TSRC: A Deep Learning Model for Precipitation Short-Term Forecasting over China Using Radar Echo Data

Currently, most deep learning (DL)-based models for precipitation forecasting face two conspicuous issues: the smoothing effect in the precipitation field and the degenerate effect of forecasting precipitation intensity. Therefore, this study proposes “time series residual convolution (TSRC)”, a DL-...

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Bibliographic Details
Published in:Remote sensing (Basel, Switzerland) Switzerland), 2023-01, Vol.15 (1), p.142
Main Authors: Huang, Qiqiao, Chen, Sheng, Tan, Jinkai
Format: Article
Language:English
Subjects:
Agricultural production
Artificial neural networks
Case studies
Deep learning
False alarms
Forecasting
Lead time
Mathematical models
Model testing
Neural networks
Nowcasting
optical flow
Optical flow (image analysis)
Precipitation
precipitation nowcasting
Radar
Radar data
radar echo
Radar echoes
Rain
Rainfall
Rainfall intensity
Smoothing
Typhoons
UNet
Weather forecasting
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Summary:Currently, most deep learning (DL)-based models for precipitation forecasting face two conspicuous issues: the smoothing effect in the precipitation field and the degenerate effect of forecasting precipitation intensity. Therefore, this study proposes “time series residual convolution (TSRC)”, a DL-based convolutional neural network for precipitation nowcasting over China with a lead time of 3 h. The core idea of TSRC is it compensates the current local cues with previous local cues during convolution processes, so more contextual information and less uncertain features would remain in deep networks. We use four years’ radar echo reflectivity data from 2017 to 2020 for model training and one year’s data from 2021 for model testing and compare it with two commonly used nowcasting models: optical flow model (OF) and UNet. Results show that TSRC obtains better forecasting performances than OF and UNet with a relatively high probability of detection (POD), low false alarm rate (FAR), small mean absolute error (MAE) and high structural similarity index (SSIM), especially at longer lead times. Meanwhile, the results of two case studies suggest that TSRC still introduces smoothing effects and slightly outperforms UNet at longer lead times. The most considerable result is that our model can forecast high-intensity radar echoes even for typhoon rainfall systems, suggesting that the degenerate effect of forecasting precipitation intensity can be improved by our model. Future works will focus on the combination of multi-source data and the design of the model’s architecture to gain further improvements in precipitation short-term forecasting.
ISSN:2072-4292
2072-4292
DOI:10.3390/rs15010142