Conceptual integration of seismic attributes and well log data for pore pressure prediction
1 Schlumberger (SLB), Port Harcourt, Nigeria and Mexico.
2 Shell, Nigeria.
3 Independent Researcher, USA.
4 Independent Researcher, Houston Texas, USA.
Review Article
Global Journal of Engineering and Technology Advances, 2024, 20(01), 118–130.
Article DOI: 10.30574/gjeta.2024.20.1.0125
Publication history:
Received on 09 June 2024; revised on 16 July 2024; accepted on 19 July 2024
Abstract:
Accurate pore pressure prediction is critical for safe and efficient hydrocarbon exploration and production, particularly in complex geological settings. Traditional methods often fall short due to the inherent uncertainties and limitations in heterogeneous formations. This paper explores the conceptual integration of seismic attributes and well log data to enhance pore pressure prediction accuracy using advanced machine learning techniques. Seismic attributes provide valuable information on subsurface properties, while well log data offer high-resolution insights into geological formations. Integrating these data sources leverages their complementary strengths, facilitating a more holistic understanding of subsurface conditions. The fusion of seismic and well log data, supported by machine learning algorithms, can significantly improve the prediction of pore pressure, thereby enhancing drilling safety and operational efficiency. The integration process begins with the extraction and preprocessing of relevant seismic attributes and well log parameters. Key seismic attributes such as amplitude, frequency, and phase are correlated with well log data, including porosity, permeability, and lithology. Machine learning models, including neural networks, support vector machines, and ensemble learning techniques, are trained to recognize patterns and relationships between these attributes and pore pressure measurements. This approach addresses several challenges inherent in traditional methods. It allows for the handling of nonlinear and multidimensional data, adaptive learning from new datasets, and real-time integration of diverse data types. The resulting models can identify subtle geological features and trends, which are crucial for accurate pore pressure prediction in complex environments like deep-water and tectonically active regions. Case studies demonstrate the effectiveness of this integrated approach, showing significant improvements in pore pressure prediction accuracy and reliability. These improvements lead to better wellbore stability, reduced risk of blowouts, and optimized drilling plans, ultimately enhancing hydrocarbon recovery and productivity. In conclusion, the conceptual integration of seismic attributes and well log data, underpinned by machine learning techniques, represents a promising advancement in pore pressure prediction. This integrated approach not only mitigates the limitations of traditional methods but also opens new avenues for research and application in geosciences, driving safer and more efficient exploration and production practices in the oil and gas industry.
Keywords:
Conceptual Integration; Seismic Attributes; Well Log Data; Pore Pressure; Prediction
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