%0 Generic %1 wang2018uncertainty %A Wang, Bin %A Lu, Jie %A Yan, Zheng %A Luo, Huaishao %A Li, Tianrui %A Zheng, Yu %A Zhang, Guangquan %D 2018 %K bayesian deep-learning uncertainty %T Deep Uncertainty Quantification: A Machine Learning Approach for Weather Forecasting %U http://arxiv.org/abs/1812.09467 %X Weather forecasting is usually solved through numerical weather prediction (NWP), which can sometimes lead to unsatisfactory performance due to inappropriate setting of the initial states. In this paper, we design a data-driven method augmented by an effective information fusion mechanism to learn from historical data that incorporates prior knowledge from NWP. We cast the weather forecasting problem as an end-to-end deep learning problem and solve it by proposing a novel negative log-likelihood error (NLE) loss function. A notable advantage of our proposed method is that it simultaneously implements single-value forecasting and uncertainty quantification, which we refer to as deep uncertainty quantification (DUQ). Efficient deep ensemble strategies are also explored to further improve performance. This new approach was evaluated on a public dataset collected from weather stations in Beijing, China. Experimental results demonstrate that the proposed NLE loss significantly improves generalization compared to mean squared error (MSE) loss and mean absolute error (MAE) loss. Compared with NWP, this approach significantly improves accuracy by 47.76%, which is a state-of-the-art result on this benchmark dataset. The preliminary version of the proposed method won 2nd place in an online competition for daily weather forecasting.

@misc{wang2018uncertainty, abstract = {Weather forecasting is usually solved through numerical weather prediction (NWP), which can sometimes lead to unsatisfactory performance due to inappropriate setting of the initial states. In this paper, we design a data-driven method augmented by an effective information fusion mechanism to learn from historical data that incorporates prior knowledge from NWP. We cast the weather forecasting problem as an end-to-end deep learning problem and solve it by proposing a novel negative log-likelihood error (NLE) loss function. A notable advantage of our proposed method is that it simultaneously implements single-value forecasting and uncertainty quantification, which we refer to as deep uncertainty quantification (DUQ). Efficient deep ensemble strategies are also explored to further improve performance. This new approach was evaluated on a public dataset collected from weather stations in Beijing, China. Experimental results demonstrate that the proposed NLE loss significantly improves generalization compared to mean squared error (MSE) loss and mean absolute error (MAE) loss. Compared with NWP, this approach significantly improves accuracy by 47.76%, which is a state-of-the-art result on this benchmark dataset. The preliminary version of the proposed method won 2nd place in an online competition for daily weather forecasting.}, added-at = {2019-06-13T17:59:46.000+0200}, author = {Wang, Bin and Lu, Jie and Yan, Zheng and Luo, Huaishao and Li, Tianrui and Zheng, Yu and Zhang, Guangquan}, biburl = {https://www.bibsonomy.org/bibtex/23b5a2673035417ccdac04f9813719ca6/kirk86}, description = {[1812.09467] Deep Uncertainty Quantification: A Machine Learning Approach for Weather Forecasting}, interhash = {13dd82fc0a0d4449edf1db1e937a5b22}, intrahash = {3b5a2673035417ccdac04f9813719ca6}, keywords = {bayesian deep-learning uncertainty}, note = {cite arxiv:1812.09467}, timestamp = {2019-06-13T17:59:46.000+0200}, title = {Deep Uncertainty Quantification: A Machine Learning Approach for Weather Forecasting}, url = {http://arxiv.org/abs/1812.09467}, year = 2018 }