ArrayNet: A Combined Seismic Phase Classification and Back-Azimuth Regression Neural Network for Array Processing Pipelines

IF 2.6 3区 地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS
A. Köhler, E. B. Myklebust
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引用次数: 1

Abstract

Array processing is an integral part of automatic seismic event detection pipelines for measuring apparent velocity and backazimuth of seismic arrivals. Both quantities are usually measured under the plane-wave assumption, and are essential to classify the phase type and to determine the direction toward the event epicenter. However, structural inhomogeneities can lead to deviations from the plane-wave model, which must be taken into account for phase classification and back-azimuth estimation. We suggest a combined classification and regression neural network, which we call ArrayNet, to determine the phase type and backazimuth directly from the arrival-time differences between all combinations of stations of a given seismic array without assuming a plane-wave model. ArrayNet is trained using regional P- and S-wave arrivals of over 30,000 seismic events from reviewed regional bulletins in northern Europe from the past three decades. ArrayNet models are generated and trained for each of the ARCES, FINES, and SPITS seismic arrays. We observe excellent performance for the seismic phase classification (up to 99% accuracy), and the derived back-azimuth residuals are significantly improved in comparison with traditional array processing results using the plane-wave assumption. The SPITS array in Svalbard exhibits particular issues when it comes to array processing in the form of high apparent seismic velocities and a multitude of frost quake signals inside the array, and we show how our new approach better handles these obstacles. Furthermore, we demonstrate the performance of ArrayNet on 20 months of continuous phase detections from the ARCES array and investigate the results for a selection of regional seismic events of interest. Our results demonstrate that automatic event detection at seismic arrays can be further enhanced using a machine learning approach that takes advantage of the unique array data recorded at these stations.
ArrayNet:用于阵列处理管道的地震相位分类和反向方位回归神经网络
阵列处理是地震事件自动检测管道的重要组成部分,用于测量地震到达的视速度和反方位角。这两个量通常是在平面波假设下测量的,对于区分相位类型和确定朝向事件震中的方向至关重要。然而,结构的不均匀性会导致与平面波模型的偏差,这在相位分类和反向方位估计中必须考虑到。我们提出了一种组合分类和回归神经网络,我们称之为ArrayNet,可以在不假设平面波模型的情况下,直接从给定地震阵列所有台站组合的到达时间差异中确定相位类型和反方位角。ArrayNet是利用过去三十年来北欧区域公报中超过30,000次地震事件的区域P波和s波到达进行训练的。为ARCES、fine和SPITS地震阵列生成和训练ArrayNet模型。我们观察到该方法在地震相位分类方面具有优异的性能(准确率高达99%),并且与使用平面波假设的传统阵列处理结果相比,得到的反向方位残差有了显著提高。斯瓦尔巴群岛的SPITS阵列在阵列处理方面表现出特殊的问题,例如高表观地震速度和阵列内大量的霜冻地震信号,我们展示了我们的新方法如何更好地处理这些障碍。此外,我们展示了ArrayNet在ARCES阵列20个月连续相位检测中的性能,并研究了一系列感兴趣的区域地震事件的结果。我们的研究结果表明,利用机器学习方法可以进一步增强地震阵列的自动事件检测,该方法利用了这些台站记录的独特阵列数据。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Bulletin of the Seismological Society of America
Bulletin of the Seismological Society of America 地学-地球化学与地球物理
CiteScore
5.80
自引率
13.30%
发文量
140
审稿时长
3 months
期刊介绍: The Bulletin of the Seismological Society of America, commonly referred to as BSSA, (ISSN 0037-1106) is the premier journal of advanced research in earthquake seismology and related disciplines. It first appeared in 1911 and became a bimonthly in 1963. Each issue is composed of scientific papers on the various aspects of seismology, including investigation of specific earthquakes, theoretical and observational studies of seismic waves, inverse methods for determining the structure of the Earth or the dynamics of the earthquake source, seismometry, earthquake hazard and risk estimation, seismotectonics, and earthquake engineering. Special issues focus on important earthquakes or rapidly changing topics in seismology. BSSA is published by the Seismological Society of America.
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