利用经验正交函数和神经网络预测澳大利亚东南部的季节性降雨量

arXiv - PHYS - Atmospheric and Oceanic Physics Pub Date : 2024-08-20 DOI:arxiv-2408.10550

Stjepan Marcelja

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引用次数: 0

摘要

对下一季的平均降雨量进行定量预测仍然极具挑战性，但在一些有利的个别情况下，可以通过一系列相对简单的步骤来实现。我们选择根据澳大利亚东南部地区冬季周围的海洋表面温度来探索澳大利亚东南部地区春季降雨量的预测。在第一阶段，我们搜索目标降雨量与标准海洋气候指标以及表层温度数据时间序列之间的相关性，并以经验正交函数（EOFs）的形式进行扩展。就印度洋而言，在冬季，主导 EOF 与未来降雨量的相关性要强于常用的印度洋偶极子。然后，与历史降雨量数据相关性最强的信息源被用作深度学习人工神经网络的输入。结果表明，对 9 月和 10 月的后向预测是准确的，而对 11 月的预测则不太可靠。我们还尝试预测几个地区即将到来的澳大利亚春季的降雨量。

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Forecasting seasonal rainfall in SE Australia using Empirical Orthogonal Functions and Neural Networks

Quantitative forecasting of average rainfall into the next season remains highly challenging, but in some favourable isolated cases may be possible with a series of relatively simple steps. We chose to explore predictions of austral springtime rainfall in SE Australia regions based on the surrounding ocean surface temperatures during the winter. In the first stage, we search for correlations between the target rainfall and both the standard ocean climate indicators as well as the time series of surface temperature data expanded in terms of Empirical Orthogonal Functions (EOFs). In the case of the Indian Ocean, during the winter the dominant EOF shows stronger correlation with the future rainfall than the commonly used Indian Ocean Dipole. Information sources with the strongest correlation to the historical rainfall data are then used as inputs into deep learning artificial neural networks. The resulting hindcasts appear accurate for September and October and less reliable for November. We also attempt to forecast the rainfall in several regions for the coming austral spring.

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arXiv - PHYS - Atmospheric and Oceanic Physics

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