Detection of the low-velocity layer using a convolutional neural network on passive surface-wave data: An application in Hangzhou, China

IF 4.2 2区 地球科学 Q1 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Xinhua Chen, Jianghai Xia, Jingyin Pang, Changjiang Zhou
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引用次数: 0

Abstract

Passive surface-wave methods using dense seismic arrays have gained growing attention in near-surface high-resolution imaging in urban environments. Deep learning (DL) in the extraction of dispersion curves and inversion can release a tremendous workload brought by dense seismic arrays. We presented a case study of imaging shear-wave velocity (Vs) structure and detecting low-velocity layer (LVL) in the Hangzhou urban area (eastern China). We used traffic-induced passive surface-wave data recorded by dense linear arrays. We extracted phase-velocity dispersion curves from noise recordings using seismic interferometry and multichannel analysis of surface waves. We adopted a convolutional neural network to estimate near-surface Vs models by inverting Rayleigh-wave fundamental-mode phase velocities. To improve the accuracy of the inversion, we utilized the sensitivities to weight the loss function. The average root mean square error from the weighted inversion is 46% lower than that from the unweighted DL inversion. The estimated pseudo-2D Vs profiles correspond to the velocities obtained from downhole seismic measurements. Compared with an investigation on the same survey area, our inversion results are more consistent with the Vs provided by downhole seismic measurements within 50–60 m where the LVL exists. The trained neural network successfully identified that the LVL is located at 50–60 m deep. To check the applicability of the trained neural network, we applied it to a nearby passive surface-wave survey and the inversion results agree with the existing investigation results. The two applications demonstrate the accuracy and efficiency of delineating near-surface Vs structures with the LVL from traffic-induced noise using the DL technique. The DL inversion has great potential for monitoring subsurface medium changes in urban areas.

利用卷积神经网络对被动面波数据进行低速层探测:在中国杭州的应用
使用密集地震阵列的被动面波方法在城市环境的近地表高分辨率成像中日益受到关注。深度学习(DL)在频散曲线提取和反演中可以释放密集地震阵列带来的巨大工作量。我们介绍了杭州城区(中国东部)剪切波速度(Vs)结构成像和低速层(LVL)探测的案例研究。我们使用了密集线性阵列记录的交通诱发的被动面波数据。我们利用地震干涉测量和多通道面波分析从噪声记录中提取了相位速度频散曲线。我们采用卷积神经网络,通过反演雷利波基模相速来估计近地表 Vs 模型。为了提高反演的准确性,我们利用灵敏度对损失函数进行了加权。加权反演的平均均方根误差比未加权的 DL 反演低 46%。估计的伪二维 Vs 剖面与井下地震测量获得的速度一致。与在同一勘测区进行的调查相比,我们的反演结果与井下地震测量提供的 Vs 更为一致,即在 LVL 存在的 50-60 米范围内。经过训练的神经网络成功识别出 LVL 位于 50-60 米深处。为了检验训练有素的神经网络的适用性,我们将其应用于附近的被动面波勘探,反演结果与现有勘探结果一致。这两项应用证明了利用 DL 技术从交通诱导噪声中用 LVL 划分近地表 Vs 结构的准确性和效率。DL 反演在监测城市地区地下介质变化方面具有巨大潜力。
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来源期刊
Computers & Geosciences
Computers & Geosciences 地学-地球科学综合
CiteScore
9.30
自引率
6.80%
发文量
164
审稿时长
3.4 months
期刊介绍: Computers & Geosciences publishes high impact, original research at the interface between Computer Sciences and Geosciences. Publications should apply modern computer science paradigms, whether computational or informatics-based, to address problems in the geosciences.
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