Seismic monitoring leveraging existing telecom infrastructure at the SDASA: Active, passive, and ambient-noise analysis

Martin, Eileen; Castillo, Chris M.; Cole, Steve; Sawasdee, Paphop Stock; Yuan, Siyuan; Clapp, Robert G.; Karrenbach, Martin; Biondi, Biondo

doi:10.1190/tle36121025.1

Cited by 89 publications

(46 citation statements)

References 11 publications

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“…The Stanford DAS array recorded and stored continuous data from 620 independent seismic channels at a frequency of 50 samples per second with 7.14 m gauge length and 8.16 m channel spacing. Through this experiment Martin et al () showed that DAS technology can be used to record seismic data directly from a free‐floating cable in a horizontal PVC conduit. Furthermore, by analyzing adjacent earthquakes on nearby faults, Biondi et al () demonstrated that signals recorded using this cable provide repeatable and reliable ground motion measurements.…”

Section: Methodsmentioning

confidence: 99%

“…We apply passive Rayleigh wave interferometry to the DAS channels along Via Ortega using 1 year of continuous data starting from early September 2016 (Martin et al, ). Only a collinear sub‐array is used for interferometry because that virtual‐source configuration is expected to yield Rayleigh waves (Martin et al, ).…”

Section: Methodsmentioning

confidence: 99%

“…We window of continuous signal into 5 min intervals with 50% overlap, band‐passed filter from 0.5 to 24 Hz, perform a 1‐bit normalization, and then stack hourly cross correlations. After saving each hour's average cross correlations throughout the week, we normalized them by their L1 norms and stack them for each month, yielding a series of virtual‐source response estimates (Martin et al, ).…”

Section: Methodsmentioning

confidence: 99%

“…Our approach can be used to extract almost continuous

V_{S}

profiles along a fiber cable network and could eventually be repeated through time at little additional cost. We illustrate our method using the Stanford DAS array (Figure ), which consists of a fiber cable laying in an air‐filled PVC conduit (no clamping or cementing) (Martin et al, ). Our results suggest that if a standard velocimeter (i.e, seismometer) is close to a DAS array, similar analysis could be performed on many existing fiber‐optic networks around the world.…”

Section: Introductionmentioning

confidence: 99%

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Urban Seismic Site Characterization by Fiber‐Optic Seismology

et al. 2020

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Accurate ground motion prediction requires detailed site effect assessment, but in urban areas where such assessments are most important, geotechnical surveys are difficult to perform, limiting their availability. Distributed acoustic sensing (DAS) offers an appealing alternative by repurposing existing fiber‐optic cables, normally employed for telecommunication, as an array of seismic sensors. We present a proof‐of‐concept demonstration by using DAS to produce high‐resolution maps of the shallow subsurface with the Stanford DAS array, California. We describe new methods and their assumptions to assess H/V spectral ratio—a technique widely used to estimate the natural frequency of the soil—and to extract Rayleigh wave dispersion curves from ambient seismic field. These measurements are jointly inverted to provide models of shallow seismic velocities and sediment thicknesses above bedrock in central campus. The good agreement with an independent survey validates the methodology and demonstrates the power of DAS for microzonation.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

“…Our approach can be used to extract almost continuous

V_{S}

Section: Introductionmentioning

confidence: 99%

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Urban Seismic Site Characterization by Fiber‐Optic Seismology

et al. 2020

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“…Since September 2016, the Stanford Fiber Optic Seismic Observatory has been continuously collecting passive seismic data at a rate of 50 samples per second at 4 meter channel spacing on 2.5 km of fiber optic cables in existing telecommunications conduits underneath the Stanford University campus (Martin et al, 2018). It is the longest running, ultra-dense urban seismic experiment, and has been used to ambient noise interferometry, earthquake detection (Lindsey et al, 2017), and active seismic acquisition (Martin et al, 2017). An array with similar settings that covered 1000 km (a reasonable length for an array covering a major metropolitan area in an earthquake-prone region) would collect 0.5 petabytes of data annually, so some form of lossy compression will need to be part of any scalable plan for future DAS data archiving.…”

Section: Application To Passive Das Datamentioning

confidence: 99%

A Scalable Algorithm for Cross-correlations of Compressed Ambient Seismic Noise

Martin¹

2019

Preprint

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Companies and academic geophysicists are increasingly collecting continuous seismic data on denser arrays, and are looking to a variety of lossy compression methods to store and quickly access this data. Some researchers turn to ambient noise interferometry for low-cost near-surface imaging to avoid to cost and permitting required for active source experiments, but the computation can be very expensive. For each window of time, typical ambient noise interferometry scales as the product of the number of time samples per window and the number of sensors squared. This paper proposes a new algorithm for data stored in a low-rank matrix factorized form, performing interferometry in compressed form, and separating scalability in sensors from time samples. Application to real data shows nearly identical results at orders of magnitude lower cost. The algorithm can be extended to tensor compressions, averaging cross-correlations over many time windows.

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