井志中的岩流和岩相自动分类:岩石物理学视角

GEOPHYSICS Pub Date : 2024-04-01 DOI:10.1190/geo2023-0533.1
R. Beloborodov, James Gunning, M. Pervukhina, Juerg Hauser, M. B. Clennell, Alan Mur, Vladimir Li
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引用次数: 0

摘要

从有线测井数据中准确解释岩性流体和岩相对于地震数据的联合岩相和阻抗反演等应用至关重要,但由于测井的复杂性和高维性,人工提取这些信息极具挑战性。由于压实和成岩作用导致岩石物理特性的深度趋势不同,传统的聚类方法在岩石流体类型推断方面也很吃力。我们介绍了一种岩石物理机器学习工作流程,可自动进行岩石流体分类和属性深度趋势建模,以应对这些挑战。该工作流程采用最大似然法,通过岩石物理模型明确考虑与深度相关的影响,从井眼数据中推断岩石流体类型。它采用稳健的期望最大化算法,将每种岩石流体类型与特定的岩石物理模型实例相关联,并限制在物理上合理的范围内。工作流程直接输出岩石流体类型比例和特定类型的岩石物理模型以及相关的不确定性,为地震反演提供重要的先验信息。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Automated litho-fluid and facies classification in well-logs: the Rock Physics perspective
While accurate litho-fluid and facies interpretation from wireline log data is critical for applications like joint facies and impedance inversion of seismic data, extracting this information manually is challenging due to the complexity and high dimensionality of the logs. Traditional clustering methods also struggle with litho-fluid type inference due to different depth trends in petrophysical rock properties due to compaction and diagenesis. We introduce a Rock Physics Machine Learning workflow that automates litho-fluid classification and property depth trend modeling to address these challenges. This workflow employs a maximum-likelihood approach, explicitly accounting for depth-related effects via Rock Physics models, to infer litho-fluid types from borehole data. It utilizes a robust Expectation-Maximization algorithm to associate each litho-fluid type with a specific Rock Physics model instance, constrained within physically reasonable bounds. The workflow directly outputs litho-fluid type proportions and type-specific Rock Physics models with associated uncertainties, providing essential prior information for seismic inversion.
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