Future climate emulations using quantile regressions on large ensembles

Q1 Mathematics

Advances in Statistical Climatology, Meteorology and Oceanography Pub Date : 2019-04-10 DOI:10.5194/ASCMO-5-37-2019

Matz A. Haugen, M. Stein, R. Sriver, E. Moyer

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引用次数: 8

Abstract

Abstract. The study of climate change and its impacts depends on generating projections of future temperature and other climate variables. For detailed studies, these projections usually require some combination of numerical simulation and observations, given that simulations of even the current climate do not perfectly reproduce local conditions. We present a methodology for generating future climate projections that takes advantage of the emergence of climate model ensembles, whose large amounts of data allow for detailed modeling of the probability distribution of temperature or other climate variables. The procedure gives us estimated changes in model distributions that are then applied to observations to yield projections that preserve the spatiotemporal dependence in the observations. We use quantile regression to estimate a discrete set of quantiles of daily temperature as a function of seasonality and long-term change, with smooth spline functions of season, long-term trends, and their interactions used as basis functions for the quantile regression. A particular innovation is that more extreme quantiles are modeled as exceedances above less extreme quantiles in a nested fashion, so that the complexity of the model for exceedances decreases the further out into the tail of the distribution one goes. We apply this method to two large ensembles of model runs using the same forcing scenario, both based on versions of the Community Earth System Model (CESM), run at different resolutions. The approach generates observation-based future simulations with no processing or modeling of the observed climate needed other than a simple linear rescaling. The resulting quantile maps illuminate substantial differences between the climate model ensembles, including differences in warming in the Pacific Northwest that are particularly large in the lower quantiles during winter. We show how the availability of two ensembles allows the efficacy of the method to be tested with a “perfect model” approach, in which we estimate transformations using the lower-resolution ensemble and then apply the estimated transformations to single runs from the high-resolution ensemble. Finally, we describe and implement a simple method for adjusting a transformation estimated from a large ensemble of one climate model using only a single run of a second, but hopefully more realistic, climate model.

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在大集合上使用分位数回归的未来气候模拟

摘要对气候变化及其影响的研究取决于对未来温度和其他气候变量的预测。为了进行详细的研究，这些预测通常需要数值模拟和观测相结合，因为即使是对当前气候的模拟也不能完美地再现当地条件。我们提出了一种生成未来气候预测的方法，该方法利用了气候模型集合的合并，其大量数据允许对温度或其他气候变量的概率分布进行详细建模。该程序为我们提供了模型分布的估计变化，然后将其应用于观测，以产生保持观测时空相关性的投影。我们使用分位数回归来估计作为季节性和长期变化函数的一组离散的日温度分位数，将季节、长期趋势及其相互作用的光滑样条函数用作分位数回归的基函数。一个特别的创新是，更多的极值方程被建模为嵌套函数中不太极端的分位数以上的超越，因此超越模型的复杂性随着分布的尾部而降低。我们将这种方法应用于使用相同强迫场景的两个大型模型运行集合，这两个集合都基于社区地球系统模型（CESM）的版本，以不同的分辨率运行。该方法生成基于观测的未来模拟，除了简单的线性重新缩放外，无需对观测到的气候进行处理或建模。由此产生的分位数图揭示了气候模型集合之间的实质性差异，包括太平洋西北部变暖的差异，这些差异在冬季的较低分位数中尤其大。我们展示了两个系综的可用性如何允许使用“完美模型”方法来测试该方法的有效性，在该方法中，我们使用较低分辨率系综估计变换，然后将估计的变换应用于高分辨率系综的单次运行。最后，我们描述并实现了一种简单的方法，用于调整从一个气候模型的大型集合估计的转换，只使用一秒钟的时间，但希望更现实的气候模型。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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