Improved Correction of Extreme Precipitation Through Explicit and Continuous Nonstationarity Treatment and the Metastatistical Approach

IF 4.6 1区地球科学 Q2 ENVIRONMENTAL SCIENCES

Water Resources Research Pub Date : 2025-01-03 DOI:10.1029/2024wr037721

Cuauhtémoc Tonatiuh Vidrio-Sahagún, Jianxun He, Alain Pietroniro

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引用次数: 0

Abstract

Climate models simulate extreme precipitation under nonstationarity due to continuous climate change. However, systematic errors in local-scale climate projections are often corrected using stationary or quasi-stationary methods without explicit and continuous nonstationarity treatment, like quantile mapping (QM), detrended QM, and quantile delta mapping. To bridge this gap, we introduce nonstationary QM (NS-QM) and its simplified version for consistent nonstationarity patterns (CNS-QM). Besides, correction approaches for extremes often rely on limited extreme-event records. To leverage ordinary-event information while focusing on extremes, we propose integrating the simplified Metastatistical extreme value (SMEV) distribution into NS-QM and CNS-QM (NS-QM-SMEV and CNS-QM-SMEV). We demonstrate the superiority of NS- and CNS-QM-SMEV over existing methods through a simulation study and show several real-world applications using high-resolution-regional and coarse-resolution-global climate models. NS-QM and CNS-QM reflect nonstationarity more realistically but may encounter challenges due to data limitations like estimation errors and uncertainty, particularly for the most extreme events. These issues, shared by existing approaches, are effectively mitigated using the SMEV distribution. NS- and CNS-QM-SMEV offer lower estimation error, approximate unbiasedness, reduced uncertainty, and improved representation of the entire distribution, especially for samples of ∼70 years, and greater superiority with larger samples. We show existing methods may perform competitively for short samples but exhibit substantial biases in quantile-quantile matching due to bypassing nonstationarity modeling. NS- and CNS-QM-SMEV avoid these biases, adhering better to their theoretical functioning. Thus, NS- and CNS-QM-SMEV enhance the correction of extremes under nonstationarity. Yet, properly identifying nonstationarity patterns is crucial for reliable implementations.

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通过明确和连续的非平稳性处理和亚转移方法改进极端降水的校正

气候模式模拟了由于持续气候变化造成的非平稳性条件下的极端降水。然而，局地尺度气候预估的系统误差通常使用平稳或准平稳方法进行校正，而不需要明确和连续的非平稳性处理，如分位数映射（QM）、去趋势QM和分位数增量映射。为了弥补这一差距，我们引入了非平稳QM （NS-QM）及其简化版本的一致非平稳模式（CNS-QM）。此外，极值的校正方法通常依赖于有限的极端事件记录。为了在关注极值的同时利用普通事件信息，我们提出将简化的亚稳态极值（SMEV）分布整合到NS-QM和CNS-QM （NS-QM-SMEV和CNS-QM-SMEV）中。我们通过模拟研究证明了NS-和CNS-QM-SMEV比现有方法的优越性，并展示了使用高分辨率区域和粗分辨率全球气候模式的几个实际应用。NS-QM和CNS-QM更真实地反映了非平稳性，但由于数据的限制，如估计误差和不确定性，特别是对于最极端的事件，可能会遇到挑战。使用SMEV分布可以有效地缓解现有方法所共有的这些问题。NS-和CNS-QM-SMEV提供了更低的估计误差、近似无偏性、更少的不确定性，并改善了整个分布的代表性，特别是对于~ 70年的样本，并且在更大的样本中具有更大的优势。我们表明，现有的方法可能对短样本具有竞争力，但由于绕过非平稳性建模，在分位数-分位数匹配中表现出实质性的偏差。NS-和CNS-QM-SMEV避免了这些偏差，更好地坚持了它们的理论功能。因此，NS-和CNS-QM-SMEV增强了非平稳条件下极值的校正。然而，正确识别非平稳性模式对于可靠的实现至关重要。

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来源期刊

Water Resources Research 环境科学-湖沼学

CiteScore

8.80

自引率

13.00%

发文量

599

审稿时长

3.5 months

期刊介绍： Water Resources Research (WRR) is an interdisciplinary journal that focuses on hydrology and water resources. It publishes original research in the natural and social sciences of water. It emphasizes the role of water in the Earth system, including physical, chemical, biological, and ecological processes in water resources research and management, including social, policy, and public health implications. It encompasses observational, experimental, theoretical, analytical, numerical, and data-driven approaches that advance the science of water and its management. Submissions are evaluated for their novelty, accuracy, significance, and broader implications of the findings.