Novel Intelligent Spatiotemporal Grid Earthquake Early-Warning Model

The integration analysis of multi-type geospatial information poses challenges to existing spatiotemporal data organization models and analysis models based on deep learning. For earthquake early warning, this study proposes a novel intelligent spatiotemporal grid model based on GeoSOT (SGMG-EEW) for feature fusion of multi-type geospatial data. This model includes a seismic grid sample model (SGSM) and a spatiotemporal grid model based on a three-dimensional group convolution neural network (3DGCNN-SGM). The SGSM solves the problem concerning that the layers of different data types cannot form an ensemble with a consistent data structure and transforms the grid representation of data into grid samples for deep learning. The 3DGCNN-SGM is the first application of group convolution in the deep learning of multi-source geographic information data. It avoids direct superposition calculation of data between different layers, which may negatively affect the deep learning analysis model results. In this study, taking the atmospheric temperature anomaly and historical earthquake precursory data from Japan as an example, an earthquake early warning verification experiment was conducted based on the proposed SGMG-EEW. Five groups of control experiments were designed, namely with the use of atmospheric temperature anomaly data only, use of historical earthquake data only, a non-group convolution control group, a support vector machine control group, and a seismic statistical analysis control group. The results showed that the proposed SGSM is not only compatible with the expression of a single type of spatiotemporal data but can also support multiple types of spatiotemporal data, forming a deep-learning-oriented data structure. Compared with the traditional deep learning model, the proposed 3DGCNN-SGM is more suitable for the integration analysis of multiple types of spatiotemporal data.

[1]  Alicia Troncoso Lora,et al.  Medium–large earthquake magnitude prediction in Tokyo with artificial neural networks , 2015, Neural Computing and Applications.

[2]  M. Herold,et al.  Robust monitoring of small-scale forest disturbances in a tropical montane forest using Landsat time series , 2015 .

[3]  Chengqi Cheng,et al.  Multiscale Spatial Polygonal Object Granularity Factor Matching Method Based on BPNN , 2021, ISPRS Int. J. Geo Inf..

[4]  Shunji Murai Can we predict earthquakes with GPS data? , 2010, Int. J. Digit. Earth.

[5]  Timothy E. Dawson,et al.  Uniform California Earthquake Rupture Forecast, Version 2 (UCERF 2) , 2009 .

[6]  N. A. Naqvi,et al.  Atmospheric anomalies associated with Mw>6.0 earthquakes in Pakistan and Iran during 2010–2017 , 2019, Journal of Atmospheric and Solar-Terrestrial Physics.

[7]  Alicia Troncoso Lora,et al.  Improving Earthquake Prediction with Principal Component Analysis: Application to Chile , 2015, HAIS.

[8]  Khawaja M. Asim,et al.  Earthquake magnitude prediction in Hindukush region using machine learning techniques , 2016, Natural Hazards.

[9]  Francisco Martínez-Álvarez,et al.  Neural networks to predict earthquakes in Chile , 2013, Appl. Soft Comput..

[10]  Francisco Martínez-Álvarez,et al.  Determining the best set of seismicity indicators to predict earthquakes. Two case studies: Chile and the Iberian Peninsula , 2013, Knowl. Based Syst..

[11]  J. Gong,et al.  An on-demand scheme driven by the knowledge of geospatial distribution for large-scale high-resolution impervious surface mapping , 2021 .

[12]  E. Ivo Alves,et al.  Earthquake Forecasting Using Neural Networks: Results and Future Work , 2006 .

[13]  Dino Ienco,et al.  Combining Sentinel-1 and Sentinel-2 Satellite Image Time Series for land cover mapping via a multi-source deep learning architecture , 2019 .

[14]  J. T. Kuo,et al.  Statistical prediction of the occurrence of maximum magnitude earthquakes : 13F, 4T, 12R Seismol. Soc. Amer. Bull. V64, N2, April, 1974, P393–414 , 1974 .

[15]  Orhan Altan,et al.  Integrating Remote Sensing and a Markov-FLUS Model to Simulate Future Land Use Changes in Hokkaido, Japan , 2021, Remote. Sens..

[16]  Yu-Chen Song,et al.  The influence of distance weight on the inverse distance weighted method for ore-grade estimation , 2021, Scientific Reports.

[17]  Mohammad Reza Mosavi,et al.  Interevent times estimation of major and continuous earthquakes in Hormozgan region based on radial basis function neural network , 2016 .

[18]  Wen Zhou,et al.  The deterministic dendritic cell algorithm with Haskell in earthquake magnitude prediction , 2020, Earth Science Informatics.

[19]  Wang Ten A Sensor of Ground Temperature and Its Application in Big Earthquake Monitoring , 2014 .

[20]  B. Gutenberg,et al.  Seismicity of the Earth , 1970, Nature.

[21]  Jukka Heikkonen,et al.  Localization in Unstructured Environments: Towards Autonomous Robots in Forests with Delaunay Triangulation , 2020, Remote. Sens..

[22]  Jia Liu,et al.  Change detection based on deep feature representation and mapping transformation for multi-spatial-resolution remote sensing images , 2016 .

[23]  Yutaka Satoh,et al.  Would Mega-scale Datasets Further Enhance Spatiotemporal 3D CNNs? , 2020, ArXiv.

[24]  F. Viégas,et al.  Deep learning of aftershock patterns following large earthquakes , 2018, Nature.

[25]  Mei Li,et al.  Studies on earthquake precursors in China: A review for recent 50 years , 2017 .