Elastic full-waveform inversion on Caesar-Tonga — Case study

Q2 Earth and Planetary Sciences

Leading Edge Pub Date : 2023-06-01 DOI:10.1190/tle42060414.1

J. Richardson, Kun Fu, Shaoming Lu, B. Bai, Xin Cheng, D. Vígh

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引用次数: 0

Abstract

Full-waveform inversion (FWI) has been widely used on 3D data sets to build detailed velocity models over the past 10 years. Most of these projects used pressure data and an acoustic approximation, with the assumption that the field data were dominated with P-waves. This approach of FWI can determine parameters related to the acoustic wave equation. It focuses on updating velocities by minimizing the misfit between observed and model data. Acoustic FWI, using the pressure component of collected data, has shown tremendous potential in simple geologic settings. Successful FWI projects, using wide-azimuth streamer, ocean bottom, and land survey geometries, have convinced the oil industry to pursue the next step by involving more physical properties. However, questions remain on how far we can properly describe field data with the acoustic approximation and at what point we need to switch to a much more expensive elastic wave equation implementation. In a complicated geologic region such as the Gulf of Mexico (GoM), the seismic wavefield can be complex and elastic FWI is needed to achieve a better velocity model, even when using mostly pressure data alone. We demonstrate the application of elastic FWI on sparse-node ocean-bottom-node data from the GoM and show comparisons to the acoustic solution. The comparisons demonstrate the benefits of the elastic FWI implementation when applied to image steeply dipping Miocene sands beneath a complex salt canopy, despite the increased computational expense. Furthermore, we demonstrate that when elastic FWI is applied to sufficiently high frequencies, the FWI-derived reflectivity product and velocity model are reliable interpretation products.

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凯撒-汤加弹性全波形反演——以实例研究

近10年来，全波形反演(FWI)在三维数据集上被广泛应用于建立详细的速度模型。这些项目大多使用压力数据和声学近似，并假设现场数据以纵波为主。该方法可以确定与声波方程相关的参数。它侧重于通过最小化观测数据和模型数据之间的不匹配来更新速度。声波FWI利用所收集数据的压力分量，在简单的地质环境中显示出巨大的潜力。成功的FWI项目使用了宽方位角拖缆、海底和陆地测量几何形状，使石油行业确信下一步将涉及更多的物理性质。然而，问题仍然存在，我们可以在多大程度上用声学近似来正确描述现场数据，以及在什么时候我们需要切换到更昂贵的弹性波动方程实现。在墨西哥湾(GoM)等复杂的地质区域，地震波场可能很复杂，即使仅使用压力数据，也需要弹性FWI来获得更好的速度模型。我们演示了弹性FWI在墨西哥湾海底节点稀疏数据上的应用，并与声学解决方案进行了比较。对比表明，弹性FWI应用于复杂盐层下中新世急倾斜砂岩成像时，尽管计算成本增加，但仍具有优势。此外，我们还证明，当弹性FWI应用于足够高的频率时，FWI推导的反射率乘积和速度模型是可靠的解释产品。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Leading Edge Earth and Planetary Sciences-Geology

CiteScore

3.10

自引率

0.00%

发文量

180

期刊介绍： THE LEADING EDGE complements GEOPHYSICS, SEG"s peer-reviewed publication long unrivalled as the world"s most respected vehicle for dissemination of developments in exploration and development geophysics. TLE is a gateway publication, introducing new geophysical theory, instrumentation, and established practices to scientists in a wide range of geoscience disciplines. Most material is presented in a semitechnical manner that minimizes mathematical theory and emphasizes practical applications. TLE also serves as SEG"s publication venue for official society business.