Reservoir characterization reimagined: a hybrid neural network approach for direct three-dimensional petrophysical property characterization

IF 1.1 4区 地球科学 Q3 GEOLOGY
Matin Mahzad, Mohammad Ali Riahi
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Abstract

Reservoir characterization, crucial for oilfield development, aims to unravel intricate non-linear relationships within real-world data. Conventional methods, rooted in simplistic theories, often lead to uncertainties and inaccuracies in workflows. Leveraging the power of deep learning, this study introduces a pioneering approach: a hybrid neural network model merging convolutional and Long Short-Term Memory (LSTM) RNN layers. Focused on effective porosity modeling for the Ghar Member of the Asmari Formation in western Iran, the study utilizes post-stack seismic data and well-log information. By effectively deciphering spatio-temporal information within the data, our methodology allows for spatially aware predictions of effective porosity values, a capability not addressed by previous studies. The hybrid neural network model predicts effective porosity values for the entire reservoir, creating a 3D grid of porosity. It leverages CNN and RNN layers to decipher spatio-temporal information within the data, thereby enabling the model to make spatially aware predictions. The model achieved a mean squared error (MSE) of 0.005, generating clear 3D porosity models with greater detail compared to traditional machine learning and geostatistical methods. This innovative methodology represents a step forward in reservoir characterization, offering improved precision and efficiency. It holds promise for advancing oilfield development practices in the future.

Abstract Image

储层表征再造:直接三维岩石物理特性表征的混合神经网络方法
油藏特征描述对油田开发至关重要,其目的是揭示真实世界数据中错综复杂的非线性关系。根植于简单化理论的传统方法往往会导致工作流程中的不确定性和不准确性。本研究利用深度学习的强大功能,引入了一种开创性的方法:融合卷积层和长短期记忆(LSTM)RNN 层的混合神经网络模型。该研究利用叠后地震数据和井记录信息,重点对伊朗西部阿斯马拉地层 Ghar 成员进行了有效的孔隙度建模。通过有效破译数据中的时空信息,我们的方法可以对有效孔隙度值进行空间感知预测,而这是以往的研究无法实现的。混合神经网络模型可预测整个储层的有效孔隙度值,创建一个三维孔隙度网格。它利用 CNN 和 RNN 层来解读数据中的时空信息,从而使模型能够进行空间感知预测。与传统的机器学习和地质统计方法相比,该模型的均方误差 (MSE) 为 0.005,能生成更详细、更清晰的三维孔隙度模型。这一创新方法代表着油藏表征技术向前迈进了一步,提高了精度和效率。它有望在未来推动油田开发实践。
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来源期刊
Carbonates and Evaporites
Carbonates and Evaporites 地学-地质学
CiteScore
2.80
自引率
14.30%
发文量
70
审稿时长
3 months
期刊介绍: Established in 1979, the international journal Carbonates and Evaporites provides a forum for the exchange of concepts, research and applications on all aspects of carbonate and evaporite geology. This includes the origin and stratigraphy of carbonate and evaporite rocks and issues unique to these rock types: weathering phenomena, notably karst; engineering and environmental issues; mining and minerals extraction; and caves and permeability. The journal publishes current information in the form of original peer-reviewed articles, invited papers, and reports from meetings, editorials, and book and software reviews. The target audience includes professional geologists, hydrogeologists, engineers, geochemists, and other researchers, libraries, and educational centers.
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