可解释性
台风
摄动(天文学)
非线性系统
概率逻辑
集合预报
计算机科学
预测技巧
数据同化
数值天气预报
数学优化
计量经济学
分歧(语言学)
状态变量
贝叶斯概率
人工智能
机器学习
进化算法
气象学
概率分布
空间生态学
反演(地质)
应用数学
非线性模型
拉格朗日
数学
人工神经网络
提前期
作者
Bo Qin,Guokun Dai,Mu Mu,Jingchen Pu,Zeyi Niu,Chaopeng Ji,S. C. Yuan
摘要
Abstract Ensemble forecasts promote the productive shift toward quantifying prediction uncertainties, a trend increasingly embraced by current artificial intelligence (AI) models. However, most skillful data‐driven ensemble forecast models rely on probabilistic neural architectures to directly learn the future state distribution, usually overlooking the role of initial uncertainties. This oversight is partly due to the limited sensitivity of AI models to random perturbations. Recent studies indicate initial perturbations with specific spatial structures can evolve similarly in both AI and dynamic models. Inspired by this, the variational inference–conditional nonlinear optimal perturbation (VI–CNOP) method is applied in the FuXi model to investigate typhoon track ensemble forecasts. This approach involves solving a physics‐informed nonlinear optimization problem. Numerical results show VI–CNOP optimally estimates the distribution of growing‐type errors, enabling efficient sampling of more representative members than other widely used initial perturbation generation methods. Further diagnosis shows the evolutions of initial perturbations derived from VI–CNOP lead to the potential vorticity anomalies, which in turn modify the intensity and spatial extent of the Western Pacific Subtropical High, causing the uncertainties of typhoon trajectories. This investigation illustrates that introducing physics‐informed initial perturbations in AI models not only yields higher forecast performances and meaningful spread–skill relationships, but also enhances the interpretability of AI models and understanding of perturbation evolutions.
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