A Spatiotemporal Model for Global Earthquake Prediction Based on Convolutional LSTM
Zhongchang Zhang, Yubing Wang
Abstract
Deep learning has been widely used to address earthquake prediction as a time series problem. However, existing methods are often limited to local areas and lack sufficient consideration of spatial correlation and resolution. To address these limitations, we propose a new approach that uses a sequence-to-sequence framework model with a convolutional LSTM network (ConvLSTM) to learn both temporal and spatial correlations of seismic data on a global scale for high-resolution earthquake prediction. The approach offers several advantages over existing methods. First, we create a spatiotemporal series dataset consisting of global high-resolution seismic maps. Second, we address the problem of spatial distortion in global seismic maps by randomly rotating the seismic maps. Third, we incorporate a weighted MSE-MAE loss function that considers the weighted map, which helps the approach focus on areas where earthquakes may occur. Finally, our approach can deal with a four-dimensional dataset that integrates not only the magnitude but also the depth of every earthquake. The results demonstrate that our approach outperforms existing methods, achieving an average recall of 51.83% and precision of 64.54% on the test set when the minimum pixel unit is 72.92km × 67.71km (longitude × latitude). The results indicate that our approach can effectively predict earthquakes with higher resolution and accuracy than previous methods, offering valuable insights into the spatiotemporal patterns of seismic activity at a global scale.