Abstract
Interpretation of seismic structural traps for accurate hydrocarbon reservoirs characterization is a challenging task. Seismic interpreters learn to accurately delineate subsurface structures after going through a lengthy process of training and expertise-acquiring that is challenging and time-consuming. In this paper, we propose a novel semantic segmentation model for salt domes and faults identification in a real concurrent scenario using an improved encoder-decoder deep neural network that achieves high detection accuracy for both salt domes and faults. We also introduce transfer learning to alleviate the everlasting scarcity issue of labeled seismic data and develop a robust model whose performance is not affected by event similarities among various discontinuities in seismic data. In addition, we use residual blocks in our deep neural network to make it even more robust. To demonstrate the effectiveness of our model, extensive experiments were conducted through validation and testing on real-world seismic data from the publicly available Netherlands offshore F3 block, the LANDMASS, and the TGS datasets. Both qualitative and quantitative evaluations are provided to confirm the superior performance achieved by our deep learning based workflow under the challenging scenario of multiple events detection in subsurface surveys.
Highlights
I NTERPRETATION of seismic records is a crucial task for understanding and analyzing geological information about subsurface structures
We propose a new approach for seismic interpretation using a deconvolutional neural network (DCNN)
We introduced a novel semantic segmentation workflow for the simultaneous detection of salt domes and faults, using an improved UNet deep network
Summary
I NTERPRETATION of seismic records is a crucial task for understanding and analyzing geological information about subsurface structures. Seismic interpretation is a workflow that is traditionally undertaken within a collaborative work involving domain experts (i.e. geologists, geophysicists, geoscientists, etc) and is normally done interactively on robust interpretation workstations These workstations are sets of high-powered computers and software tools, meant to assist interpreters with storing, rendering, and analyzing seismic images. The main goal of seismic interpretation is to accurately identify geological structures from seismic surveys Such structures include salt domes, faults, unconformities, horizons, facies, and gas chimneys, to name a few. Even though our pre-trained networks have a lower F1-score: 0.7712 with the VGG19 network and 0.6817 with the ResNet network, our results were obtained on challenging field data. The authors in [35] used a small set of real seismic data to train a U-Net model on fault detection. Our pre-trained networks reached higher IoU with 0.6588 with VGG19, and 0.5419 with the ResNet network
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