Fracture density reconstruction using direct sampling multiple-point statistics and extreme value theory

IF 2.6 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS Applied Computing and Geosciences Pub Date : 2024-03-23 DOI:10.1016/j.acags.2024.100161
Ana Paula Burgoa Tanaka , Philippe Renard , Julien Straubhaar
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Abstract

The aim of this work is to present a methodology for the reconstruction of missing fracture density within highly fractured intervals, which can represent preferential fluid flow pathways. The lack of record can be very common due to the intense presence of fractures, dissolution processes, or data acquisition issues. The superposition of numerous fractures makes the definition of fracture surfaces impossible, as a consequence, modeling such zones is challenging. In order to address this issue, the usage of direct sampling multiple-point statistics to perform gap filling in well logs is demonstrated as an alternative to other techniques. It reproduces data patterns and provides several models representing uncertainty. The method was tested in intervals from a highly fractured well, by removing previously known fracture density data, and simulating different scenarios with direct sampling. Simulation results are compared to the observed data using cross-validation and continuous rank probability score. The reference scenario training data set consists in one well and two variables: fracture density and fracture occurrence. A sensitivity analysis is carried out considering additional variables, additional wells, different intervals, resampling with extremes, and other gap filling techniques. The auxiliary variable plays an important role in pattern matching, but adding wells and logs increases the complexity of the method without improving pattern retrieval. Best results are obtained applying extreme values theory for stochastic process with the enrichment of the fracture density data at the tail region, followed by resampling of the new values. The enriched data is used for the gap filling resulting in lower continuous rank probability score, and the achievement of extreme fracture density values.

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利用直接采样多点统计和极值理论重建断裂密度
这项工作的目的是提出一种方法,用于重建高度断裂区段内缺失的断裂密度,这些断裂密度可以代表流体流动的优先路径。由于裂缝密集、溶解过程或数据采集问题,记录缺失的情况非常普遍。大量断裂的叠加使得断裂面的定义变得不可能,因此,对这类区域进行建模具有挑战性。为了解决这个问题,我们展示了使用直接采样多点统计法对测井记录进行间隙填充,以替代其他技术。它能再现数据模式,并提供多个代表不确定性的模型。通过去除先前已知的压裂密度数据,并使用直接采样模拟不同的情况,在一口高度压裂井的区间对该方法进行了测试。使用交叉验证和连续等级概率分数将模拟结果与观测数据进行比较。参考情景训练数据集包括一口井和两个变量:压裂密度和压裂发生率。考虑到额外的变量、额外的井、不同的区间、用极端值重新采样以及其他填补空白的技术,进行了敏感性分析。辅助变量在模式匹配中起着重要作用,但增加油井和测井记录会增加方法的复杂性,却不会改善模式检索。应用随机过程的极值理论,在尾部区域丰富裂缝密度数据,然后对新值进行重采样,可以获得最佳结果。丰富后的数据用于填补空白,从而降低了连续等级概率得分,并获得了极值裂缝密度值。
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来源期刊
Applied Computing and Geosciences
Applied Computing and Geosciences Computer Science-General Computer Science
CiteScore
5.50
自引率
0.00%
发文量
23
审稿时长
5 weeks
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