Development of Oil Formation Volume Factor Model using Adaptive Neuro-Fuzzy Inference Systems ANFIS

F. Alakbari, M. Mohyaldinn, M. Ayoub, A. Muhsan, I. Hussein
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引用次数: 3

Abstract

The oil formation volume factor is one of the main reservoir fluid properties that plays a crucial role in designing successful field development planning and oil and gas production optimization. The oil formation volume factor can be acquired from pressure-volume-temperature (PVT) laboratory experiments; nonetheless, these experiments' results are time-consuming and costly. Therefore, many studies used alternative methods, namely empirical correlations (using regression techniques) and machine learning to determine the formation volume factor. Unfortunately, the previous correlations and machine learning methods have some limitations, such as the lack of accuracy. Furthermore, most earlier models have not studied the relationships between the inputs and outputs to show the proper physical behaviors. Consequently, this study comes to develop a model to predict the oil formation volume factor at the bubble point (Bo) using an adaptive neuro-fuzzy inference system (ANFIS). The ANFIS model was built based on 924 data sets collected from published sources. The ANFIS model and previous 28 models were validated and compared using the trend analysis and statistical error analysis, namely average absolute percent relative error (AAPRE) and correlation coefficient (R). The trend analysis study has shown that the ANFIS model and some previous models follow the correct trend analysis. The ANFIS model is the first rank model and has the lowest AAPRE of 0.71 and the highest (R) of 0.9973. The ANFIS model also has the lowest average percent relative error (APRE), root mean square error (RMSE), and standard deviation (SD) of -0.09, 1.01, 0.0075, respectively.
基于自适应神经模糊推理系统的油层体积因子模型研究
地层体积系数是油藏流体的主要性质之一,对油田开发规划和油气生产优化具有重要意义。油层体积因子可通过压力-体积-温度(PVT)室内实验获得;然而,这些实验的结果既耗时又昂贵。因此,许多研究使用替代方法,即经验相关性(使用回归技术)和机器学习来确定地层体积因子。不幸的是,以前的相关性和机器学习方法都有一些局限性,比如缺乏准确性。此外,大多数早期的模型没有研究输入和输出之间的关系,以显示适当的物理行为。因此,本研究建立了一个利用自适应神经模糊推理系统(ANFIS)预测气泡点(Bo)油层体积因子的模型。ANFIS模型是基于从公开来源收集的924个数据集建立的。通过趋势分析和统计误差分析,即平均绝对百分比相对误差(AAPRE)和相关系数(R),对ANFIS模型和之前的28个模型进行了验证和比较。趋势分析研究表明,ANFIS模型和之前的一些模型遵循了正确的趋势分析。ANFIS模型为第一等级模型,AAPRE最低,为0.71,R最高,为0.9973。ANFIS模型的平均相对误差(APRE)、均方根误差(RMSE)和标准差(SD)也最低,分别为-0.09、1.01和0.0075。
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