Deep-learning-based workflow for boundary and small target segmentation in digital rock images using UNet++ and IK-EBM

Hongsheng Wang, Laura Dalton, Ming Fan, Ruichang Guo, James McClure, Dustin Crandall, Cheng Chen

Research output: Contribution to journalArticlepeer-review

32 Scopus citations

Abstract

Three-dimensional (3D) X-ray micro-computed tomography (μCT) has been widely used in petroleum engineering because it can provide detailed pore structural information for a reservoir rock, which can be imported into a pore-scale numerical model to simulate the transport and distribution of multiple fluids in the pore space. The partial volume blurring (PVB) problem is a major challenge in segmenting raw μCT images of rock samples, which impacts boundaries and small targets near the resolution limit. We developed a deep-learning (DL)-based workflow for accurate and fast partial volume segmentation. The DL model's performance depends primarily on the training data quality and model architecture. This study employed the entropy-based-masking indicator kriging (IK-EBM) to segment 3D Berea sandstone images as training datasets. The comparison between IK-EBM and manual segmentation using a 3D synthetic sphere pack, which had a known ground truth, showed that IK-EBM had higher accuracy on partial volume segmentation. We then trained and tested the UNet++ model, a state-of-the-art supervised encoder-decoder model, for binary (i.e., void and solid) and four-class segmentation. We compared the UNet++ with the commonly used U-Net and wide U-Net models and showed that the UNet++ had the best performance in terms of pixel-wise and physics-based evaluation metrics. Specifically, boundary-scaled accuracy demonstrated that the UNet++ architecture outperformed the regular U-Net architecture in the segmentation of pixels near boundaries and small targets, which were subjected to the PVB effect. Feature map visualization illustrated that the UNet++ bridged the semantic gaps between the feature maps extracted at different depths of the network, thereby enabling faster convergence and more accurate extraction of fine-scale features. The developed workflow significantly enhances the performance of supervised encoder-decoder models in partial volume segmentation, which has extensive applications in fundamental studies of subsurface energy, water, and environmental systems.

Original languageEnglish
Article number110596
JournalJournal of Petroleum Science and Engineering
Volume215
DOIs
StatePublished - Aug 2022

Funding

The authors are thankful for the financial support provided by the University Coalition for Fossil Energy Research (UCFER) Program under the U.S. Department of Energy's National Energy Technology Laboratory through the Award Number DE-FE0026825 and Subaward Number S000038-USDOE .

FundersFunder number
University Coalition for Fossil Energy Research
U.S. Department of Energy
National Energy Technology LaboratoryDE-FE0026825

    Keywords

    • Boundary and small targets
    • Digital rock physics
    • IK-EBM
    • Image segmentation
    • Partial volume blurring
    • Supervised deep learning
    • UNet++

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