Crynodeb
Seismic surveys are widely used to study the properties of glaciers,
basal material and conditions, ice temperature and crystal orientation
fabric. The emerging technology of Distributed Acoustic Sensing (DAS)
uses fibre optic cables as pseudo-seismic receivers,reconstructing
seismic measurements at a higher spatial and temporal resolution than is
possible using traditional geophone deployments. DAS generates large
volumes of data, especially in passive mode, which can be costly in time
and cumbersome to analyse. Machine learning tools provide an effective
means of automatically identifying events within these records, avoiding
a bottleneck in the data analysis process. Here we present initial
trials of machine learning for a borehole-deployed DAS system on Store
Glacier, West Greenland. Data were acquired in July 2019, using a Silixa
iDAS interrogator and a BRUsens fibre optic cable installed in a 1043
m-deep borehole. The interrogator sampled at 4000 Hz, recording both
controlled-source Vertical Seismic Profiles (VSPs), made with
hammer-and-plate source, and a 3-day passive record of cryoseismicity.We
used a Convolutional Neural Network (CNN) to identify seismic events
within the seismic record. A CNN is a deep learning algorithm that uses
a series of convolutional filters to extract features from a
2-dimensional matrix of values. These features are then used to train a
modelthat can recognise objects or patterns within the dataset. CNNs are
a powerful classification tool, widely applied to the analysis of both
images and time series data. Previous research has demonstrated the
ability of CNNs to recognise seismic phases in time series data for
long-rangeearthquake detection, even when the phases are masked by a low
signal-to-noise ratio. For the Store Glacier data, initial results were
obtained using a CNN trained on hand-labelled, uniformly-sized windows.
At present, these windows have been targeted around high signal-to-noise
ratio seismic events in the controlled-source VSPs only. Once trained,
the CNN achieved accuracy of 90% in recognising whether new windows
contained coherent seismicenergy.The next phase of analysis will be to
assess the performance of the CNN when trained and tested on large
passive DAS datasets. The method will then be used for the
identification and flagging of seismic events within the passive record
for interpretation and event location. The identified signals will be
used to provide information on the glacier"s seismic velocity structure,
ice temperature and ice crystal orientation fabric and anisotropy. Basal
reflections were identified and will be used to provide information on
subglacial material properties and conditions of Store Glacier. The
efficiency of the CNN allows detailed insight to be made into the
origins and style of glacier seismicity, facilitating further advantages
of passive DAS instrumentation.
Iaith wreiddiol | Saesneg |
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Dynodwyr Gwrthrych Digidol (DOIs) | |
Statws | Cyhoeddwyd - 01 Ebr 2021 |
Digwyddiad | EGU General Assembly 2021: Gather Online - Online, Vienna, Awstria Hyd: 19 Ebr 2021 → 30 Mai 2021 https://www.egu21.eu |
Cynhadledd
Cynhadledd | EGU General Assembly 2021 |
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Teitl cryno | vEGU21 |
Gwlad/Tiriogaeth | Awstria |
Dinas | Vienna |
Cyfnod | 19 Ebr 2021 → 30 Mai 2021 |
Cyfeiriad rhyngrwyd |