Even though the ANN and CNN had roughly the same number of parameters, the CNN outperformed the ANN in terms of both validation and test sets. The CNN successfully classified the reference model’s TI with about 95% probability. This is because the CNN can grasp the overall trend of production history. The probabilities of TI from the SVM and CNN were applied to regenerate more reliable reservoir models using the concept of TI rejection and reduced the uncertainty in the geological scenario successfully.
Highlights
Reliable reservoir modeling is one of the most important tasks in the decision-making process in field development planning
Because the test score was increased by 30.77% compared to the artificial neural network (ANN)’s score in Figure 10(b) at the same epoch, the convolutional neural network (CNN) was more effective than the ANN to make stable and reliable Training image (TI) classification
Compared to the mean of the 800 initial models (Figure 14(a)), the regenerated models by the support vector machine (SVM) and CNN could significantly reduce the uncertainty in channel distribution by determining a proper TI based on the observed data
Summary
Reliable reservoir modeling is one of the most important tasks in the decision-making process in field development planning. Core and well logs are important for reservoir modeling as hard data, but they are only available by drilling which costs a lot. Understanding spatial correlations such as variograms and training images (TIs) is important to generate reservoir properties where drilling data in not available. Conventional geostatistical algorithms such as sequential Gaussian simulation and kriging identify spatial relationships using variograms. Variograms can only assess the relationship between two points even though there are other data available nearby [1]. Starting in the 1990s, multipoint geostatistics (MPS), which is about sets of three or more data points, has been developed [2, 3].
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