Forecasting Tsunami Hazards Using Ocean Bottom Sensor Data and Classification Predictive Modeling

Forecasting Tsunami Hazards Using Ocean Bottom Sensor Data and Classification Predictive Modeling

This study compares the results of analyzing tsunami simulations that are based on two approaches of characterizing earthquake slips, i.e., uniform (simplistic) and heterogeneous (complex) distributions. The aim of this study is to compare how heterogeneous and uniform distributed data affect the cl...

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Bibliographic Details
Main Author: Yao Li
Format: Article
Language:English
Published: MDPI AG 2023-03-01
Series:Proceedings
Subjects:
tsunami forecast classification
ocean bottom sensor
stochastic tsunami simulation
Online Access:https://www.mdpi.com/2504-3900/87/1/7
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Summary:This study compares the results of analyzing tsunami simulations that are based on two approaches of characterizing earthquake slips, i.e., uniform (simplistic) and heterogeneous (complex) distributions. The aim of this study is to compare how heterogeneous and uniform distributed data affect the classification of maximum near-shore tsunami amplitudes. Due to the lack of historical earthquake and tsunami data to train the forecasting model, 4000 stochastic tsunami simulations are employed. The focused location is Iwanuma, Japan, where an ocean bottom sensors (OBS) S-net network has been deployed. Multiple linear regression combined with the Akaike information criterion (AIC) is applied to the simulated off-shore wave amplitude data to fit the model. The estimated tsunami amplitude is classified into four levels of warning classes. The performance of the models is quantified by the accuracy of the confusion matrices and is compared with the base model, which only uses earthquake information. The forecasting accuracy can be improved by 30% when the wave amplitude data are used as additional information. The heterogeneous slip-based model reaches a higher accuracy than the uniform-slip based model. The results of this study are particularly valuable for setting up an OBS-based system for monitoring the physical phenomena of tsunamis, and choosing heterogeneous as a preferable slip distribution when tsunami events are simulated.
ISSN:2504-3900

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