Carbonate Lithology Identification with Generative Adversarial Networks

Takashi Nanjo, S. Tanaka
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引用次数: 5

Abstract

Carbonate sedimentary rocks form the reservoir rocks of many oil and gas fields. The largest oil and gas fields in the world, such as the Ghawar field in Saudi Arabia and the Zakum field in Abu Dhabi, consist of carbonate reservoirs. Therefore, understanding the structure of carbonate sedimentary rocks is important to estimate the reservoir quality and distribution in the oil and gas field. However, carbonate sedimentary rocks have complex sedimentary structures that comprise various kinds of carbonate minerals. In addition, carbonate reservoirs often undergo diagenesis after deposition. Therefore, a detailed carbonate facies analysis requires great expertise. Additionally, traditional thin section analysis approaches such as the point counting method are extremely time intensive. In this context, machine learning, including deep learning, is attracting significant attention. In particular, image analysis using convolutional neural networks (CNNs) has seen dramatic development since the emergence of AlexNet in 2012. CNNs achieve superhuman image recognition capability by utilizing a deep layer structure that consists of a convolutional layer, activation function, etc. In the field of petroleum exploration and production, several studies on image analysis using CNNs have been performed by petroleum exploration and production companies and universities . Nanjo and Tanaka (in press) attempted carbonate lithology identification with pixel-wise segmentation in thin section images; the average accuracy of their category identification for each components [grain, cement, pore, and lime mud areas] was 83.9% and the automatic carbonate lithology identification based on the category identification was over 90%. They showed that machine learning is effective for carbonate lithology identification. However, the model is still not perfect with respect to both of category identification and automatic carbonate lithology identification. Generative Adversarial Networks (GAN) are unique and thought as useful tool to improve the model. GAN has already been studied in various fields (e.g., image generation and analysis). However, few studies have attempted to use GAN for carbonate lithology identification. In this study, the authors attempted to conduct carbonate lithology identification with a GAN and to review the potential of applying GAN for FMI imaging.
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基于生成对抗网络的碳酸盐岩岩性识别
碳酸盐岩沉积岩是许多油气田的储集岩。世界上最大的油气田,如沙特阿拉伯的Ghawar油田和阿布扎比的Zakum油田,都是由碳酸盐岩储层组成的。因此,了解碳酸盐岩沉积岩的构造对评价油气田储层质量和分布具有重要意义。碳酸盐沉积岩具有复杂的沉积构造,由多种碳酸盐矿物组成。此外,碳酸盐岩储层在沉积后经常发生成岩作用。因此,详细的碳酸盐相分析需要很高的专业知识。此外,传统的薄片分析方法,如点计数法,是非常耗时的。在这种背景下,机器学习,包括深度学习,正在引起人们的极大关注。特别是,自2012年AlexNet出现以来,使用卷积神经网络(cnn)的图像分析得到了巨大的发展。cnn利用由卷积层、激活函数等组成的深层结构实现了超人的图像识别能力。在石油勘探和生产领域,石油勘探和生产公司和大学已经进行了一些利用cnn进行图像分析的研究。Nanjo和Tanaka(已出版)尝试用薄片图像的逐像素分割来识别碳酸盐岩岩性;各组分[颗粒区、水泥区、孔隙区、灰泥区]分类识别的平均准确率为83.9%,基于分类识别的碳酸盐岩岩性自动识别准确率在90%以上。他们表明,机器学习对于碳酸盐岩性识别是有效的。然而,该模型在类别识别和碳酸盐岩岩性自动识别方面还不完善。生成对抗网络(GAN)是一种独特的、被认为是改进模型的有用工具。GAN已经在各个领域得到了研究(例如,图像生成和分析)。然而,很少有研究尝试使用氮化镓进行碳酸盐岩岩性识别。在这项研究中,作者试图用氮化镓进行碳酸盐岩性识别,并回顾了氮化镓在FMI成像中的应用潜力。
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