Detecting local earthquakes via fiber-optic cables in telecommunication conduits under Stanford University campus using deep learning

IF 4.2 2区 地球科学 Q1 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS Computers & Geosciences Pub Date : 2024-06-04 DOI:10.1016/j.cageo.2024.105625
Fantine Huot, Robert G. Clapp, Biondo L. Biondi
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Abstract

With fiber-optic seismic acquisition development, continuous dense seismic monitoring is becoming increasingly more accessible. Repurposing fiber cables in telecommunication conduits makes it possible to run seismic studies at low cost, even in locations where traditional seismometers are not easily installed, such as urban areas. However, due to the large volume of continuous streaming data, data collected in such a manner will go to waste unless we significantly automate the processing workflow. We train a convolutional neural network (CNN) for earthquake detection using 3000 events from a publicly available catalog and data acquired over three years by fiber cables in telecommunication conduits under the Stanford University campus. We performed a hyperparameter search both on the network architecture itself (e.g., number of layers, number of parameters) and on its training parameters, showing that CNNs with a small number of layers are sufficient for performing this detection task with high accuracy. We introduce a novel method for combining the deep learning results on fiber-optic and seismometer data to improve detection accuracy, dramatically reducing the false detection rate that is often a problem when processing large time-scale noisy continuous data. Consequently, we demonstrate that enhancing two sparse seismometer stations with an urban fiber system allows for the reliable detection of small earthquakes despite a low signal-to-noise ratio. We scale this processing method over three years of continuous data and show that this system reliably detects local small-amplitude earthquakes down to magnitudes as low as 0.5, leading to the discovery of previously uncataloged events.

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利用深度学习,通过斯坦福大学校园地下电信管道中的光缆探测局部地震
随着光纤地震采集技术的发展,连续高密度地震监测变得越来越容易获得。重新利用电信管道中的光缆,即使在城市等不易安装传统地震仪的地方,也能以低成本开展地震研究。然而,由于连续流数据量巨大,除非我们大幅提高处理工作流程的自动化程度,否则以这种方式收集的数据将被浪费。我们利用公开目录中的 3000 个事件和斯坦福大学校园地下电信管道中的光缆三年来采集的数据,训练了一个用于地震检测的卷积神经网络(CNN)。我们对网络结构本身(如层数、参数数)及其训练参数进行了超参数搜索,结果表明,具有少量层数的 CNN 足以高精度地完成这项检测任务。我们介绍了一种结合光纤数据和地震仪数据深度学习结果的新方法,以提高检测精度,显著降低误检率,而误检率是处理大时间尺度噪声连续数据时经常出现的问题。因此,我们证明了利用城市光纤系统增强两个稀疏地震仪台站,可以在信噪比较低的情况下可靠地检测到小地震。我们将这种处理方法应用于三年的连续数据,结果表明该系统能可靠地探测到震级低至 0.5 级的局部小震级地震,从而发现了以前未编入目录的地震事件。
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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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