Abstract
Due to the rapid development of shale gas, a system has been established that can utilize a considerable amount of data using the database system. As a result, many studies using various machine learning techniques were carried out to predict the productivity of shale gas reservoirs. In this study, a comprehensive analysis is performed for a machine learning method based on data-driven approaches that evaluates productivity for shale gas wells by using various parameters such as hydraulic fracturing and well completion in Eagle Ford shale gas field. Two techniques are used to improve the performance of the productivity prediction machine learning model developed in this study. First, the optimal input variables were selected by using the variables importance method (VIM). Second, cluster analysis was used to analyze the similarities in the datasets and recreate the machine learning models for each cluster to compare the training and test results. To predict productivity, we used random forest (RF), gradient boosting tree (GBM), and support vector machine (SVM) supervised learning models. Compared to other supervised learning models, RF, which is applied with the VIM, has the best prediction performance. The retraining model through cluster analysis has excellent predictive performance. The developed model and prediction workflow are considered useful for reservoir engineers planning of field development plan.
Highlights
Since 2010, the multistage hydraulic fracturing for horizontal wells has been established as a method for producing shale gas and tight oil, especially in North America
We have developed the supervised learning model that predicts the cumulative production using a data-driven approach and machine learning modeling for Eagle Ford shale reservoirs
This study introduced a robust model and workflow of productivity prediction using machine learning for shale reservoirs at the early time stages of less than 6 months
Summary
Since 2010, the multistage hydraulic fracturing for horizontal wells has been established as a method for producing shale gas and tight oil, especially in North America. Future production profiles and estimated ultimate recovery (EUR) of shale gas wells are obtained by such methods as reservoir simulation [2], hydraulic fracturing modeling, rate transient analysis (RTA), and decline curve analysis (DCA). In case of RTA, data of flow pressure and reservoir property over time are necessary, and the end of transient linear flow can be accurately predicted only by deriving the stimulated reservoir volume (SRV) through microseismic (MS) analysis. In this way, the estimated ultimate recovery (EUR) can be calculated [8]
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