Improved reservoir characterization of thin beds by advanced deep learning approach

IF 2.6 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Umar Manzoor , Muhsan Ehsan , Muyyassar Hussain , Yasir Bashir
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Abstract

Targeting reservoirs below seismic resolution presents a major challenge in reservoir characterization. High-resolution seismic data is critical for imaging the thin gas-bearing Khadro sand facies in several fields within the Lower Indus Basin (LIB). To truly characterize thin beds below tuning thickness, we showcase an optimally developed deep learning technique that can save up to 75% turn-around time while significantly reducing cost. Our workflow generates high-frequency acoustic impedance synthetics by utilizing a deep neural network (DNN) at the reservoir level vis-a-vis validating the results with existing geological facies. Simultaneously, we introduce continuous wavelet transform (CWT); wherein the three components (real, imaginary, and magnitude) are interrelated to obtain a resultant high-frequency seismic volume. A strong agreement is established at available wells to achieve a higher resolution seismic by injecting higher frequencies, which is then populated throughout the 3D cube. An excellent correlation is met with key seismic attributes extracted across the field for original and CWT-based synthetic seismic. The augmented seismic volume with enhanced frequency range substantiates the dominant frequency (Fd) and resolves thin beds, which is also validated with the help of wedge modeling of both acquired and high-frequency datasets. As a geologically valid solution, our approach effectively resolves an initially 54 m bed to ∼25 m. This deep-learning methodology is ideally suited to regions where the acquired seismic has limited resolution and lacks advanced reservoir characterization.

Abstract Image

利用先进的深度学习方法改进薄层的储层特征描述
锁定地震分辨率以下的储层是储层特征描述的一大挑战。高分辨率地震数据对于下印度河盆地(LIB)几个油田的薄含气卡德罗砂层成像至关重要。为了真正描述调厚以下薄层的特征,我们展示了一种优化开发的深度学习技术,该技术可节省高达 75% 的周转时间,同时显著降低成本。我们的工作流程通过在储层层面利用深度神经网络(DNN)生成高频声阻抗合成,并根据现有地质面验证结果。同时,我们引入了连续小波变换(CWT),将三个分量(实值、虚值和幅值)相互关联,以获得高频地震量。通过注入更高的频率,在现有的油井中建立了很强的一致性,以获得更高分辨率的地震,然后将其填充到整个三维立方体中。原始地震和基于 CWT 的合成地震与整个油气田提取的关键地震属性具有极好的相关性。频率范围增强的增强地震量证实了主频(Fd)并解析了薄层,这也在采集数据集和高频数据集的楔形建模的帮助下得到了验证。作为一种地质学上有效的解决方案,我们的方法有效地将最初 54 米的薄层解析至 25 米。这种深度学习方法非常适合于地震采集分辨率有限、缺乏先进储层特征描述的地区。
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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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