Abstract

In order to solve the existing problems of easy spatiotemporal information loss and low forecast accuracy in traditional radar echo nowcasting, this paper proposes an encoding-forecasting model (3DCNN-BCLSTM) combining 3DCNN and bi-directional convolutional long short-term memory. The model first constructs dimensions of input data and gets 3D tensor data with spatiotemporal features, extracts local short-term spatiotemporal features of radar echoes through 3D convolution networks, then utilizes constructed bi-directional convolutional LSTM to learn global long-term spatiotemporal feature dependencies, and finally realizes the forecast of echo image changes by forecasting network. This structure can capture the spatiotemporal correlation of radar echoes in continuous motion fully and realize more accurate forecast of moving trend of short-term radar echoes within a region. The samples of radar echo images recorded by Shenzhen and Hong Kong meteorological stations are used for experiments, the results show that the critical success index (CSI) of this proposed model for eight predicted echoes reaches 0.578 when the echo threshold is 10 dBZ, the false alarm ratio (FAR) is 20% lower than convolutional LSTM network (ConvLSTM), and the mean square error (MSE) is 16% lower than the real-time optical flow by variational method (ROVER), which outperforms the current state-of-the-art radar echo nowcasting methods.

Highlights

  • Radar echo nowcasting is a crucial method in the field of atmospheric science

  • The spatiotemporal information of continuous multi-frame image sequences is transmitted by bi-directional convolutional long short-term memory (LSTM), which has been effectively fused in the global long-term range

  • In order to verify the effectiveness of this 3DCNN-BCLSTM radar echo nowcasting model, pixel-level mean square error (MSE), the number of network parameters, critical success index (CSI), probability of detection (POD), and false alarm ratio (FAR) are commonly used by the meteorological community [36]

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Summary

Introduction

Radar echo nowcasting is a crucial method in the field of atmospheric science. The goal of this task is to carry out prediction timely and accurately for weather conditions of local areas in a relatively short period (such as 0–2 h) in the future [1,2,3]. In order to achieve a more accurate nowcasting result, it first introduces a 3D convolution network that is usually used for feature extraction of continuous video frames This can preserve the feature information of motion in the temporal dimension and extract local short-term spatiotemporal features of consecutive images more effectively, which enters the bi-directional convolutional LSTM networks. Frame radar echo images; the prediction accuracy is improved effectively

Construction of 3D Spatiotemporal Data
Bi‐Directional
EncodingFforecasting Network Structure
Dataset
Network Training
Experimental Quantitative Analysis
Evaluation Analysis of Convolution Kernel Size
Evaluation Analysis of Network Layers
Evaluation Analysis of Performances of Various Models
Experimental
The prediction of advection advectionmotion motion radar nowcasting
Experimental Qualitative Analysis
The prediction of stable advection for radarprocess echo nowcasting
Conclusions

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