An Artificial Intelligence Approach to Predict the Water Saturation in Carbonate Reservoir Rocks

Day 2 Tue, October 01, 2019 Pub Date : 2019-09-23 DOI:10.2118/195804-ms

Zeeshan Tariq, M. Mahmoud, A. Abdulraheem

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引用次数: 8

Abstract

Carbonate rocks have a very complex pore system due to the presence of interparticle and intra-particle porosities. This makes the acquisition and analysis of the petrophysical data, and the characterization of carbonate rocks a big challenge. In this study, functional network tool is used to develop a model to predict water saturation using petrophysical well logs as input data and the dean-stark measured water saturation as an output parameter. The data comprised of more than 200 well log points corresponding to available core data. The developed FN model was optimized by using several optimization algorithms such as differential evolution (DE), particle swarm optimization (PSO), and covariance matrix adaptation evolution strategy (CMAES). FN model optimized with PSO found to be the most robust artificial intelligence (AI) model to predict water saturation in carbonate rocks. The results showed that the proposed model predicted the water saturation with an accuracy of 97% when related to the experimental core values. In this study in addition to the development of optimized FN model, an explicit empirical correlation is also extracted from the optimized FN model. To validate the proposed correlation, three most commonly applied water saturation models (Simandoux, Bardon and Pied model, Fertl and Hammack Model, Waxman-Smits, and Indonesian) from literature were selected and subjected to same well log data as the AI model to estimate water saturation. The estimated water saturation values for AI and other saturation models were then compared with experimental values of testing data and the results showed that AI model was able to predict water saturation with an error of less than 5% while the saturation models did the same with lesser accuracy of error up to 50%. This work clearly shows that computer-based machine learning techniques can determine water saturation with a high precision and the developed correlation works extremely well in prediction mode.

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碳酸盐岩储层含水饱和度预测的人工智能方法

碳酸盐岩由于存在颗粒间和颗粒内孔隙，具有非常复杂的孔隙系统。这使得岩石物理数据的采集和分析以及碳酸盐岩的表征成为一个巨大的挑战。在本研究中，使用功能网络工具建立了一个模型，以岩石物理测井作为输入数据，dean-stark测量的含水饱和度作为输出参数来预测含水饱和度。该数据由200多个测井点组成，对应于可用的岩心数据。采用差分进化(DE)、粒子群优化(PSO)和协方差矩阵自适应进化策略(CMAES)等优化算法对FN模型进行了优化。经PSO优化后的FN模型是预测碳酸盐岩含水饱和度最强的人工智能模型。结果表明，该模型预测含水饱和度与实验岩心值的拟合精度为97%。本研究除了开发优化后的FN模型外，还从优化后的FN模型中提取了显式的经验相关性。为了验证所提出的相关性，从文献中选择了三种最常用的含水饱和度模型(Simandoux、Bardon和Pied模型、Fertl和Hammack模型、Waxman-Smits和Indonesian模型)，并使用与AI模型相同的测井数据来估计含水饱和度。将人工智能和其他饱和模型的含水饱和度估算值与测试数据的实验值进行比较，结果表明，人工智能模型预测含水饱和度的误差小于5%，而饱和模型预测含水饱和度的误差较小，误差可达50%。这项工作清楚地表明，基于计算机的机器学习技术可以高精度地确定含水饱和度，并且开发的相关性在预测模式下非常有效。

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, October 01, 2019

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