岩石物理学中的机器学习:优势与局限

Chicheng Xu , Lei Fu , Tao Lin , Weichang Li , Shouxiang Ma
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引用次数: 5

摘要

机器学习提供了一种强大的替代数据驱动方法,可以从地下数据中完成许多岩石物理任务。它可以从庞大而丰富的数据库中吸收信息,并推断出隐藏在数据中的关系、规则和知识。当数据背后的物理变得极其复杂、不明确,甚至不清楚/未知时,机器学习方法的优势在于比传统的基于物理的解释模型更具灵活性和更广泛的适用性。此外,机器学习可以用来协助许多劳动密集型的人类解释任务,如不良数据识别、相分类和图像数据的地理特征分割。然而,机器学习结果的有效性在很大程度上取决于输入数据的数量、质量、代表性和相关性,包括准确的标签。为了达到最佳性能,需要在数据准备、特征工程、算法选择、架构设计超参数调优和正则化方面付出大量努力。此外,还需要克服人口不平衡、过拟合、欠拟合等技术问题。本文讨论了利用机器学习解决岩石物理难题的优势、局限性和条件。机器学习算法完成不同挑战性任务的能力只能通过克服其自身的局限性来实现。如果使用得当,机器学习可以成为一种强大的颠覆性工具,帮助完成一系列关键的岩石物理任务。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Machine learning in petrophysics: Advantages and limitations

Machine learning provides a powerful alternative data-driven approach to accomplish many petrophysical tasks from subsurface data. It can assimilate information from large and rich data bases and infer relations, rules, and knowledge hidden in the data. When the physics behind data becomes extremely complex, inexplicit, or even unclear/unknown, machine learning approaches have the advantage of being more flexible with wider applicability over conventional physics-based interpretation models. Moreover, machine learning can be utilized to assist many labor-intensive human interpretation tasks such as bad data identification, facies classification, and geo-features segmentation out of imagery data.

However, the validity of the outcome from machine learning largely depends on the quantity, quality, representativeness, and relevance of the feeding data including accurate labels. To achieve the best performance, it requires significant effort in data preparation, feature engineering, algorithm selection, architecture design hyperparameter tuning, and regularization. In addition, it needs to overcome technical issues such as imbalanced population, overfitting, and underfitting.

In this paper, advantages, limitations, and conditions of using machine learning to solve petrophysics challenges are discussed. The capability of machine learning algorithms in accomplishing different challenging tasks can only be achieved by overcoming its own limitations. Machine learning, if properly utilized, can become a powerful disruptive tool for assisting a series of critical petrophysics tasks.

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