基于物理信息神经网络的激发时间成像条件反向时间迁移，利用光流矢量进行波场分解的行进时间计算

IF 1.6 3区地球科学 Q3 GEOCHEMISTRY & GEOPHYSICS

Journal of Geophysics and Engineering Pub Date : 2024-01-10 DOI:10.1093/jge/gxad106

Jian Li, Guoning Du, Dewen Qin, Wensun Yin, Jun Tan, Zhaolun Liu, Peng Song

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引用次数: 0

摘要

虽然与交叉相关成像条件相比，激发时间成像条件具有更低的内存消耗和更高的计算效率，但由于其旅行时间计算的精度问题和低波数噪声的影响，在工业应用中尚未得到广泛应用。本文介绍了物理信息神经网络（PINN）算法，以实现对源前向波场的高精度旅行时间计算。随后，我们介绍了一种通过光流矢量对反向时间波场进行高精度波场分解的技术，从而实现了每个波场的相关加权叠加成像。模型实验和实际数据处理表明，所提出的基于 PINN 的旅行时间计算算法在复杂模型的激发时间反向时间迁移成像中具有较高的精度和良好的适用性，而基于光流矢量波场分离的相关加权叠加成像可以显著抑制低波数噪声，实现复杂模型的高精度成像。

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Excitation time imaging condition reverse time migration based on physics-informed neural network traveltime calculation with wavefield decomposition using optical flow vector

Although the excitation-time imaging condition offers a lower memory consumption and higher computational efficiency compared to cross-correlation imaging condition, it has not been widely used in industrial applications because of the accuracy problem of traveltime calculation and the influence of low-wave-number noise. In this paper, we introduce the physics-informed neural network (PINN) algorithm to achieve a high-precision traveltime calculation of the source forward wavefield. Subsequently, we introduce a technique for high-precision wavefield decomposition of the reverse-time wavefield via the optical flow vector, enabling us to realize a correlation-weighted stacking imaging of each wavefield. Model experiments and real data processing show that the proposed traveltime calculation algorithm based on PINN offers high accuracy and good applicability in the excitation time reverse-time migration imaging of complex models, and correlation-weighted stacking imaging based on optical flow vector-based wavefield separation can significantly suppress the noise with low wavenumber and achieve high-precision imaging of complex models.

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来源期刊

Journal of Geophysics and Engineering 工程技术-地球化学与地球物理

CiteScore

2.50

自引率

21.40%

发文量

审稿时长

4 months

期刊介绍： Journal of Geophysics and Engineering aims to promote research and developments in geophysics and related areas of engineering. It has a predominantly applied science and engineering focus, but solicits and accepts high-quality contributions in all earth-physics disciplines, including geodynamics, natural and controlled-source seismology, oil, gas and mineral exploration, petrophysics and reservoir geophysics. The journal covers those aspects of engineering that are closely related to geophysics, or on the targets and problems that geophysics addresses. Typically, this is engineering focused on the subsurface, particularly petroleum engineering, rock mechanics, geophysical software engineering, drilling technology, remote sensing, instrumentation and sensor design.