2017
DOI: 10.1007/s11589-017-0195-2
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Real-time numerical shake prediction and updating for earthquake early warning

Abstract: Ground motion prediction is important for earthquake early warning systems, because the region's peak ground motion indicates the potential disaster. In order to predict the peak ground motion quickly and precisely with limited station wave records, we propose a realtime numerical shake prediction and updating method. Our method first predicts the ground motion based on the ground motion prediction equation after P waves detection of several stations, denoted as the initial prediction. In order to correct the … Show more

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Cited by 4 publications
(4 citation statements)
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“…For example, de Matteis and Convertito (2015) developed a procedure for updating the PGA parameters of a GMM (and hence reducing its associated standard deviation) to account for the specific features of a seismic source and propagation medium, which uses real-time maximum acceleration amplitudes recorded during an event at one-second intervals. Wang et al (2017) proposed a technique for replacing initial PGV estimates from a GMM with more certain real-time amplitude predictions calculated using recorded seismogram envelopes and wave propogation (i.e., radiative transfer) modelling. Hoshiba and Aoki (2015); Kodera et al (2018Kodera et al ( , 2016…”
Section: Ground-shaking Estimationmentioning
confidence: 99%
“…For example, de Matteis and Convertito (2015) developed a procedure for updating the PGA parameters of a GMM (and hence reducing its associated standard deviation) to account for the specific features of a seismic source and propagation medium, which uses real-time maximum acceleration amplitudes recorded during an event at one-second intervals. Wang et al (2017) proposed a technique for replacing initial PGV estimates from a GMM with more certain real-time amplitude predictions calculated using recorded seismogram envelopes and wave propogation (i.e., radiative transfer) modelling. Hoshiba and Aoki (2015); Kodera et al (2018Kodera et al ( , 2016…”
Section: Ground-shaking Estimationmentioning
confidence: 99%
“…Mathematical programing [89,[119][120][121][122][123][124]] Heuristic [125][126][127] Decision analysis [122] Emergency response & relief chain coordination Soft OR [128] Early warning system Earthquake/tsunami prediction and notification Machine learning [129][130][131][132][133][134][135][136] Simulation [137,138]…”
Section: Preparedness Stagementioning
confidence: 99%
“…Machine learning [133][134][135] Earthquake detection Machine learning [136] Early warning lead time and reliability estimation Simulation [137] Ground motion prediction Simulation [138] Seismometer/tsunameter location Mathematical programing [139] Heuristic [140] As seen in Table 10, machine learning is the most commonly used approach in EEWS prediction and performance, comprising 8 (67%) of the 12 studies reviewed here. An example application of machine learning is to reduce false alarms by rapidly and reliably discriminating real earthquake signals from other signals [133][134][135].…”
Section: Reduction Of False Alarm Ratesmentioning
confidence: 99%
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