Optimization research on air quality numerical model forecasting effects based on deep learning methods.

To improve the forecasting effectiveness of numerical air quality models, two deep learning models, DeepPM and APTR, were constructed and trained in this study using PM 2.5 and O 3 monitoring data, and WRF-Chem numerical forecasts in the south-central Beijing-Tianjin-Hebei region. The optimization effects were evaluated using test datasets and various evaluation metrics. The results show that the PM 2.5 and O 3 forecast results optimized by the DeepPM, and APTR models significantly outperform the WRF-Chem numerical model for both proximity forecasts over the next 24 h and short- to medium-term forecasts over the next 144 h. The APTR model achieves the best optimization results in proximity forecasting, whereas the DeepPM model has a better overall performance in optimizing the short- and medium-term forecasts. WRF-Chem is superior to other models in predicting high O 3 concentration. DeepPM and APTR deep learning models are still significantly better than WRF-Chem for forecasting high concentration bands within the proximity forecast time period. For short- to medium-term forecasting, the DeepPM model outperforms WRF-Chem for forecasting high O 3 concentrations. This paper provides a new method and idea for improving the forecasting performance of air quality numerical models. • Two deep learning models were established to improve forecasting performance of WRF-Chem. • The APTR model achieves the best optimization results in proximity forecasting (24-h). • The DeepPM model has a better performance in optimizing short- and medium-term forecasts (144-h). [ABSTRACT FROM AUTHOR]