4.6 Article

Added value of an atmospheric circulation pattern-based statistical downscaling approach for daily precipitation distributions in complex terrain

Journal

INTERNATIONAL JOURNAL OF CLIMATOLOGY
Volume 43, Issue 11, Pages 5130-5153

Publisher

WILEY
DOI: 10.1002/joc.8136

Keywords

bias correction; circulation patterns; ERA5; extreme events; heavy precipitation; simulated annealing; statistical downscaling

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Reliable prediction of heavy precipitation events causing floods is crucial for adaptation strategies in a changing climate. This study proposes a circulation pattern conditional downscaling approach that considers frequency changes of circulation patterns. Precipitation observations are used to derive conditional cumulative distribution functions and raw precipitation time series are sampled from these functions. Bias correction is applied using quantile mapping and parametric transfer functions. The evaluation shows that the proposed approach yields more reliable and accurate downscaled precipitation time series, particularly for extreme events.
Reliable prediction of heavy precipitation events causing floods in a world of changing climate is crucial for the development of appropriate adaption strategies. Many attempts to provide such predictions have already been conducted but there is still much potential for improvement left. This is particularly true for statistical downscaling of heavy precipitation due to changes present in the corresponding atmospheric drivers. In this study, a circulation pattern (CP) conditional downscaling to the station level is proposed which considers occurring frequency changes of CPs. Following a strict circulation-to-environment approach we use atmospheric predictors to derive CPs. Subsequently, precipitation observations are used to derive CP conditional cumulative distribution functions (CDFs) of daily precipitation. Raw precipitation time series are sampled from these CDFs. Bias correction is applied to the sampled time series with quantile mapping (QM) and parametric transfer functions (PTFs) as methods being tested. The added value of this CP conditional downscaling approach is evaluated against the corresponding common non-CP conditional approach. The performance evaluation is conducted by using Kling-Gupta Efficiency (KGE), root mean squared error (RMSE), and mean absolute error (MAE) metrics. In both cases the applied bias correction is identical. Potential added value can therefore only be attributed to the CP conditioning. It can be shown that the proposed CP conditional downscaling approach is capable of yielding more reliable and accurate downscaled daily precipitation time series in comparison to a non-CP conditional approach. This can be seen in particular for the extreme parts of the distribution. Above the 95th percentile, an average performance gain of +0.24 and a maximum gain of +0.6 in terms of KGE is observed. These findings support the assumption of conserving and utilizing atmospheric information through CPs can be beneficial for more reliable statistical precipitation downscaling. Due to the availability of these atmospheric predictors in climate model output, the presented method is potentially suitable for downscaling precipitation projections.

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