Prediction of Reservoir Quality from Log-Core and Seismic Inversion Analysis with an Artificial Neural Network: A Case Study from the Sawan Gas Field, Pakistan
Abstract
:1. Introduction
2. Materials and Methods
2.1. Reservoir Parameters Estimation
2.2. Support Vector Machine
- (a)
- Select a set of the appropriate seismic attribute after examineing the seismic and well log data at well locations.
- (b)
- Considering a logical relationship between suitable seismic attributes and the reservoir characters by linear or non-linear algorithms.
- (c)
- Train the data until maximizing the correlation coefficient between original and synthetic AI. If the correlation is high, then apply the selected parameters information to a seismic cube and generate a cube or volume of a specific reservoir property.
- (d)
- The AI model was developed to extract the petrophysical properties from seismic amplitude reflection. The results obtained from inversion was interpreted and cross-examined with other geological features to assess a prospect.
3. Results and Discussion
3.1. Reservoir Characterization from Logs and Core
3.1.1. Petrographic and SEM Image Analysis
3.1.2. NMR Investigation of the Cores and SEM Image Analysis
3.1.3. Facies Analysis and Modeling
3.2. Reservoir Characterization from Seismic Data
3.2.1. Seismic Inversion
3.2.2. Reservoir Character (Porosity) Estimation
3.2.3. Integrated Petrophysical Data Interpretation
4. Prediction of Reservoir Quality
5. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Acronyms
AI | Acoustic Impedance |
CAL | Caliper |
DTP | P-wave sonic |
DTS | S-wave sonic |
GIS | Gaussian Indicator Simulation |
GR | Gamma-Ray |
LLD | Deep Resistivity |
ML | Machine Learning |
NPHI | Neutron Porosity |
NMR | Nuclear Magnetic Resonance |
RBF | Radial Basis Function |
RHOB | Bulk Density |
SVM | Support Vector Machine |
SV | Support Vectors |
SGS | Sequential Gaussian Simulation |
SP | Spontaneous Potential |
Sat. HC | Hydrocarbon Saturation |
TCF | Trillion Cubic Feet |
MMscf | Millions Cubic Feet |
Ms | milli-second |
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Well ID | Production (MMscf) |
---|---|
Well-A | 12.779 |
Well-C | 24.428 |
Well-D | 13.760 |
Well-X | 04.703 |
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Qiang, Z.; Yasin, Q.; Golsanami, N.; Du, Q. Prediction of Reservoir Quality from Log-Core and Seismic Inversion Analysis with an Artificial Neural Network: A Case Study from the Sawan Gas Field, Pakistan. Energies 2020, 13, 486. https://doi.org/10.3390/en13020486
Qiang Z, Yasin Q, Golsanami N, Du Q. Prediction of Reservoir Quality from Log-Core and Seismic Inversion Analysis with an Artificial Neural Network: A Case Study from the Sawan Gas Field, Pakistan. Energies. 2020; 13(2):486. https://doi.org/10.3390/en13020486
Chicago/Turabian StyleQiang, Zhang, Qamar Yasin, Naser Golsanami, and Qizhen Du. 2020. "Prediction of Reservoir Quality from Log-Core and Seismic Inversion Analysis with an Artificial Neural Network: A Case Study from the Sawan Gas Field, Pakistan" Energies 13, no. 2: 486. https://doi.org/10.3390/en13020486
APA StyleQiang, Z., Yasin, Q., Golsanami, N., & Du, Q. (2020). Prediction of Reservoir Quality from Log-Core and Seismic Inversion Analysis with an Artificial Neural Network: A Case Study from the Sawan Gas Field, Pakistan. Energies, 13(2), 486. https://doi.org/10.3390/en13020486