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引用次数: 0
摘要
本研究利用三口井的常规地球物理测井记录,采用机器学习技术改进印度博卡罗煤田巴拉卡地层的岩相分类。我们使用 k-近邻(kNN)、支持向量机(SVM)和随机森林(RF)分类器分析了天然伽马射线、真电阻率、体积密度、中子孔隙度和光电因子数据。一口母井提供了页岩、砂岩、碳质页岩和煤等典型岩性的初始参考测井测量截止值,为我们的训练数据集奠定了基础。我们使用精确度、召回率和 F1 分数指标评估模型的准确性,发现随机森林模型在岩性类型判别方面最为有效。在训练阶段,计算得出的 ML 模式预测总体准确率超过 89%,模型准确率等级为 RF>SVM>kNN。这些分类器随后被应用于其他井位的岩性序列预测,有助于岩性序列识别和潜在断层延伸检测。这项研究证明,随机森林模型在岩性识别方面具有更高的精度和效率。我们的研究结果增强了在油井相关过程中识别缺失岩性的自动化流程,为资源勘探和开发中的地质解释提供了宝贵的见解。这种机器学习驱动的方法标志着地下地质研究的重大进展。
Machine learning assisted model based petrographic classification: a case study from Bokaro coal field
This study applies machine learning techniques to improve petrographic classification in India's Bokaro coalfield's Barakar Formation, using conventional geophysical well logs from three wells. We analysed natural gamma ray, true resistivity, bulk density, neutron porosity, and photoelectric factor data using k-nearest neighbor (kNN), support vector machine (SVM) and random forest (RF) classifiers. A master well provided initial reference log measurement cut-off values for typical lithologies like shale, sandstone, carbonaceous shale, and coal, forming the basis of our training dataset. We assessed model accuracy using precision, recall, and F1-score metrics, finding the random forest model to be the most effective in litho-type discrimination. During the training phase, the computed overall accuracy of the predicted ML modes exceeded 89% and model accuracy hierarchy was RF>SVM>kNN. These classifiers were then applied to other well locations to predict lithological sequences, aiding in lithofacies sequence identification and potential fault extension detection. The study demonstrates the random forest model's superior precision and efficiency in lithological discrimination. Our findings enhance automated processes for identifying missing lithology during well correlation, offering valuable insights for geological interpretation in resource exploration and development. This machine learning-driven approach marks a significant advancement in subsurface geological studies.
期刊介绍:
The journal publishes original research papers in the field of geodesy and geophysics under headings: aeronomy and space physics, electromagnetic studies, geodesy and gravimetry, geodynamics, geomathematics, rock physics, seismology, solid earth physics, history. Papers dealing with problems of the Carpathian region and its surroundings are preferred. Similarly, papers on topics traditionally covered by Hungarian geodesists and geophysicists (e.g. robust estimations, geoid, EM properties of the Earth’s crust, geomagnetic pulsations and seismological risk) are especially welcome.