BPMF:用于地震自动探测和定位的反向投影和匹配过滤工作流程

IF 2.6 3区 地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS
É. Beaucé, W. Frank, L. Seydoux, Piero Poli, Nathan Groebner, R. D. van der Hilst, Michel Campillo
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引用次数: 0

摘要

我们介绍了BPMF(反向投影和匹配过滤)——一个为地震检测和定位设计的完整且完全自动化的工作流,并以Python包的形式发布。该工作流程可以创建完整的低震级地震目录,而无需或很少使用对研究区域的先验知识。BPMF使用地震波场反投影方法构造初始地震目录,然后通过匹配滤波进行密集化。BPMF集成了最新的机器学习工具,以补充基于物理的技术,并改进地震的检测和定位。特别是,BPMF提供了一个灵活的框架,在这个框架中,机器学习检测器和反向投影可以和谐地结合在一起,有效地将单站检测器转换为多站检测器。BPMF的模块化使用户能够控制工作流中机器学习工具的贡献。计算密集型任务(反向投影和匹配过滤)是用Python代码包装的C和CUDA-C例程执行的。利用低级、快速的编程语言和图形处理单元加速使BPMF能够有效地处理大型数据集。在这里,我们首先总结了方法并描述了应用程序编程接口。然后,我们通过在加州里奇克莱斯特地区长达10年的应用,说明了BPMF表征微震活动的能力。最后,我们讨论了工作流在数值资源下的运行时缩放及其在不同构造环境和不同问题上的通用性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
BPMF: A Backprojection and Matched-Filtering Workflow for Automated Earthquake Detection and Location
We introduce BPMF (backprojection and matched filtering)—a complete and fully automated workflow designed for earthquake detection and location, and distributed in a Python package. This workflow enables the creation of comprehensive earthquake catalogs with low magnitudes of completeness using no or little prior knowledge of the study region. BPMF uses the seismic wavefield backprojection method to construct an initial earthquake catalog that is then densified with matched filtering. BPMF integrates recent machine learning tools to complement physics-based techniques, and improve the detection and location of earthquakes. In particular, BPMF offers a flexible framework in which machine learning detectors and backprojection can be harmoniously combined, effectively transforming single-station detectors into multistation detectors. The modularity of BPMF grants users the ability to control the contribution of machine learning tools within the workflow. The computation-intensive tasks (backprojection and matched filtering) are executed with C and CUDA-C routines wrapped in Python code. This leveraging of low-level, fast programming languages and graphic processing unit acceleration enables BPMF to efficiently handle large datasets. Here, we first summarize the methodology and describe the application programming interface. We then illustrate BPMF’s capabilities to characterize microseismicity with a 10 yr long application in the Ridgecrest, California area. Finally, we discuss the workflow’s runtime scaling with numerical resources and its versatility across various tectonic environments and different problems.
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来源期刊
Seismological Research Letters
Seismological Research Letters 地学-地球化学与地球物理
CiteScore
6.60
自引率
12.10%
发文量
239
审稿时长
3 months
期刊介绍: Information not localized
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