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Main Authors: Porras, Juan, Pecci, Davide, Bocchini, Gian Maria, Gaviano, Sonja, De Solda, Michele, Tuinstra, Katinka, Lanza, Federica, Tognarelli, Andrea, Stucchi, Eusebio, Grigoli, Francesco
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2312.17688
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author Porras, Juan
Pecci, Davide
Bocchini, Gian Maria
Gaviano, Sonja
De Solda, Michele
Tuinstra, Katinka
Lanza, Federica
Tognarelli, Andrea
Stucchi, Eusebio
Grigoli, Francesco
author_facet Porras, Juan
Pecci, Davide
Bocchini, Gian Maria
Gaviano, Sonja
De Solda, Michele
Tuinstra, Katinka
Lanza, Federica
Tognarelli, Andrea
Stucchi, Eusebio
Grigoli, Francesco
contents Distributed Acoustic Sensing (DAS) is becoming increasingly popular in microseismic monitoring operations. This data acquisition technology converts fiber-optic cables into dense arrays of seismic sensors that can sample the seismic wavefield produced by active or passive sources with a high spatial density, over distances ranging from a few hundred meters to tens of kilometers. However, standard microseismic data analysis procedures have several limitations when dealing with the high spatial (inter-sensor spacing up to sub-meter scale) sampling rates of DAS systems. Here we propose a semblance-based seismic event detection method that fully exploits the high spatial sampling of the DAS data. The detector identifies seismic events by computing waveform coherence of the seismic wavefield along geometrical hyperbolic trajectories for different curvatures and positions of the vertex, which are completely independent from external information (i.e. velocity models). The method detects a seismic event when the coherence values overcome a given threshold and satisfies our clustering criteria. We first validate our method on synthetic data and then apply it to real data from the FORGE geothermal experiment in Utah, USA. Our method detects about two times the number of events obtained with a standard method when applied to 24h of data.
format Preprint
id arxiv_https___arxiv_org_abs_2312_17688
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle A Semblance-based Microseismic Event Detector for DAS Data
Porras, Juan
Pecci, Davide
Bocchini, Gian Maria
Gaviano, Sonja
De Solda, Michele
Tuinstra, Katinka
Lanza, Federica
Tognarelli, Andrea
Stucchi, Eusebio
Grigoli, Francesco
Geophysics
Distributed Acoustic Sensing (DAS) is becoming increasingly popular in microseismic monitoring operations. This data acquisition technology converts fiber-optic cables into dense arrays of seismic sensors that can sample the seismic wavefield produced by active or passive sources with a high spatial density, over distances ranging from a few hundred meters to tens of kilometers. However, standard microseismic data analysis procedures have several limitations when dealing with the high spatial (inter-sensor spacing up to sub-meter scale) sampling rates of DAS systems. Here we propose a semblance-based seismic event detection method that fully exploits the high spatial sampling of the DAS data. The detector identifies seismic events by computing waveform coherence of the seismic wavefield along geometrical hyperbolic trajectories for different curvatures and positions of the vertex, which are completely independent from external information (i.e. velocity models). The method detects a seismic event when the coherence values overcome a given threshold and satisfies our clustering criteria. We first validate our method on synthetic data and then apply it to real data from the FORGE geothermal experiment in Utah, USA. Our method detects about two times the number of events obtained with a standard method when applied to 24h of data.
title A Semblance-based Microseismic Event Detector for DAS Data
topic Geophysics
url https://arxiv.org/abs/2312.17688