Y. Qiang Sun, Hamid A. Pahlavan, Ashesh Chattopadhyay, Pedram Hassanzadeh, Sandro W. Lubis, M. Joan Alexander, Edwin P. Gerber, Aditi Sheshadri, Yifei Guan
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引用次数: 0
摘要
神经网络(NN)越来越多地用于天气和气候模型中数据驱动的子网格尺度参数化。虽然神经网络是从数据中学习复杂的非线性关系的强大工具,但将其用于参数化有几个挑战。其中三个挑战是:(a)与学习稀有样本(通常是大振幅样本)相关的数据不平衡;(b)预测的不确定性量化(UQ),以提供准确性指标;以及(c)对其他气候的泛化,例如具有不同辐射强迫的气候。在此,我们使用基于全大气社区气候模式(WACCM)物理重力波(GW)参数化的 NN 仿真器作为测试案例,检验了应对这些挑战的方法的性能。WACCM 对地貌、对流和锋面驱动的重力波进行了复杂、先进的参数化。由于大多数网格点没有对流或地貌,对流和地貌驱动的 GW 存在严重的数据不平衡。我们利用重采样和/或加权损失函数来解决数据不平衡问题,从而成功模拟了所有三种来源的参数。我们证明了三种 UQ 方法(贝叶斯 NN、变异自动编码器和 dropouts)在测试过程中提供了与准确性相对应的集合扩散,为识别 NN 预测不准确提供了标准。最后,我们表明,在气候变暖(4 × CO2)的情况下,这些 NN 的准确性会降低。然而,通过迁移学习,例如仅使用来自较暖气候的 ∼1% 的新数据重新训练一层,它们的性能得到了明显改善。本研究的发现为开发可靠和可推广的数据驱动参数化提供了启示,这些参数化适用于各种过程,包括(但不限于)全球变暖。
Data Imbalance, Uncertainty Quantification, and Transfer Learning in Data-Driven Parameterizations: Lessons From the Emulation of Gravity Wave Momentum Transport in WACCM
Neural networks (NNs) are increasingly used for data-driven subgrid-scale parameterizations in weather and climate models. While NNs are powerful tools for learning complex non-linear relationships from data, there are several challenges in using them for parameterizations. Three of these challenges are (a) data imbalance related to learning rare, often large-amplitude, samples; (b) uncertainty quantification (UQ) of the predictions to provide an accuracy indicator; and (c) generalization to other climates, for example, those with different radiative forcings. Here, we examine the performance of methods for addressing these challenges using NN-based emulators of the Whole Atmosphere Community Climate Model (WACCM) physics-based gravity wave (GW) parameterizations as a test case. WACCM has complex, state-of-the-art parameterizations for orography-, convection-, and front-driven GWs. Convection- and orography-driven GWs have significant data imbalance due to the absence of convection or orography in most grid points. We address data imbalance using resampling and/or weighted loss functions, enabling the successful emulation of parameterizations for all three sources. We demonstrate that three UQ methods (Bayesian NNs, variational auto-encoders, and dropouts) provide ensemble spreads that correspond to accuracy during testing, offering criteria for identifying when an NN gives inaccurate predictions. Finally, we show that the accuracy of these NNs decreases for a warmer climate (4 × CO2). However, their performance is significantly improved by applying transfer learning, for example, re-training only one layer using ∼1% new data from the warmer climate. The findings of this study offer insights for developing reliable and generalizable data-driven parameterizations for various processes, including (but not limited to) GWs.
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