A revised interpretation of signal-to-noise ratio paradox and its application to constrain regional climate projections

Yanan Duan, Sanjiv Kumar
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Abstract

The signal-to-noise ratio paradox is interpreted as the climate model’s ability to predict observations better than the model itself. This view is counterintuitive, given that climate models are simplified numerical representations of complex earth system dynamics. A revised interpretation is provided here: the signal-to-noise ratio paradox represents excessive noise in climate predictions and projections. Noise is potentially reducible, providing a scientific basis for improving the signal in regional climate projections. The signal-to-noise ratio paradox was assessed in long-term climate projections using Single-model and Multi-model Large Ensemble climate data. A null hypothesis was constructed by performing bootstrap resampling of climate model ensembles to test its ability to predict the 20th-century temperature and precipitation trends locally and compare it with the observations. The rejection of the null hypothesis indicates the existence of a paradox. The multi-model large ensemble does not reject the null hypothesis in most places globally. The rejection rate in the single-model large ensemble is related to the model's fidelity to simulate internal climate variability rather than its ensemble size. For regions where the null hypothesis is rejected in the multi-model large ensemble, for example, India, the paradox is caused by a smaller signal strength in the climate model's ensemble. The signal strength was improved by 100% through ensemble selection and based on past performance, which reduced uncertainty in India's 30-year temperature projections by 25%. Consistent with previous studies, precipitation projections are noisier, leading to a paradox metric value 2-3 times higher than that of the temperature projections. The application of ensemble selection methodology significantly decreased uncertainty in precipitation projections for the United Kingdom, Western Australia, and Northeastern America by 47%, 36%, and 20%, respectively. Overall, this study makes a unique contribution by reducing uncertainty at the temporal scale, specifically in estimating trends using the signal-to-noise ratio paradox metric.
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信噪比悖论的修订解释及其在制约区域气候预测中的应用
信噪比悖论被解释为气候模式预测观测结果的能力优于模式本身。鉴于气候模式是复杂地球系统动力学的简化数字表示,这种观点有违直觉。本文提供了一种修正的解释:信噪比悖论代表气候预测和预报中噪音过大。噪声有可能减少,这为改善区域气候预测中的信号提供了科学依据。利用单一模式和多模式大型集合气候数据对长期气候预测中的信噪比悖论进行了评估。通过对气候模式集合进行引导重采样,构建了一个零假设,以检验其预测 20 世纪当地气温和降水趋势的能力,并将其与观测数据进行比较。拒绝零假设表明存在一个悖论。在全球大多数地方,多模式大集合并不拒绝零假设。单模型大集合的拒绝率与模型模拟内部气候变异性的保真度有关,而与集合规模无关。对于在多模型大集合中拒绝零假设的地区,例如印度,矛盾的原因是气候模型集合中的信号强度较小。通过集合选择并根据过去的表现,信号强度提高了 100%,从而将印度 30 年气温预测的不确定性降低了 25%。与之前的研究一致,降水预测的噪音更大,导致悖论指标值比温度预测高出 2-3 倍。集合选择方法的应用大大降低了英国、澳大利亚西部和美国东北部降水预测的不确定性,分别降低了 47%、36% 和 20%。总体而言,这项研究通过减少时间尺度上的不确定性,特别是在使用信噪比悖论指标估计趋势方面,做出了独特的贡献。
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