冰盖模式中具有时空变率的海洋强迫的统计生成

IF 1.8 4区 计算机科学 Q3 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Shivaprakash Muruganandham, A. Robel, M. Hoffman, Stephen F. Price
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引用次数: 0

摘要

在南极冰盖边缘的浮冰架底部的冰融化已被确定为海平面上升预估的一个重要不确定性来源。这种不确定性部分来自耦合海洋-大气系统的混沌内部变率。对于数值冰盖模式预估,由于运行大型气候模式组合的计算费用过高,这种不确定性以前没有被量化。在这里,我们开发并演示了一种技术,该技术可以从单一气候模式模拟中生成内部气候变率的独立实现。该技术基于以往模式仿真的发展,使用经验正交函数分解和傅立叶相位随机化来生成目标气候变量的时空变异性场的统计一致性实现。该方法有助于对大范围的气候轨迹进行有效采样,这些轨迹也可以纳入冰盖或其他物理模型中,以表示反馈过程。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Statistical Generation of Ocean Forcing With Spatiotemporal Variability for Ice Sheet Models
Melting of ice at the base of floating ice shelves that fringe the Antarctic ice sheet has been identified as a significant source of uncertainty in sea level rise projections. Part of this uncertainty derives from chaotic internal variability of the coupled ocean-atmosphere system. For numerical ice sheet model projections, this uncertainty has not previously been quantified because of the prohibitive computational expense of running large climate model ensembles. Here, we develop and demonstrate a technique that generates independent realizations of internal climate variability from a single climate model simulation. Building on previous developments in model emulation, this technique uses empirical orthogonal function decomposition and Fourier-phase randomization to generate statistically consistent realizations of spatiotemporal variability fields for the target climate variable. The method facilitates efficient sampling of a wide range of climate trajectories, which can also be incorporated within ice sheet or other physical models to represent feedback processes.
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来源期刊
Computing in Science & Engineering
Computing in Science & Engineering 工程技术-计算机:跨学科应用
CiteScore
4.20
自引率
0.00%
发文量
77
审稿时长
6-12 weeks
期刊介绍: Physics, medicine, astronomy -- these and other hard sciences share a common need for efficient algorithms, system software, and computer architecture to address large computational problems. And yet, useful advances in computational techniques that could benefit many researchers are rarely shared. To meet that need, Computing in Science & Engineering presents scientific and computational contributions in a clear and accessible format. The computational and data-centric problems faced by scientists and engineers transcend disciplines. There is a need to share knowledge of algorithms, software, and architectures, and to transmit lessons-learned to a broad scientific audience. CiSE is a cross-disciplinary, international publication that meets this need by presenting contributions of high interest and educational value from a variety of fields, including—but not limited to—physics, biology, chemistry, and astronomy. CiSE emphasizes innovative applications in advanced computing, simulation, and analytics, among other cutting-edge techniques. CiSE publishes peer-reviewed research articles, and also runs departments spanning news and analyses, topical reviews, tutorials, case studies, and more.
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