深层地震的深度学习:汤加俯冲带 OBS 观测的启示

Ziyi Xi, S. S. Wei, Weiqiang Zhu, G. Beroza, Yaqi Jie, N. Saloor
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引用次数: 0

摘要

机器学习在地震学中的应用大大提高了我们在大型地震数据档案中探测地震的能力。这些工作大多集中在大陆浅层地震上,但在这里,我们介绍了一种基于深度学习的集成工作流程,用于探测汤加俯冲带的海洋底部地震仪(OBS)临时阵列和陆基台站记录的深层地震。我们开发了一种新的相位选取器 PhaseNet-TF,用于检测和选取时频域的 P 波和 S 波到达。频域信息对于分析 OBS 数据,尤其是水平分量至关重要,因为它们在某些频段受到洋底流信号和其他噪声源的污染。与前代 PhaseNet 相比,PhaseNet-TF 在拾取 OBS 和陆地站的 S 波方面表现出更好的性能。使用改进的高斯混合模型关联器 GaMMA-1D 对预测的相位进行关联,然后使用双差分软件包 teletomoDD 进行重定位。我们采用半监督学习方法,通过迭代完善标记数据和重新训练 PhaseNet-TF 来进一步提高模型性能。这种方法有效地抑制了误判,并显著提高了对小地震的检测能力。与人工分析的参考目录相比,新的汤加深层地震目录包含的地震事件多出 10 倍以上。这份经深度学习增强的地震目录以前所未有的细节揭示了汤加的地震活动,并更好地界定了中等深度双震带的横向范围以及 4 个大型深焦距地震相对于背景地震的位置。它还为破译深层地震机制、完善层析成像模型和了解俯冲过程提供了新的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Deep Learning for Deep Earthquakes: Insights from OBS Observations of the Tonga Subduction Zone
Applications of machine learning in seismology have greatly improved our capability of detecting earthquakes in large seismic data archives. Most of these efforts have been focused on continental shallow earthquakes, but here we introduce an integrated deep-learning-based workflow to detect deep earthquakes recorded by a temporary array of ocean-bottom seismographs (OBSs) and land-based stations in the Tonga subduction zone. We develop a new phase picker, PhaseNet-TF, to detect and pick P- and S-wave arrivals in the time-frequency domain. The frequency-domain information is critical for analyzing OBS data, particularly the horizontal components, because they are contaminated by signals of ocean-bottom currents and other noise sources in certain frequency bands. PhaseNet-TF shows a much better performance in picking S waves at OBSs and land stations compared to its predecessor PhaseNet. The predicted phases are associated using an improved Gaussian Mixture Model Associator GaMMA-1D and then relocated with a double-difference package teletomoDD. We further enhance the model performance with a semi-supervised learning approach by iteratively refining labelled data and retraining PhaseNet-TF. This approach effectively suppresses false picks and significantly improves the detection of small earthquakes. The new catalogue of Tonga deep earthquakes contains more than 10 times more events compared to the reference catalogue that was analyzed manually. This deep-learning-enhanced catalogue reveals Tonga seismicity in unprecedented detail, and better defines the lateral extent of the double-seismic zone at intermediate depths and the location of 4 large deep-focus earthquakes relative to background seismicity. It also offers new potential for deciphering deep earthquake mechanisms, refining tomographic models, and understanding of subduction processes.
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