Abstract
Accurate prediction of formation permeability plays a crucial role in reservoir characterization, well planning, production forecasting, reservoir management, and risk mitigation. Traditional methods including core analysis, well testing, and well logging can be used to estimate the reservoir permeability. However, these methods are time-consuming and expensive, making them impractical for comprehensive reservoir evaluation. This study aims to apply different machine learning tools to predict the formation permeability in a real-time using readily available drilling parameters. The dataset used in this study was gathered from two vertical wells located in the Middle East. It encompasses a variety of drilling parameters such as rate of penetration (ROP), gallons per minute (GPM), revolutions per minute (RPM), strokes per minute (SPP), torque, and weight on bit (WOB). Alongside these parameters, permeability (k) was obtained through core analysis. To predict the formation permeability, three machine learning models were employed: gradient boosting regressors (GBRs), artificial neural networks (ANNs), and function networks (FNs). These models were utilized and assessed to determine their efficacy in estimating the formation permeability from the drilling parameters. Furthermore, an empirical correlation was developed based on the optimized weights and biases derived from the ANN model. Preliminary results showed that the different ML models slightly struggled for direct permeability prediction from the drilling parameters. Adding an intermediate step of predicting the porosity from the drilling parameters and then using the estimated porosity in addition to the drilling parameters improved the permeability prediction. The ANN model showed a superior performance with correlation coefficient (R) value higher than 0.95 and root mean square error (RMSE) less than 0.28 in the different datasets. Similarly, the FN model was able to predict the permeability with R value higher than 0.94 and RMSE less than 0.38 in the different datasets. The GBR model slightly struggled in permeability prediction as the R value decreased to 0.89 in the testing and validation datasets. Accurate prediction of formation permeability enables operators to make informed decisions, enhance hydrocarbon recovery, and optimize overall field development strategies.
Original language | English |
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Article number | 015113 |
Journal | Arabian Journal for Science and Engineering |
DOIs | |
State | Accepted/In press - 2024 |
Bibliographical note
Publisher Copyright:© King Fahd University of Petroleum & Minerals 2024.
Keywords
- Drilling parameters
- Formation permeability
- Machine learning
- Real-time
ASJC Scopus subject areas
- General