Free-surface multiple attenuation and seismic deghosting for blended data using convolutional neural networks

IF 3 2区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS Geophysics Pub Date : 2024-04-09 DOI:10.1190/geo2023-0417.1
Mert S. R. Kiraz, Roel Snieder, Jon Sheiman
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Abstract

Simultaneous source acquisition has become common over the past few decades for marine seismic surveys because of the increased efficiency of seismic acquisition by limiting the time, reducing the cost, and having less environmental impact than conventional single-source (or unblended) acquisition surveys. For simultaneous source acquisition, seismic sources at different locations are fired with time delays, and the recorded data are referred to as the blended data. The air-water interface (or free surface) creates strong multiples and ghost reflections for blended seismic data. The multiples and/or ghost reflections caused by a source in the blended data overlap with the primary reflections of another source, thus creating a strong interference between the primary and multiple events of different sources. We develop a convolutional neural network (CNN) method to attenuate free-surface multiples and remove ghost reflections simultaneously from the blended seismic data. The CNN-based solution that we develop operates on single traces and is not sensitive to the missing near-offset traces, missing traces, and irregular/sparse acquisition parameters (e.g., for ocean-bottom node acquisition and time-lapse monitoring studies). We illustrate the efficacy of our free-surface multiple attenuation and seismic deghosting method by presenting synthetic and field data applications. The numerical experiments demonstrate that our CNN-based approach for simultaneously attenuating free-surface multiples and removing ghost reflections can be applied to the blended data without the deblending step. Although the interference of primaries and multiples from different shots in the blended data makes free-surface multiple attenuation harder than the unblended data, we determine that our CNN-based method effectively attenuates free-surface multiples in the blended synthetic and field data even when the delay time for the blending is different in the training data than in the data to which the CNN is applied.
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利用卷积神经网络对混合数据进行自由表面多重衰减和地震解调
与传统的单震源(或非混合震源)采集勘探相比,同步震源采集可以限制时间、降低成本、减少对环境的影响,从而提高地震采集的效率,因此在过去几十年里,同步震源采集已成为海洋地震勘探的普遍做法。在同步震源采集中,不同位置的震源在发射时会有时间延迟,记录的数据称为混合数据。空气-水界面(或自由表面)会对混合地震数据产生强烈的多重反射和鬼影反射。混合数据中一个震源产生的多重反射和/或鬼魂反射与另一个震源的主反射重叠,从而在不同震源的主事件和多重事件之间产生强烈干扰。我们开发了一种卷积神经网络(CNN)方法,可同时衰减自由表面多重反射和去除混合地震数据中的鬼魂反射。我们开发的基于卷积神经网络的解决方案可在单个地震道上运行,对丢失的近偏移地震道、丢失的地震道和不规则/稀疏的采集参数(例如,用于海底节点采集和延时监测研究)不敏感。我们通过合成数据和野外数据的应用,说明了我们的自由表面多重衰减和地震减震方法的功效。数值实验证明,我们基于 CNN 的同时衰减自由表面多重反射和去除鬼反射的方法可用于混合数据,而无需去叠加步骤。虽然混合数据中来自不同镜头的原点和多点干扰使得自由表面多点衰减比未混合数据更难,但我们确定,基于 CNN 的方法能有效衰减混合合成数据和现场数据中的自由表面多点,即使训练数据中的混合延迟时间与应用 CNN 的数据中的延迟时间不同。
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来源期刊
Geophysics
Geophysics 地学-地球化学与地球物理
CiteScore
6.90
自引率
18.20%
发文量
354
审稿时长
3 months
期刊介绍: Geophysics, published by the Society of Exploration Geophysicists since 1936, is an archival journal encompassing all aspects of research, exploration, and education in applied geophysics. Geophysics articles, generally more than 275 per year in six issues, cover the entire spectrum of geophysical methods, including seismology, potential fields, electromagnetics, and borehole measurements. Geophysics, a bimonthly, provides theoretical and mathematical tools needed to reproduce depicted work, encouraging further development and research. Geophysics papers, drawn from industry and academia, undergo a rigorous peer-review process to validate the described methods and conclusions and ensure the highest editorial and production quality. Geophysics editors strongly encourage the use of real data, including actual case histories, to highlight current technology and tutorials to stimulate ideas. Some issues feature a section of solicited papers on a particular subject of current interest. Recent special sections focused on seismic anisotropy, subsalt exploration and development, and microseismic monitoring. The PDF format of each Geophysics paper is the official version of record.
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