Scaled distribution mapping: a bias correction method that preserves raw climate model projected changes

被引:154
作者
Switanek, Matthew B. [1 ]
Troch, Peter A. [2 ]
Castro, Christopher L. [2 ]
Leuprecht, Armin [1 ]
Chang, Hsin-I [2 ]
Mukherjee, Rajarshi [2 ]
Demaria, Eleonora M. C. [3 ]
机构
[1] Karl Franzens Univ Graz, Wegener Ctr Climate & Global Change, A-8010 Graz, Austria
[2] Univ Arizona, Dept Hydrol & Atmospher Sci, Tucson, AZ 85721 USA
[3] USDA ARS, Southwest Watershed Res Ctr, Tucson, AZ 85719 USA
来源
HYDROLOGY AND EARTH SYSTEM SCIENCES | 2017年 / 21卷 / 06期
关键词
DOWNSCALING METHODS; CHANGE IMPACTS; PRECIPITATION; SIMULATIONS; EXTREMES; RAINFALL;
D O I
10.5194/hess-21-2649-2017
中图分类号
P [天文学、地球科学];
学科分类号
07 ;
摘要
Commonly used bias correction methods such as quantile mapping (QM) assume the function of error correction values between modeled and observed distributions are stationary or time invariant. This article finds that this function of the error correction values cannot be assumed to be stationary. As a result, QM lacks justification to inflate/deflate various moments of the climate change signal. Previous adaptations of QM, most notably quantile delta mapping (QDM), have been developed that do not rely on this assumption of stationarity. Here, we outline a methodology called scaled distribution mapping (SDM), which is conceptually similar to QDM, but more explicitly accounts for the frequency of rain days and the likelihood of individual events. The SDM method is found to outperform QM, QDM, and detrended QM in its ability to better preserve raw climate model projected changes to meteorological variables such as temperature and precipitation.
引用
收藏
页码:2649 / 2666
页数:18
相关论文
共 51 条
[1]   Multiscale spatial recorrelation of RCM precipitation to produce unbiased climate change scenarios over large areas and small [J].
Bardossy, Andres ;
Pegram, Geoffrey .
WATER RESOURCES RESEARCH, 2012, 48
[2]   Impact of bias correction to reanalysis products on simulations of North American soil moisture and hydrological fluxes [J].
Berg, AA ;
Famiglietti, JS ;
Walker, JP ;
Houser, PR .
JOURNAL OF GEOPHYSICAL RESEARCH-ATMOSPHERES, 2003, 108 (D16)
[3]   Statistical and dynamical downscaling of the Seine basin climate for hydro-meteorological studies [J].
Boe, J. ;
Terray, L. ;
Habets, F. ;
Martin, E. .
INTERNATIONAL JOURNAL OF CLIMATOLOGY, 2007, 27 (12) :1643-1655
[4]  
Brekke L., 2013, DOWNSCALING CMIP3 CM
[5]   Downscaling Extremes: An Intercomparison of Multiple Methods for Future Climate [J].
Buerger, G. ;
Sobie, S. R. ;
Cannon, A. J. ;
Werner, A. T. ;
Murdock, T. Q. .
JOURNAL OF CLIMATE, 2013, 26 (10) :3429-3449
[6]   Bias Correction of GCM Precipitation by Quantile Mapping: How Well Do Methods Preserve Changes in Quantiles and Extremes? [J].
Cannon, Alex J. ;
Sobie, Stephen R. ;
Murdock, Trevor Q. .
JOURNAL OF CLIMATE, 2015, 28 (17) :6938-6959
[7]   Performance and uncertainty evaluation of empirical downscaling methods in quantifying the climate change impacts on hydrology over two North American river basins [J].
Chen, Jie ;
Brissette, Francois P. ;
Chaumont, Diane ;
Braun, Marco .
JOURNAL OF HYDROLOGY, 2013, 479 :200-214
[8]   On the need for bias correction of regional climate change projections of temperature and precipitation [J].
Christensen, Jens H. ;
Boberg, Fredrik ;
Christensen, Ole B. ;
Lucas-Picher, Philippe .
GEOPHYSICAL RESEARCH LETTERS, 2008, 35 (20)
[9]   Potential for added value in temperature simulated by high-resolution nested RCMs in present climate and in the climate change signal [J].
Di Luca, Alejandro ;
de Elia, Ramon ;
Laprise, Rene .
CLIMATE DYNAMICS, 2013, 40 (1-2) :443-464
[10]   Should we apply bias correction to global and regional climate model data? [J].
Ehret, U. ;
Zehe, E. ;
Wulfmeyer, V. ;
Warrach-Sagi, K. ;
Liebert, J. .
HYDROLOGY AND EARTH SYSTEM SCIENCES, 2012, 16 (09) :3391-3404
123456