Application of Machine Learniing For Reservoir Facies Classification in Port Field, Offshore Niger Delta

Day 2 Tue, August 03, 2021 Pub Date : 2021-08-02 DOI:10.2118/207163-ms

J. Asedegbega, Oladayo Ayinde, A. Nwakanma

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引用次数: 1

Abstract

Several computer-aided techniques have been developed in recent past to improve interpretational accuracy of subsurface geology. This paradigm shift has provided tremendous success in variety of Machine Learning Application domains and help for better feasibility study in reservoir evaluation using multiple classification techniques. Facies classification is an essential subsurface exploration task as sedimentary facies reflect associated physical, chemical, and biological conditions that formation unit experienced during sedimentation activity. This study however, employed formation samples for facies classification using Machine Learning (ML) techniques and classified different facies from well logs in seven (7) wells of the PORT Field, Offshore Niger Delta. Six wells were concatenated during data preparation and trained using supervised ML algorithms before validating the models by blind testing on one well log to predict discrete facies groups. The analysis started with data preparation and examination where various features of the available well data were conditioned. For the model building and performance, support vector machine, random forest, decision tree, extra tree, neural network (multilayer preceptor), k-nearest neighbor and logistic regression model were built after dividing the data sets into training, test, and blind test well data. Results of metric score for the blind test well estimated for the various models using Jaccard index and F1-score indicated 0.73 and 0.82 for support vector machine, 0.38 and 0.54 for random forest, 0.78 and 0.83 for extra tree, 0.91 and 0.95 for k-nearest neighbor, 0.41 and 0.56 for decision tree, 0.63 and 0.74 for logistic regression, 0.55 and 0.68 for neural network, respectively. The efficiency of ML techniques for enhancing the prediction accuracy and decreasing the procedure time and their approach toward the data, makes it importantly desirable to recommend them in subsurface facies classification analysis.

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机器学习在尼日尔三角洲港口油田储层相分类中的应用

近年来发展了几种计算机辅助技术，以提高地下地质的解释精度。这种模式的转变在各种机器学习应用领域取得了巨大的成功，并有助于使用多种分类技术进行储层评价的可行性研究。相分类是一项重要的地下勘探任务，因为沉积相反映了地层单元在沉积活动期间所经历的相关物理、化学和生物条件。然而，该研究使用机器学习(ML)技术对地层样本进行相分类，并从尼日尔三角洲PORT油田的7口井的测井资料中对不同的相进行了分类。在数据准备过程中，将6口井连接起来，并使用监督ML算法进行训练，然后通过对一口井的盲测来验证模型，以预测离散相组。分析从数据准备和检查开始，其中对现有井数据的各种特征进行了条件反射。在模型构建和性能方面，将数据集分为训练井、测试井和盲测井数据，分别构建了支持向量机、随机森林、决策树、额外树、神经网络(多层感知器)、k近邻和逻辑回归模型。使用Jaccard指数和f1分数对各种模型进行盲测试的度量得分分别为:支持向量机0.73和0.82，随机森林0.38和0.54，额外树0.78和0.83,k-近邻0.91和0.95，决策树0.41和0.56，逻辑回归0.63和0.74，神经网络0.55和0.68。机器学习技术在提高预测精度和缩短程序时间方面的效率及其对数据的处理方法，使其在地下相分类分析中具有重要的可取性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Day 2 Tue, August 03, 2021

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