Application of Seismic Array Processing to Earthquake Early Warning

Meng, Lingsen; Allen, R. M.; Ampuero, Jean‐Paul

doi:10.1785/0120130277

Cited by 27 publications

(27 citation statements)

References 38 publications

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“…Second, BP algorithms (such as beamforming) are simple and do not require heavy computations, such as large‐scale matrix inversions or wave‐propagation simulations. Therefore, BP is easily automated (e.g., IRIS BP products) and well suited for implementation in real time for the purpose of rapid seismic hazard assessment or earthquake/tsunami early warning (An & Meng, ; Meng et al, ). Third, since BP does not attempt to deterministically fit seismic waves and relies only on the coherent phase of seismic array signals, it does not require the detailed knowledge of the Green's functions.…”

Section: High‐frequency Distance Metricmentioning

confidence: 99%

A High‐Frequency Distance Metric in Ground‐Motion Prediction Equations Based on Seismic Array Backprojections

Feng

Meng

2018

Geophysical Research Letters

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Typical ground‐motion prediction equations (GMPEs) measure source‐to‐site distances relative to the closest point on the rupture plane (Rrup). However, for megathrust earthquakes (Mw > 8), the oversimplification of the earthquake source characteristics in distance metrics results in significant bias. Recent studies suggest that the high‐frequency (HF) and low‐frequency (LF) energy tend to emanate from different portions of the megathrusts. This phenomenon motivates an alternative distance metric based on the array backprojection imaging technique that effectively captures regions releasing HF energy. Herein, we define an HF distance metric (Rhf) as the distance from the site to the high‐frequency radiation zone. We study five Mw > 7.2 megathrust earthquakes in Japan and Chile and find that Rhf outperforms Rrup in predicting the ground shaking intensity between 0.5 and 4 Hz. We consider Rhf as a complementary measure to conventional GMPE distance metrics and a more accurate ground‐motion predictor in many cases.

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Section: High‐frequency Distance Metricmentioning

confidence: 99%

A High‐Frequency Distance Metric in Ground‐Motion Prediction Equations Based on Seismic Array Backprojections

Feng

Meng

2018

Geophysical Research Letters

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“…Arrays have a variety of applications, particularly when the signal enhancement is a prerequisite to detect seismic events, and in situations where installing and maintaining sparse networks around the source is impractical. Study and monitoring of nuclear and chemical explosions (Baumgardt & Der 1998;Kim et al 1998), volcanic and non-volcanic tremors (Saccorotti & Del Pezzo 2000;La Rocca et al 2008;Ghosh et al 2009), earthquake swarms (Hiemer et al 2012) and real-time monitoring and early warning systems of active faults (Meng et al 2014) are examples of array applications.…”

Section: Introductionmentioning

confidence: 99%

Application based seismological array design by seismicity scenario modelling

Karamzadeh

Heimann

Dahm

2018

Geophysical Journal International

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The design of an array configuration is an important task in array seismology during experiment planning. Often the array response function (ARF), which depends on the relative position of array stations and frequency content of the incoming signals, is used as the array design criterion. In practice, additional constraints and parameters have to be taken into account, for example, land ownership, site-specific noise levels or characteristics of the seismic sources under investigation. In this study, a flexible array design framework is introduced that implements a customizable scenario modelling and optimization scheme by making use of synthetic seismograms. Using synthetic seismograms to evaluate array performance makes it possible to consider additional constraints. We suggest to use synthetic array beamforming as an array design criterion instead of the ARF. The objective function of the optimization scheme is defined according to the monitoring goals, and may consist of a number of subfunctions. The array design framework is exemplified by designing a seven-station small-scale array to monitor earthquake swarm activity in Northwest Bohemia/Vogtland in central Europe. Two subfunctions are introduced to verify the accuracy of horizontal slowness estimation; one to suppress aliasing effects due to possible secondary lobes of synthetic array beamforming calculated in horizontal slowness space and the other to reduce the event's mislocation caused by miscalculation of the horizontal slowness vector. Subsequently, a weighting technique is applied to combine the subfunctions into one single scalar objective function to use in the optimization process.

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“…Given the occurrence of destructive earthquakes in seismically intensive regions, the resultant human and financial losses, and the scientific inability to predict earthquakes, investigations into earthquake early warning systems (EEWSs), and their development are critical requirements. Accordingly, researchers have recently proposed many approaches to improving EEWS performance [1,3,4,12,14,15,17,26,27,29]. Earthquake records generally contain valuable information on seismic sources [20]; records of the first waves of an earthquake contain information on magnitude, and those of second waves carry information on energy [2,12].…”

Section: Introductionmentioning

confidence: 99%

A frequency-based parameter for rapid estimation of magnitude

et al. 2017

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This study introduce a new frequency parameter called s fcwt , which can be used to estimate earthquake magnitude on the basis of the first few seconds of P-waves, using the waveforms of earthquakes occurring in Japan. This new parameter is introduced using continuous wavelet transform as a tool for extracting the frequency contents carried by the first few seconds of P-wave. The empirical relationship between the logarithm of s fcwt within the initial 4 s of a waveform and magnitude was obtained. To evaluate the precision of s fcwt , we also calculated parameters s max p and s c . The average absolute values of observed and estimated magnitude differences (jM est À M obs j) were 0.43, 0.49, and 0.66 units of magnitude, as determined using s max p , s c , and s fcwt , respectively. For earthquakes with magnitudes greater than 6, these values were 0.34, 0.56, and 0.44 units of magnitude, as derived using s max p , s c , and s fcwt , respectively. The s fcwt parameter exhibited more precision in determining the magnitude of moderate-and small-scale earthquakes than did the s c -based approach. For a general range of magnitudes, however, the s max p -based method showed more acceptable precision than did the other two parameters.

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Application of Seismic Array Processing to Earthquake Early Warning

Cited by 27 publications

References 38 publications

A High‐Frequency Distance Metric in Ground‐Motion Prediction Equations Based on Seismic Array Backprojections

A High‐Frequency Distance Metric in Ground‐Motion Prediction Equations Based on Seismic Array Backprojections

Application based seismological array design by seismicity scenario modelling

A frequency-based parameter for rapid estimation of magnitude

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