Deep Learning Enabled Deblurring of Computed Tomography Images of Porous Media

Khalid L. Alsamadony, E. U. Yildirim, G. Glatz, Umair Bin Waheed, Sherif M. Hanafy
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Abstract

Computed tomography (CT) is an important tool to characterize rock samples allowing quantification of physical properties in 3D and 4D. The accuracy of a property delineated from CT data is strongly correlated with the CT image quality. In general, high-quality, lower noise CT Images mandate greater exposure times. With increasing exposure time, however, more wear is put on the X-Ray tube and longer cooldown periods are required, inevitably limiting the temporal resolution of the particular phenomena under investigation. In this work, we propose a deep convolutional neural network (DCNN) based approach to improve the quality of images collected during reduced exposure time scans. First, we convolve long exposure time images from medical CT scanner with a blur kernel to mimic the degradation caused because of reduced exposure time scanning. Subsequently, utilizing the high- and low-quality scan stacks, we train a DCNN. The trained network enables us to restore any low-quality scan for which high-quality reference is not available. Furthermore, we investigate several factors affecting the DCNN performance such as the number of training images, transfer learning strategies, and loss functions. The results indicate that the number of training images is an important factor since the predictive capability of the DCNN improves as the number of training images increases. We illustrate, however, that the requirement for a large training dataset can be reduced by exploiting transfer learning. In addition, training the DCNN on mean squared error (MSE) as a loss function outperforms both mean absolute error (MAE) and Peak signal-to-noise ratio (PSNR) loss functions with respect to image quality metrics. The presented approach enables the prediction of high-quality images from low exposure CT images. Consequently, this allows for continued scanning without the need for X-Ray tube to cool down, thereby maximizing the temporal resolution. This is of particular value for any core flood experiment seeking to capture the underlying dynamics.
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深度学习实现多孔介质计算机断层图像去模糊
计算机断层扫描(CT)是表征岩石样品的重要工具,可以在3D和4D中量化岩石的物理性质。从CT数据中勾画出的属性的准确性与CT图像质量密切相关。一般来说,高质量、低噪声的CT图像需要更长的曝光时间。然而,随着曝光时间的增加,x射线管的磨损也越来越大,所需的冷却时间也越来越长,这不可避免地限制了所研究的特定现象的时间分辨率。在这项工作中,我们提出了一种基于深度卷积神经网络(DCNN)的方法来提高在减少曝光时间扫描期间收集的图像质量。首先,我们用模糊核卷积来自医学CT扫描仪的长曝光时间图像,以模拟由于减少曝光时间扫描而引起的退化。随后,利用高质量和低质量的扫描堆栈,我们训练了一个DCNN。经过训练的网络使我们能够恢复任何没有高质量参考的低质量扫描。此外,我们还研究了影响DCNN性能的几个因素,如训练图像的数量、迁移学习策略和损失函数。结果表明,训练图像的数量是一个重要的影响因素,因为随着训练图像数量的增加,DCNN的预测能力会提高。然而,我们说明了可以通过利用迁移学习来减少对大型训练数据集的需求。此外,在图像质量指标方面,用均方误差(MSE)作为损失函数训练DCNN优于平均绝对误差(MAE)和峰值信噪比(PSNR)损失函数。所提出的方法能够从低曝光CT图像中预测高质量的图像。因此,这允许在不需要x射线管冷却的情况下继续扫描,从而最大化时间分辨率。这对于任何试图捕捉潜在动态的岩心洪水实验都具有特别的价值。
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