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Which Picker Fits My Data? A Quantitative Evaluation of Deep Learning Based Seismic Pickers (2022)

Münchmeyer, Jannes ; Woollam, Jack ; Rietbrock, Andreas ; [et al.]

Wiley-AGU

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Publication Date: 2022-02-11

Description: Seismic event detection and phase picking are the base of many seismological workflows. In recent years, several publications demonstrated that deep learning approaches significantly outperform classical approaches, achieving human-like performance under certain circumstances. However, as studies differ in the datasets and evaluation tasks, it is unclear how the different approaches compare to each other. Furthermore, there are no systematic studies about model performance in cross-domain scenarios, that is, when applied to data with different characteristics. Here, we address these questions by conducting a large-scale benchmark. We compare six previously published deep learning models on eight data sets covering local to teleseismic distances and on three tasks: event detection, phase identification and onset time picking. Furthermore, we compare the results to a classical Baer-Kradolfer picker. Overall, we observe the best performance for EQTransformer, GPD and PhaseNet, with a small advantage for EQTransformer on teleseismic data. Furthermore, we conduct a cross-domain study, analyzing model performance on data sets they were not trained on. We show that trained models can be transferred between regions with only mild performance degradation, but models trained on regional data do not transfer well to teleseismic data. As deep learning for detection and picking is a rapidly evolving field, we ensured extensibility of our benchmark by building our code on standardized frameworks and making it openly accessible. This allows model developers to easily evaluate new models or performance on new data sets. Furthermore, we make all trained models available through the SeisBench framework, giving end-users an easy way to apply these models.

Description: This work was supported by the Helmholtz Association Initiative and Networking Fund on the HAICORE@KIT partition. J. Münchmeyer acknowledges the support of the Helmholtz Einstein International Berlin Research School in Data Science (HEIBRiDS). The authors thank the Impuls-und Vernetzungsfonds of the HGF to support the REPORT-DL project under the grant agreement ZT-I-PF-5-53. This work was also partially supported by the project INGV Pianeta Dinamico 2021 Tema 8 SOME (CUP D53J1900017001) funded by Italian Ministry of University and Research “Fondo finalizzato al rilancio degli investimenti delle amministrazioni centrali dello Stato e allo sviluppo del Paese, legge 145/2018.” Open access funding enabled and organized by Projekt DEAL.

Description: Published

Description: e2021JB023499

Description: 3T. Fisica dei terremoti e Sorgente Sismica

Description: JCR Journal

Keywords: seismic phase recognition ; deep learnig ; 04.06. Seismology

Repository Name: Istituto Nazionale di Geofisica e Vulcanologia (INGV)

Type: article

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Rapid prediction of ground shaking intensity with Graph Neural Networks (2023)

Bloemheuvel, Stefan ; van den Hoogen, Jurgen ; Jozinović, Dario ; [et al.]

PUBLISHING Conspress & editors

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Publication Date: 2023-01-27

Description: Rapid accurate prediction of strong ground shaking can be crucial for earthquake early warning. Recently, machine learning (ML), with its advances in Deep Learning (DL), has shown great potential in analysing seismic waveforms. More specifically, when using the data acquired by a seismic network, the incorporation of additional information consisting of the network station positioning into the DL model has been found beneficial to improve the accuracy of the ground motion predictions (Jozinović et al., 2022). Such spatial information can be exploited thoroughly by adopting graph structures, along with the seismic waveforms. Recent advances in adapting DL to graphs have shown promising potential in various graph- related tasks. However, these methods have not been completely adapted for seismological tasks. In this work, we advance an architecture capable of processing a set of seismic time series acquired by a network of stations using the benefits of Graph Neural Networks (GNNs) (see Fig. 1). The objective of the study is the rapid determination of the ground motion (PGA, PGV, and SA 0.3s, 1s and 3s) at farther stations that have not been yet reached by the strong ground shaking by availing of the first signals recorded at the stations close to the epicentre. The work builds upon the GNN approach proposed in Bloemheuvel et al. (2022) and incorporates transfer learning, see Jozinović et al. (2022). We apply the methodology to two datasets having very different source-receiver geometries sited in central Italy (CI, Jozinović et al., 2020, Jozinović et al., 2022) and in north-western central Italy (CW), respectively (Fig. 2). The two datasets have already been the object of similar studies using convolutional neural networks which serve as baselines for comparison. We find that the GNNs are highly suited for the analysis of seismic data from a set of stations and show improvement when compared to the previous work (Bloemheuvel et al., 2022 and Jozinović et al., 2022). We exemplify the early warning capabilities of the proposed approach.

Description: Interreg North-West Europe program (Interreg NWE), project Di-Plast - Digital Circular Economy for the Plastics Industry (NWE729), and partially funded by the INGV project Pianeta Dinamico 2021 Tema 8 SOME (grant no. CUP D53J1900017001) funded by the Italian Ministry of University and Research “Fondo finalizzato al rilancio degli investimenti delle amministrazioni centrali dello Stato e allo sviluppo del Paese, legge 145/2018” and by the European Union’s Horizon 2020 research and innovation program (grant no. 821115), Real-time Earthquake Risk Reduction for a Resilient Europe (RISE).

Description: Published

Description: 4300-4306

Description: 8T. Sismologia in tempo reale e Early Warning Sismico e da Tsunami

Description: N/A or not JCR

Keywords: Graph Neural Networks, Seismogram, Convolutional Neural Networks, Sensors, Regression, Earthquake Ground Motion, Seismic Network, EEW ; 04.06. Seismology