Evaluation of Statistical Downscaling Methods for Simulating Daily Precipitation Distribution, Frequency, and Temporal Sequence

IF 1.4 4区 农林科学 Q3 AGRICULTURAL ENGINEERING
X. Zhang, Mingxi Shen, Jie Chen, J. Homan, P. Busteed
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引用次数: 5

Abstract

HighlightsNine statistical downscaling methods from three downscaling categories were evaluated.Weather generator-based methods had advantages in simulating non-stationary precipitation.Differences in downscaling performance were smaller within each category than between categories.The performance of each downscaling method varied with climate conditions.Abstract. Spatial discrepancy between global climate model (GCM) projections and the climate data input required by hydrological models is a major limitation for assessing the impact of climate change on soil erosion and crop production at local scales. Statistical downscaling techniques are widely used to correct biases of GCM projections. The objective of this study was to evaluate the ability of nine statistical downscaling methods from three available statistical downscaling categories to simulate daily precipitation distribution, frequency, and temporal sequence at four Oklahoma weather stations representing arid to humid climate regions. The three downscaling categories included perfect prognosis (PP), model output statistics (MOS), and stochastic weather generator (SWG). To minimize the effect of GCM projection error on downscaling quality, the National Centers for Environmental Prediction (NCEP) Reanalysis 1 data at a 2.5° grid spacing (treated as observed grid data) were downscaled to the four weather stations (representing arid, semi-arid, sub humid, and humid regions) using the nine downscaling methods. The station observations were divided into calibration and validation periods in a way that maximized the differences in annual precipitation means between the two periods for assessing the ability of each method in downscaling non-stationary climate changes. All methods were ranked with three metrics (Euclidean distance, sum of absolute relative error, and absolute error) for their ability in simulating precipitation amounts at daily, monthly, yearly, and annual maximum scales. After eliminating the poorest two performers in simulating precipitation mean, distribution, frequency, and temporal sequence, the top four remaining methods in ascending order were Distribution-based Bias Correction (DBC), Generator for Point Climate Change (GPCC), SYNthetic weather generaTOR (SYNTOR), and LOCal Intensity scaling (LOCI). DBC and LOCI are bias-correction methods, and GPCC and SYNTOR are generator-based methods. The differences in performances among the downscaling methods were smaller within each downscaling category than between the categories. The performance of each method varied with the climate conditions of each station. Overall results indicated that the SWG methods had certain advantages in simulating daily precipitation distribution, frequency, and temporal sequence for non-stationary climate changes. Keywords: Climate change, Climate downscaling, Downscaling method evaluation, Statistical downscaling.
模拟日降水分布、频率和时间序列的统计降尺度方法的评价
从三个降尺度类别中评估了9种统计降尺度方法。基于天气发生器的方法在模拟非平稳降水方面具有优势。每个类别内缩小性能的差异小于类别之间的差异。各种降尺度方法的性能随气候条件的不同而不同。全球气候模式(GCM)预估与水文模型所需的气候数据输入之间的空间差异是评估气候变化对地方尺度土壤侵蚀和作物生产影响的主要限制因素。统计降尺度技术被广泛用于修正GCM预测的偏差。本研究的目的是评估九种统计降尺度方法在俄克拉何马州四个气象站的日降水分布、频率和时间序列模拟能力,这些气象站分别代表干旱和湿润气候区。三个降尺度分类包括完美预测(PP)、模式输出统计(MOS)和随机天气发生器(SWG)。为了最大限度地减少GCM投影误差对降尺度质量的影响,采用9种降尺度方法,将美国国家环境预测中心(NCEP)再分析1在2.5°栅格间距上的数据(作为观测栅格数据处理)降尺度到4个气象站(分别代表干旱、半干旱、半湿润和湿润地区)。台站观测被划分为校准期和验证期,以最大限度地利用两个期之间的年降水量平均值差异,以评估每种方法对非平稳气候变化的降尺度能力。用欧几里得距离、绝对相对误差和绝对误差之和对所有方法在日、月、年和年最大尺度上的降水模拟能力进行了排序。在去除模拟降水平均值、分布、频率和时间序列方面表现最差的两种方法后,排名前四的方法依次为基于分布的偏差校正(DBC)、点气候变化发生器(GPCC)、合成天气发生器(SYNTOR)和局部强度标度(LOCI)。DBC和LOCI是偏置校正方法,GPCC和SYNTOR是基于生成器的方法。各降阶方法之间的性能差异在每个降阶类别内小于类别之间。每一种方法的效果随各站气候条件的不同而不同。总体结果表明,SWG方法在模拟非平稳气候变化的日降水分布、频率和时间序列方面具有一定优势。关键词:气候变化,气候降尺度,降尺度方法评价,统计降尺度
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来源期刊
Transactions of the ASABE
Transactions of the ASABE AGRICULTURAL ENGINEERING-
CiteScore
2.30
自引率
0.00%
发文量
0
审稿时长
6 months
期刊介绍: This peer-reviewed journal publishes research that advances the engineering of agricultural, food, and biological systems. Submissions must include original data, analysis or design, or synthesis of existing information; research information for the improvement of education, design, construction, or manufacturing practice; or significant and convincing evidence that confirms and strengthens the findings of others or that revises ideas or challenges accepted theory.
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