Machine-Learning-Based Surface Ground-Motion Prediction Models for South Korea with Low-to-Moderate Seismicity

Seo, Hwanwoo; Kim, Jisong; Kim, Byungmin

doi:10.1785/0120210244

Cited by 18 publications

(5 citation statements)

References 51 publications

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“…An advantage of ML models over conventional GMPEs is that nonparametric ML methods can learn the functions of ground-motion models directly from data without assuming regression equations, resulting in a more accurate and useful predictor within the range of training data. Some studies have reported that ML prediction models have higher accuracy than the existing GMPEs (Khosravikia and Clayton 2021;Oana et al 2022;Seo et al 2022). Khosravikia and Clayton (2021) reported that when sufficient data are available, the ML prediction models provide more accurate estimates than the conventional linear regression-based method.…”

Section: Prediction Of Ground-motion Intensity From Featuresmentioning

confidence: 99%

Recent advances in earthquake seismology using machine learning

Kubo,

Naoi,

Kano

2024

Earth Planets Space

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Given the recent developments in machine-learning technology, its application has rapidly progressed in various fields of earthquake seismology, achieving great success. Here, we review the recent advances, focusing on catalog development, seismicity analysis, ground-motion prediction, and crustal deformation analysis. First, we explore studies on the development of earthquake catalogs, including their elemental processes such as event detection/classification, arrival time picking, similar waveform searching, focal mechanism analysis, and paleoseismic record analysis. We then introduce studies related to earthquake risk evaluation and seismicity analysis. Additionally, we review studies on ground-motion prediction, which are categorized into four groups depending on whether the output is ground-motion intensity or ground-motion time series and the input is features (individual measurable properties) or time series. We discuss the effect of imbalanced ground-motion data on machine-learning models and the approaches taken to address the problem. Finally, we summarize the analysis of geodetic data related to crustal deformation, focusing on clustering analysis and detection of geodetic signals caused by seismic/aseismic phenomena. Graphical Abstract

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Section: Prediction Of Ground-motion Intensity From Featuresmentioning

confidence: 99%

Recent advances in earthquake seismology using machine learning

Kubo,

Naoi,

Kano

2024

Earth Planets Space

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“…We used Scikitlearn (Pedregosa et al, 2011) for the implementation of Gradient Boosting (GB) and Random Forest (RF) algorithms and the Tensorflow (Abadi et al, 2016) for the Artificial Neural Network (ANN) algorithm. Note that comparing these three algorithms is a popular practice in the field of machine learning-based studies (e.g., Krauss et al, 2017;Kim et al, 2020;Jun, 2021;Seo et al, 2022). These methods represent different types of machine learning algorithms and have been proven effective in handling complicated relationships within various datasets.…”

Section: Machine Learning (Ml) Modelsmentioning

confidence: 99%

Machine-learning models to predict P- and S-wave velocity profiles for Japan as an example

Kim,

Kang,

Kim

2023

Front. Earth Sci.

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Wave velocity profiles are significant for various fields, including rock engineering, petroleum engineering, and earthquake engineering. However, direct measurements of wave velocities are often constrained by time, cost, and site conditions. If wave velocity measurements are unavailable, they need to be estimated based on other known proxies. This paper proposes machine learning (ML) approaches to predict the compression and shear wave velocities (VP and VS, respectively) in Japan. We utilize borehole databases from two seismograph networks of Japan: Kyoshin Network (K-NET) and Kiban Kyoshin Network (KiK-net). We consider various factors such as depth, N-value, density, slope angle, elevation, geology, soil/rock type, and site coordinates. We use three ML techniques: Gradient Boosting (GB), Random Forest (RF), and Artificial Neural Network (ANN) to develop predictive models for both VP and VS and evaluate the performances of the models based on root mean squared errors and the five-fold cross-validation method. The GB-based model provides the best estimation of VP and VS for both seismograph networks. Among the considered factors, the depth, standard penetration test (SPT) N-value, and density have the strongest influence on the wave velocity estimation for K-NET. For KiK-net, the depth and site longitude have the strongest influence. The study confirms the applicability of commonly used machine-learning techniques in predicting wave velocities, and implies that exploring additional factors will enhance the performance.

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“…In this study, we applied deep learning technologies for immediate forecasting of distant LP ground motions from seismic observations near the epicenter, anticipating the feasibility of a computing facility to analyze real‐time observation data. Previous studies based on deep learning have successfully predicted peak ground accelerations (PGA) and peak ground velocities (PGV) of distant target locations (e.g., Derras et al., 2012; Zhang et al., 2021) and the distribution of shaking intensity over a wide area (e.g., Kubo et al., 2020; Lilienkamp et al., 2022; Seo et al., 2022) using immediately estimated source parameters (magnitude (Mw), location, and depth) from observed waveforms. Research is underway to forecast the PGA, PGV (e.g., Jozinović et al., 2020, 2022), and velocity response spectrum (Taya & Furumura, 2022) of target locations from observed waveforms without estimating source parameters.…”

Section: Introductionmentioning

confidence: 99%

An Early Forecast of Long‐Period Ground Motions of Large Earthquakes Based on Deep Learning

Furumura

Oishi

2023

Geophysical Research Letters

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Long-period (LP) seismic waves (approximately 2-10 s), radiated from the sources of large earthquakes, propagate over several hundred kilometers without much weakening due to their long wavelength and produce large-amplitude and long-duration shaking in distant basins. Large-scale structures, such as skyscrapers and oil storage tanks, might resonate with this LP ground motion and suffer damage. During the 2003 Tokachi-oki earthquake (Mw 8.0), the floating roof of an oil storage tank in the Yufutsu basin of Hokkaido, 150 km from the epicenter, was sloshed by LP ground motion, resulting in damage and a fire (Koketsu et al., 2005). When the 2011 Off the Pacific coast of Tohoku earthquake (Tohoku-oki earthquake, Mw 9.0) occurred, high-rise buildings in the Kanto (Tokyo) and Osaka basins, more than 400-800 km away, were severely shaken, causing facility damages such as falling ceiling material and tangled elevator cables (Building Research Institute, 2012). For safety, a system to forecast and warn of the occurrence of LP ground motion is needed in large basins, using the lead time of the shaking arrival from distant large earthquakes.In this study, we applied deep learning technologies for immediate forecasting of distant LP ground motions from seismic observations near the epicenter, anticipating the feasibility of a computing facility to analyze real-time observation data. Previous studies based on deep learning have successfully predicted peak ground accelerations (PGA) and peak ground velocities (PGV) of distant target locations (e.g., Derras et al., 2012; Zhang et al., 2021) and the distribution of shaking intensity over a wide area (e.g., Kubo et al., 2020;Lilienkamp et al., 2022; Seo et al., 2022) using immediately estimated source parameters (magnitude (Mw), location, and depth) from observed waveforms. Research is underway to forecast the PGA, PGV (e.g., Jozinović et al., 2020Jozinović et al., , 2022, and velocity response spectrum (Taya & Furumura, 2022) of target locations from observed waveforms without estimating source parameters.

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Machine-Learning-Based Surface Ground-Motion Prediction Models for South Korea with Low-to-Moderate Seismicity

Cited by 18 publications

References 51 publications

Recent advances in earthquake seismology using machine learning

Recent advances in earthquake seismology using machine learning

Machine-learning models to predict P- and S-wave velocity profiles for Japan as an example

An Early Forecast of Long‐Period Ground Motions of Large Earthquakes Based on Deep Learning

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