卷积神经网络在实验室地震事件类型分析中的应用

IF 0.9 4区地球科学 Q4 GEOCHEMISTRY & GEOPHYSICS

Acta Geodynamica et Geomaterialia Pub Date : 2021-05-04 DOI:10.13168/AGG.2021.0019

P. Kolář

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引用次数: 1

摘要

在这项工作中，我们使用卷积神经网络（CNN）成功地在地震图中识别了地震事件（地震观测）。根据过去的（模拟）地震图解释，我们没有按照一般方法将数字地震图视为时间序列，而是将其转换为连续数据流的时间快照。多通道地震图以多层图像的形式用时频域表示，每个信号通道形成一个图像层。然后将图像暴露于CNN（由三个卷积块组成，其架构设计使用贝叶斯优化进行了验证）。为了提高可靠性，我们将后验类型函数（PTP）评估为所有考虑的信号类型类别（在我们的情况下为五类）的概率的组合，这提高了识别的稳健性。对于数据，我们使用了声发射（AE）事件的记录。这些事件是在最初为研究材料/岩石特性而进行的实验室加载实验期间产生的。众所周知，AE事件可以以与自然地震相同的方式进行研究，并以其他方式作为实验室地震模型进行处理。与许多物理参数已知或可以控制的自然地震相比，AE事件不那么复杂。根据我们的结果，我们得出结论，在应用所提出的方法在地震图中识别自然地震之前，成功识别AE事件是必要的一步。

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Type analysis of laboratory seismic events by convolutional neural network

In this work, we successfully identified seismic events (observations of earthquakes) in seismograms using a Convolutional Neural Network (CNN). In accordance with past (analogue) seismogram interpretations, we did not treat digital seismograms as a time series, as per the general method, but, rather, converted them into time snaps of continuous data flow. Multichannel seismograms were represented with a time-frequency domain in the form of multilayer images, with each signal channel forming one image layer. Images were then exposed to CNN (composed of three convolutional blocks whose architecture design was justified using Bayesian optimization). To improve reliability, we evaluated the posterior type function (PTP) as a combination of the probabilities of all of the considered classes of signal types (five in our case) which increased robustness of the identification. For data, we used records of acoustic emission (AE) events. The events were generated during laboratory loading experiments originally performed to study material/rock properties. As known, AE events may be studied in the same manner as natural earthquakes and treated in other ways as laboratory earthquake models. AE events are less complex compared to natural earthquakes where many of the physical parameters are known or may be controlled. Based on our results, we concluded that the successful identification of AE events is a necessary step prior to applying the proposed methodology for identifying natural earthquakes in seismograms.

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来源期刊

Acta Geodynamica et Geomaterialia 地学-地球化学与地球物理

CiteScore

2.30

自引率

0.00%

发文量

期刊介绍： Acta geodynamica et geomaterialia (AGG) has been published by the Institute of Rock Structures and Mechanics, Czech Academy of Sciences since 2004, formerly known as Acta Montana published from the beginning of sixties till 2003. Approximately 40 articles per year in four issues are published, covering observations related to central Europe and new theoretical developments and interpretations in these disciplines. It is possible to publish occasionally research articles from other regions of the world, only if they present substantial advance in methodological or theoretical development with worldwide impact. The Board of Editors is international in representation.