Abstract
X-ray computerized tomography (CT) images as digital representations of whole cores can provide valuable information on the composition and internal structure of cores extracted from wells. Incorporation of millimeter-scale core CT data into lithology classification workflows can result in high-resolution lithology description. In this study, we use 2D core CT scan image slices to train a convolutional neural network (CNN) whose purpose is to automatically predict the lithology of a well on the Norwegian continental shelf. The images are preprocessed prior to training, i.e., undesired artefacts are automatically flagged and removed from further analysis. The training data include expert-derived lithofacies classes obtained by manual core description. The trained classifier is used to predict lithofacies on a set of test images that are unseen by the classifier. The prediction results reveal that distinct classes are predicted with high recall (up to 92%). However, there are misclassification rates associated with similarities in gray-scale values and transport properties. To postprocess the acquired results, we identified and merged similar lithofacies classes through ad hoc analysis considering the degree of confusion from the prediction confusion matrix and aided by porosity–permeability cross-plot relationships. Based on this analysis, the lithofacies classes are merged into four rock classes. Another CNN classifier trained on the resulting rock classes generalize well, with higher pixel-wise precision when detecting thin layers and bed boundaries compared to the manual core description. Thus, the classifier provides additional and complementing information to the already existing rock type description.Article HighlightsA workflow for automatic lithofacies classification using whole core 2D image slices and CNN is introduced.The proposed classifier shows lithology-dependent accuracies.The prediction confusion matrix is exploited as a tool to identify lithofacies classes with similar transport properties and to automatically generate lithofacies hierarchies.
Highlights
Classifying lithofacies is an essential step toward characterizing reservoirs and better understanding their depositional environments
The corresponding prediction accuracy metrics and confusion matrix calculated by cross-classifying the lithofacies classes from core description and convolutional neural network (CNN) prediction are summarized in Table 3 and Fig. 9
The capability of CNN to classify lithology, based on the 2D whole core computerized tomography (CT) image slices, was investigated, and its performance was characterized in detail
Summary
Classifying lithofacies is an essential step toward characterizing reservoirs and better understanding their depositional environments. To predict reservoirs’ saturation levels, and to perform subsequent effective reservoir modeling, it is crucial to correctly assess lithological properties such as grain size, grain shape, sorting and cementation. These lithological properties affect the petrophysical and transport properties of the reservoir rocks (e.g., porosity and permeability). The whole cores extracted from wellbores are described through direct visual inspections by a team of geologists and/or petrophysicists. This process is time-consuming and the resulting facies classification can be affected by subjective interpretation
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