Seis2Rock: A Data-Driven Approach to Direct Petrophysical Inversion of Pre-Stack Seismic Data
Corrales M.1, Hoteit H.1, Ravasi M.1
1 King Abdullah University of Science and Technology (KAUST)
This repository is organized as follows:
- 📂 assets: images and figures of the project.
- 📂 seis2rock: python library containing routines for seis2rock.
- 📂 data: folder containing data (and instructions on how to retrieve the data).
- 📂 notebooks: set of jupyter notebooks reproducing the experiments in the paper (see below for more details).
The following notebooks are provided:
- 📙
01_Synthetic_Benchmark.ipynb: The notebook assesses and benchmarks the method's applicability using a synthetic dataset that has been constructed based on the reservoir model of the Smeaheia Field. - 📙
02_Synthetic_4D_Benchmark.ipynb: The notebook aims to evaluate the feasibility of tracking changes in water saturation using well logs that lack information about the new water-oil contact in the subsurface. It seeks to simulate 4D changes in the subsurface. - 📙
03_Synthetic_Stacking_Wells.ipynb: This notebook compares the inversion results obtained by varying the number of well logs used for training.
The following notebooks are provided:
- 📘
01_Wavelet_Estimation_Well_NO_15_9_19_BT2.ipynb: This notebook demonstrates the procedure for extracting a statistical wavelet estimate along the Well NO 15-9 19 BT2 fence. This wavelet is subsequently utilized in the inversion step. - 📘
02_Wavelet_Estimation_Well_NO_15_9_19_A.ipynb: This notebook demonstrates the procedure for extracting a statistical wavelet estimate along the Well NO 15-9 19 A fence. This wavelet is subsequently utilized in the inversion step. - 📘
03_Benchmark_Inversion_Synthetic_Well_NO_15_9_19_BT2.ipynb: This notebook conducts a benchmark of the method using a synthetic gather constructed from the well log information of well NO 15-9 19 BT2. - 📘
04_Benchmark_Inversion_Synthetic_Well_NO_15_9_19_A.ipynb: This notebook conducts a benchmark of the method using a synthetic gather constructed from the well log information of well NO 15-9 19 A. - 📘
05_Inversion_Well_NO_15_9_19_BT2.ipynb: This notebook presents the inversion results obtained just on the well 15-9 19 BT2.. - 📘
06_Inversion_Well_NO_15_9_19_A.ipynb: This notebook presents the inversion results obtained just on well NO 15-9 19 A. - 📘
07_Inversion_Fence_Well_NO_15_9_19_BT2.ipynb: This notebook presents the inversion results obtained along the 2D fence of well NO 15-9 19 BT2. - 📘
08_Inversion_Fence_Well_NO_15_9_19_A.ipynb: This notebook presents the inversion results obtained along the 2D fence of well NO 15-9 19 A. - 📘
09_Inversion_Fence_Well_NO_15_9_19_BT2_stacking_wells.ipynb: This notebook presents the inversion results obtained along the 2D fence using the well logs from NO 15-9 19 BT2 and NO 15-9 19 A for the training. - 📘
10_Inversion_Fence_Well_NO_15_9_19_A_stacking_wells.ipynb: This notebook presents the inversion results obtained along the 2D fence using the well logs from NO 15-9 19 BT2 and NO 15-9 19 A for the training. - 📘
11_Inversion_3D.ipynb: This notebook presents the inversion in 3D.
To ensure reproducibility of the results, we suggest using the environment.yml file when creating an environment.
Simply run:
./install_env.sh
It will take some time, if at the end you see the word Done! on your terminal you are ready to go. Αctivate the environment by typing:
conda activate seis2rock
After that you can simply install your package: (double check your new environment is active to proceed as follows)
pip install .
or in developer mode:
pip install -e .
Note
All experiments have been carried on a Intel(R) Xeon(R) W-2245 CPU @ 3.90GHz equipped with a single NVIDIA Quadro RTX 4000 GPU. Different environment configurations may be required for different combinations of workstation and GPU.