Evaluation of some distributional downscaling methods as applied to daily maximum temperature with emphasis on extremes

Statistical downscaling methods are extensively used to refine future climate change projections produced by physical models. Distributional methods, which are among the simplest to implement, are also among the most widely used, either by themselves or in conjunction with more complex approaches. H...

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Veröffentlicht in:	International journal of climatology 2020-03, Vol.40 (3), p.1571-1585
Hauptverfasser:	Lanzante, John R., Adams‐Smith, Dennis, Dixon, Keith W., Nath, Maryjo, Whitlock, Carolyn E.
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Bias bias‐correction Climate change Climate models Complexity Design of experiments distributions Dynamic models Experimental design Extreme values Future climates Maximum temperatures perfect model evaluation Performance evaluation Seasonal variation Seasonal variations statistical downscaling Statistical methods tail values Tails Temperature
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description	Statistical downscaling methods are extensively used to refine future climate change projections produced by physical models. Distributional methods, which are among the simplest to implement, are also among the most widely used, either by themselves or in conjunction with more complex approaches. Here, building off of earlier work we evaluate the performance of seven methods in this class that range widely in their degree of complexity. We employ daily maximum temperature over the Continental U.S. in a “Perfect Model” approach in which the output from a large‐scale dynamical model is used as a proxy for both observations and model output. Importantly, this experimental design allows one to estimate expected performance under a future high‐emissions climate‐change scenario. We examine skill over the full distribution as well in the tails, seasonal variations in skill, and the ability to reproduce the climate change signal. Viewed broadly, there generally are modest overall differences in performance across the majority of the methods. However, the choice of philosophical paradigms used to define the downscaling algorithms divides the seven methods into two classes, of better versus poorer overall performance. In particular, the bias‐correction plus change‐factor approach performs better overall than the bias‐correction only approach. Finally, we examine the performance of some special tail treatments that we introduced in earlier work which were based on extensions of a widely used existing scheme. We find that our tail treatments provide a further enhancement in downscaling extremes. This study compares the performance of seven distributional‐type statistical downscaling methods, with emphasis on the tails of the distribution. Output from a climate model under a climate change scenario is used in a “Perfect Model” evaluation. Skill for each method is represented by a different colour in the figure for several different testing scenarios. There is little difference in skill for the majority of the methods, although several (green, violet, and brown) perform consistently worse across scenarios.
doi_str_mv	10.1002/joc.6288
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However, the choice of philosophical paradigms used to define the downscaling algorithms divides the seven methods into two classes, of better versus poorer overall performance. In particular, the bias‐correction plus change‐factor approach performs better overall than the bias‐correction only approach. Finally, we examine the performance of some special tail treatments that we introduced in earlier work which were based on extensions of a widely used existing scheme. We find that our tail treatments provide a further enhancement in downscaling extremes. This study compares the performance of seven distributional‐type statistical downscaling methods, with emphasis on the tails of the distribution. Output from a climate model under a climate change scenario is used in a “Perfect Model” evaluation. Skill for each method is represented by a different colour in the figure for several different testing scenarios. 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subjects	Algorithms Bias bias‐correction Climate change Climate models Complexity Design of experiments distributions Dynamic models Experimental design Extreme values Future climates Maximum temperatures perfect model evaluation Performance evaluation Seasonal variation Seasonal variations statistical downscaling Statistical methods tail values Tails Temperature
title	Evaluation of some distributional downscaling methods as applied to daily maximum temperature with emphasis on extremes
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