Deep-salt: Complete three-dimensional salt segmentation from inaccurate migrated subsurface offset gathers using deep learning

IF 1.8 3区 地球科学 Q3 GEOCHEMISTRY & GEOPHYSICS
Ana P. O. Muller, Bernardo Fraga, Matheus Klatt, Jessé C. Costa, Clecio R. Bom, Elisangela L. Faria, Marcelo P. de Albuquerque, Marcio P. de Albuquerque
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引用次数: 0

Abstract

Delimiting salt inclusions from migrated images during the velocity model building flow is a time-consuming activity that depends on highly human-curated analysis and is subject to interpretation errors or limitations of the images and methods available. We propose a supervised deep learning based method to include three-dimensional salt geometries in the velocity models. We compare two convolutional networks – based on the U-Net architecture – which can process three-dimensional seismic data. One architecture uses three-dimensional convolutional kernels, and the other has convolutional long short-term memory units. Each architecture requires specific preprocessing steps which affects their training and predictive performance. Both proposed architectures use subsurface offset gathers obtained from reverse time migration with an extended imaging condition as input and are trained to predict the salt inclusions. The velocity model used in migration is a reasonable approximation of sediment velocity but without salt inclusions. Thus, the migration model and, consequently, the migrated images are inaccurate due to the absence of the salt inclusion in the model using just the sediment velocity information for the segmentation. A similar salt inclusion methodology was previously validated for two-dimensional approaches; we extend it to the three-dimensional case. Our approach relies on subsurface common image gathers to focus the sediments' reflections around the zero offset and spread salt reflections' energy over large subsurface offsets. The results show that both proposed network models can accurately delineate the salt bodies in the test models, but when evaluating the trained networks for the three-dimensional SEG/EAGE salt model, the architecture with convolutional long short-term memory units has proven to generalize better.

深盐:利用深度学习从不确定性迁移的地下偏移采集中完成三维盐分分割
在速度模型建立过程中,从迁移图像中划分盐包裹体是一项耗时的工作,它依赖于高度人工化的分析,并受到解释错误或可用图像和方法的限制。我们提出了一种基于深度学习的监督方法,将三维盐几何形状纳入速度模型。我们比较了两种基于 U-Net 架构的卷积网络,它们可以处理三维地震数据。一种结构使用三维卷积核,另一种结构使用卷积长短期记忆单元。每种架构都需要特定的预处理步骤,这会影响其训练和预测性能。这两种拟议的架构都使用从反向时间迁移中获得的地下偏移采集,并将扩展成像条件作为输入,经过训练后预测盐夹杂物。迁移中使用的速度模型是沉积物速度的合理近似值,但不含盐包裹体。因此,由于在仅使用沉积物速度信息进行分割的模型中没有盐包裹体,因此迁移模型以及迁移图像都是不准确的。类似的盐类包裹体方法之前已在二维方法中得到验证,我们将其扩展到三维情况。我们的方法依赖于次表层共同图像采集,将沉积物的反射聚焦在零偏移附近,并将盐反射的能量分散到大的次表层偏移上。结果表明,所提出的两种网络模型都能准确划分测试模型中的盐体,但在评估针对三维 SEG/EAGE 盐模型所训练的网络时,事实证明具有卷积长短期记忆单元的架构具有更好的泛化能力。
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来源期刊
Geophysical Prospecting
Geophysical Prospecting 地学-地球化学与地球物理
CiteScore
4.90
自引率
11.50%
发文量
118
审稿时长
4.5 months
期刊介绍: Geophysical Prospecting publishes the best in primary research on the science of geophysics as it applies to the exploration, evaluation and extraction of earth resources. Drawing heavily on contributions from researchers in the oil and mineral exploration industries, the journal has a very practical slant. Although the journal provides a valuable forum for communication among workers in these fields, it is also ideally suited to researchers in academic geophysics.
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