基于Shearlet变换的三维地震数据重建

doi:10.11720/wtyht.2025.1271

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摘要

在地震勘探中,受采集成本或地形环境的限制,地震数据往往存在缺失,因此数据重建是地震数据预处理的关键步骤。本文基于压缩感知理论框架,对合成数据进行二维随机欠采样,将三维地震数据划分为一系列时间切片,随后引入Shearlet稀疏变换,结合凸集投影(POCS)算法逐次对每个时间切片进行数据重建,从而实现了基于Shearlet变换的三维地震数据时间域重建方法。数值试验和实测数据结果表明,相对于Curvelet变换的重建方法,本文所提出的重建方法的信噪比更高,计算速度更快,效果更好。

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	黄伟鸿
	张华
	武召祺
	戴梦雪
	鲍兴悦
	蒋伟龙
	邱修权

关键词 ： Shearlet变换, 地震数据重建, 压缩感知, 凸集投影算法

Abstract：

Seismic data collected in the field frequently suffer from missing values due to constraints of acquisition cost or terrain. Data reconstruction is a critical step in seismic data preprocessing. Based on the compressed sensing theoretical framework, this study subsampled synthesized data using the 2D random undersampling technique. Then, the 3D seismic data were divided into a series of time slices. By introducing the sparse Shearlet transform and using the convex set projection (POCS) algorithm, this study conducted sequential data reconstruction for various time slices. As a result, a Shearlet transform-based time-domain 3D seismic data reconstruction method was developed. Numerical experiments and measured results demonstrate that the proposed reconstruction method exhibits a higher signal-to-noise ratio, a higher computational speed, and better effects than a Curvelet transform-based approach.

Key words： Shearlet transform seismic data reconstruction compression sensing convex set projection algorithm

收稿日期: 2024-06-26 修回日期: 2024-11-03 出版日期: 2025-04-20

ZTFLH:

P631.4

基金资助:国家自然科学基金项目(42304145);国家自然科学基金项目(41874126);江西省自然科学基金项目(20232BAB213077);江西省自然科学基金项目(20242BAB26051)

通讯作者: 张华(1979-),男,教授,博士生导师,研究方向为地震数据处理方法技术以及自然灾害探测与评估。Email:zhhua1979@163.com

作者简介: 黄伟鸿(2000-),男,硕士研究生,主要研究方向为地震勘探数据重建和去噪方法。Email:1372296255@qq.com

引用本文:

黄伟鸿, 张华, 武召祺, 戴梦雪, 鲍兴悦, 蒋伟龙, 邱修权. 基于Shearlet变换的三维地震数据重建[J]. 物探与化探, 2025, 49(2): 394-403.
HUANG Wei-Hong, ZHANG Hua, WU Zhao-Qi, DAI Meng-Xue, BAO Xing-Yue, JIANG Wei-Long, QIU Xiu-Quan. 3D seismic data reconstruction based on Shearlet transform. Geophysical and Geochemical Exploration, 2025, 49(2): 394-403.

链接本文:

https://www.wutanyuhuatan.com/CN/10.11720/wtyht.2025.1271 或 https://www.wutanyuhuatan.com/CN/Y2025/V49/I2/394

Fig.1 合成数据及相应速度模型

Fig.2 指数和新型阈值模型的重建信噪比曲线

Fig.3 Curvelet变换和Shearlet变换重建结果及其误差

Fig.4 Curvelet变换和Shearlet变换重建信噪比曲线

Fig.5 二维随机欠采样重建结果f-k谱

Fig.6 重建结果与误差的单道显示
1—原始记录;2—Curvelet变换重建曲线;3—Shearlet变换重建曲线;4—Curvelet变换的误差曲线;5—Shearlet变换的误差曲线

Fig.7 Curvelet变换和Shearlet变换重建结果和各时间切片信噪比

Fig.8 含噪声数据二维随机欠采样重建结果及其误差

Fig.9 连续缺失地震道重建

Fig.10 连续缺失地震道数与重建后信噪比曲线

Fig.11 实测数据重建结果

Fig.12 实测数据重建结果f-k谱

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