Linking Geostatistical Methods: Co-Kriging – Principal Component Analysis (PCA); with Integrated Well Data and Seismic Cross Sections for Improved Hydrocarbon Prospecting (Case Study: Field X)

Scientia Bruneiana Pub Date : 2018-10-06 DOI:10.46537/SCIBRU.V17I1.71

R. Andika, H. Dewi

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Abstract

In this era of globalization, the demand for energy is rising in tandem with social and economic development throughout the world. Current hydrocarbon demand is much greater than domestic crude oil and natural gas production. In order to bridge the gap between energy supply and demand, it is imperative to accelerate exploration activities and develop new effective and efficient techniques for discovering hydrocarbons. Therefore, this study presents a new method for integrating seismic inversion data and well data using geostatistical principles that allow for the high level of processing and interpretation expected nowadays. The main part of this paper will concern the preparation and processing of the input data, with the aim of constructing a map of hydrocarbon-potency distribution in a certain horizon. It will make use of principal component analysis (PCA) and the co-kriging method. In the case study of Field X, we analyze a single new dataset by applying PCA to every existing well that contains multivariate rock-physics data. The interpretation that can be extracted from the output gives us information about the hydrocarbon presence in a particular depth range. We use that output as our primary dataset from which our research map is constructed by applying the co-kriging method. We also rely on an acoustic impedance dataset that is available for a certain horizon to fulfill the co-kriging interpolation requirement. All of the acoustic impedance data and output data that result from the application of PCA in a particular horizon give strong correlation factors. Our resulting final map is also validated with information from proven hydrocarbon discoveries. It is demonstrated that the map gives accurate information suggesting the location of hydrocarbon potency, which will need some detailed follow-up work to enhance the distribution probabilities. This method can be considered for hydrocarbon prediction in any area of sparse well control.

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联合地质统计学方法:协同克里格-主成分分析结合井资料和地震剖面改进油气勘探(案例研究:X油田)

在全球化时代，世界各国对能源的需求随着社会经济的发展而不断增加。目前的碳氢化合物需求远远大于国内的原油和天然气产量。为了弥补能源供需之间的差距，必须加快勘探活动，开发新的有效和高效的碳氢化合物发现技术。因此，本研究提出了一种利用地质统计学原理整合地震反演数据和井资料的新方法，可以实现目前所期望的高水平处理和解释。本文的主要内容是对输入数据的准备和处理，目的是绘制某一层位的含油气分布图。它将利用主成分分析(PCA)和共克里格方法。在X油田的案例研究中，我们通过将PCA应用于包含多元岩石物理数据的每口现有井来分析单个新数据集。从输出中提取的解释可以为我们提供有关特定深度范围内油气存在的信息。我们使用该输出作为我们的主要数据集，通过应用共同克里格方法构建我们的研究地图。我们还依赖于声学阻抗数据集，该数据集可用于特定水平，以满足共同克里格插值要求。在某一层位应用主成分分析得到的声阻抗数据和输出数据均具有较强的相关因子。我们的最终地图也与已探明的油气发现信息进行了验证。结果表明，该地图给出了油气潜力位置的准确信息，后续还需进行详细的工作，以提高油气分布概率。该方法可用于任何井控稀疏区域的油气预测。

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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Scientia Bruneiana

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