通过迁移学习直接预测钻芯图像中的矿物含量

IF 1.8 2区 地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY Swiss Journal of Geosciences Pub Date : 2024-05-07 DOI:10.1186/s00015-024-00458-3
Romana Boiger, Sergey V. Churakov, Ignacio Ballester Llagaria, Georg Kosakowski, Raphael Wüst, Nikolaos I. Prasianakis
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引用次数: 0

摘要

深层地下勘探对于采矿、石油和天然气工业,以及评估用于处理化学或核废料的地质单元或地热能源系统的可行性都非常重要。通常情况下,对地下岩层或单元的详细检查是根据钻探活动中提取的岩屑或岩心材料以及地球物理钻孔数据进行的,这些数据提供了有关岩石岩石物理特性的详细信息。根据岩石样本量和分析程序的不同,实验室分析和诊断可能非常耗时。本研究探讨了利用机器学习,特别是卷积神经网络(CNN),仅通过分析钻芯图像来评估岩性和矿物含量的潜力,旨在支持和加快地下地质勘探。论文概述了一种综合方法,包括数据预处理、机器学习方法和迁移学习技术。研究结果表明,将钻芯片段划分为不同地层类别的准确率高达 96.7%。此外,利用来自多维测井分析数据(硅酸盐、粘土总量、碳酸盐)的学习数据集,为评估矿物含量训练了一个 CNN 模型。根据对岩心样本进行的实验室 XRD 测量结果进行比对,先进的多维测井分析模型和本文开发的神经网络方法都具有同样出色的性能。这项工作表明,深度学习,尤其是迁移学习,可以支持从钻孔岩心图像中提取岩石物理属性,包括矿物含量和地层分类,从而为在基于图像的钻孔岩心分析中提高模型性能和数据集质量提供了路线图。
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Direct mineral content prediction from drill core images via transfer learning
Deep subsurface exploration is important for mining, oil and gas industries, as well as in the assessment of geological units for the disposal of chemical or nuclear waste, or the viability of geothermal energy systems. Typically, detailed examinations of subsurface formations or units are performed on cuttings or core materials extracted during drilling campaigns, as well as on geophysical borehole data, which provide detailed information about the petrophysical properties of the rocks. Depending on the volume of rock samples and the analytical program, the laboratory analysis and diagnostics can be very time-consuming. This study investigates the potential of utilizing machine learning, specifically convolutional neural networks (CNN), to assess the lithology and mineral content solely from analysis of drill core images, aiming to support and expedite the subsurface geological exploration. The paper outlines a comprehensive methodology, encompassing data preprocessing, machine learning methods, and transfer learning techniques. The outcome reveals a remarkable 96.7% accuracy in the classification of drill core segments into distinct formation classes. Furthermore, a CNN model was trained for the evaluation of mineral content using a learning data set from multidimensional log analysis data (silicate, total clay, carbonate). When benchmarked against laboratory XRD measurements on samples from the cores, both the advanced multidimensional log analysis model and the neural network approach developed here provide equally good performance. This work demonstrates that deep learning and particularly transfer learning can support extracting petrophysical properties, including mineral content and formation classification, from drill core images, thus offering a road map for enhancing model performance and data set quality in image-based analysis of drill cores.
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来源期刊
Swiss Journal of Geosciences
Swiss Journal of Geosciences 地学-地质学
CiteScore
4.50
自引率
12.90%
发文量
21
审稿时长
>12 weeks
期刊介绍: The Swiss Journal of Geosciences publishes original research and review articles, with a particular focus on the evolution of the Tethys realm and the Alpine/Himalayan orogen. By consolidating the former Eclogae Geologicae Helvetiae and Swiss Bulletin of Mineralogy and Petrology, this international journal covers all disciplines of the solid Earth Sciences, including their practical applications. The journal gives preference to articles that are of wide interest to the international research community, while at the same time recognising the importance of documenting high-quality geoscientific data in a regional context, including the occasional publication of maps.
期刊最新文献
Facies variability and depositional cyclicity in central Northern Switzerland: insights from new Opalinus Clay drill cores Determination of a normal orogenic palaeo-geothermal gradient with clay mineral and organic matter indices: a review Unravelling the tectonic evolution of the Dinarides—Alps—Pannonian Basin transition zone: insights from structural analysis and low-temperature thermochronology from Ivanščica Mt., NW Croatia Special Issue: Evolution of collisional orogens in space and time—the Alpine-Himalayan system in 4 dimensions Ediacaran to Jurassic geodynamic evolution of the Alborz Mountains, north Iran: geochronological data from the Gasht Metamorphic Complex
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