Abstract
This paper presents the results of a research project which investigated permeability prediction for the Precipice Sandstone of the Surat Basin. Machine learning techniques were used for permeability estimation based on multiple wireline logs. This information improves the prediction of CO2 injectivity in this formation. Well logs and core data were collected from 5 boreholes in the Surat Basin, where extensive core data and complete sets of conventional well logs exist for the Precipice Sandstone. Four different machine learning (ML) techniques, including Random Forest (RF), Artificial neural network (ANN), Gradient Boosting Regressor (GBR), and Support Vector Regressor (SVR), were independently trained with a wide range of hyper-parameters to ensure that not only is the best model selected, but also the right combination of model parameters is selected. Cross-validation for 20 different combinations of the seven available input logs was used for this study. Based on the performances in the validation and blind testing phases, the ANN with all seven logs used as input was found to give the best performance in predicting permeability for the Precipice Sandstone with the coefficient of determination (R2) of about 0.93 and 0.87 for the training and blind data sets respectively. Multi-regression analysis also appears to be a successful approach to calculate reservoir permeability for the Precipice Sandstone. Models with a complete set of well logs can generate reservoir permeability with R2 of more than 90%.
Highlights
The required data for this study is collected from 5 wells (Woleebee Creek GW4, West Wandoan 1, West Moonie 1, Trelinga 1, Kenya East GW7) where extensive core data and complete sets of well logs exist for the Precipice Sandstone
The Gradient Boosting Regressor (GBR) and Random Forest (RF) achieved the best performances in training compared to Artificial neural network (ANN) and Support Vector Regressor (SVR)
This study used machine learning (ML) methods and uncertainty analysis to provide a robust tool for permeability Sandstone using conventional well well logs. logs
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. The Early Jurassic Precipice Sandstone is the target reservoir for upscaled storage trials in the area. Despite this potential for CO2 storage, the need for better characterization of the storage site has been recommended [3]. The variation of porosity and permeability values and their ranges of uncertainties need to be realistically quantified for better prediction of CO2 injectivity by a reservoir model [3–6]. For these methods, permeability is one of the most important input parameters that need to be provided with the highest possible accuracy. Mohaghegh et al [11] reported three major approaches for permeability estimation, including theoretical, statistical, and soft computing methods. Machine learning is the subset of AI that deals with algorithms that allow machines to learn useful patterns from data [13,14]
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