Multidimensional Q-compensated reverse time migration using a high-efficient decoupled viscoacoustic wave equation

IF 1.8 3区 地球科学 Q3 GEOCHEMISTRY & GEOPHYSICS
Zilong Ye, Jianping Huang, Xinru Mu, Qiang Mao
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引用次数: 0

Abstract

Seismic waves propagating through attenuating media induce amplitude loss and phase dispersion. Neglecting the attenuation effects during seismic processing results in the imaging profiles with weakened energy, mispositioned interfaces and reduced resolution. To obtain high-quality imaging results, Q-compensated reverse time migration is developed. The kernel of the Q-compensated reverse time migration algorithm is a viscoacoustic wave equation with decoupled amplitude loss and phase dispersion terms. However, the majority of current decoupled viscoacoustic wave equations are solved using the computationally expensive pseudo-spectral method. To enhance computational efficiency, we initiate our approach from the dispersion relation of a single standard linear solid model. Subsequently, we derive a novel decoupled viscoacoustic wave equation by separating the amplitude loss and phase dispersion terms, previously coupled in the memory variable. The newly derived decoupled viscoacoustic wave equation can be efficiently solved using the finite-difference method. Then, we reverse the sign of the amplitude loss term of the newly derived viscoacoustic wave equation to implement high-efficient Q-compensated reverse time migration based on the finite-difference method. In addition, we design a regularization term to suppress the high-frequency noise for stabilizing the wavefield extrapolation. Forward modelling tests validate the decoupled amplitude loss and phase dispersion characteristics of the newly derived viscoacoustic wave equation. Numerical examples in both two-dimensional and three-dimensional confirm the effectiveness of the Q-compensated reverse time migration based on the finite-difference algorithm in mitigating the attenuation effects in subsurface media and providing high-quality imaging results.

利用高效解耦粘声波方程进行多维 Q 补偿反向时间迁移
地震波在衰减介质中传播时会产生振幅损失和相位频散。在地震处理过程中忽略衰减效应会导致成像剖面能量减弱、界面位置错误和分辨率降低。为了获得高质量的成像结果,开发了 Q 补偿反向时间迁移。Q 补偿反向时间迁移算法的内核是一个粘声波方程,具有解耦振幅损耗和相位频散项。然而,目前大多数解耦粘声波方程都是采用计算成本高昂的伪谱法求解的。为了提高计算效率,我们从单一标准线性固体模型的频散关系入手。随后,我们通过分离先前在记忆变量中耦合的振幅损失项和相位分散项,推导出一种新型解耦粘声波方程。新推导出的解耦粘声波方程可以使用有限差分法高效求解。然后,我们将新导出的粘声波方程中振幅损耗项的符号反转,在有限差分法的基础上实现了高效的 Q 补偿反向时间迁移。此外,我们还设计了一个正则项来抑制高频噪声,以稳定波场外推。正向建模测试验证了新推导的粘声波方程的解耦振幅损耗和相位频散特性。二维和三维数值示例证实了基于有限差分算法的 Q 补偿反向时间迁移在减轻地下介质衰减效应和提供高质量成像结果方面的有效性。
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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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