不完整时空数据的功能主成分分析

IF 3 4区 环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES Environmental and Ecological Statistics Pub Date : 2024-03-16 DOI:10.1007/s10651-024-00598-7
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引用次数: 0

摘要

摘要 通过遥感等手段获取的环境信号,往往在空间和时间上存在大量的观测数据缺失。在这项工作中,我们提出了一种创新方法,在数据可能受到复杂的缺失数据结构影响时,识别时空数据中的主要变异模式。我们在函数数据分析的框架内正式提出了这一问题,并针对不完整的时空数据提出了一种创新的函数主成分分析(fPCA)方法。该方法的函数性质允许借用在附近时空位置观测到的测量信息。由此产生的函数主成分是所考虑的时空领域内的平滑场,可为所研究现象的时空动态提供有趣的见解。此外,在数据严重缺失的情况下,它们也可以用来重建缺失的条目。所提出的模型将数据矩阵的加权秩一近似与粗糙度惩罚相结合。我们的研究表明,估计问题可以使用大数最小化方法来解决,并提供了一种高效的数值求解算法。由于采用了基于空间有限元和时间 B 样条的离散化方法,所提出的方法可以处理形状复杂的多维空间域,如具有复杂海岸线的水体或具有复杂地形的弯曲空间区域。模拟研究表明,所提出的时空 fPCA 优于缺失数据主成分分析的其他技术。通过将时空 fPCA 应用于中非维多利亚湖湖水表面温度(LWST)的研究,我们进一步强调了所提方法在环境问题上的潜力。湖水表面温度被认为是气候变化如何影响环境的基本指标之一,也是公认的重要气候变量。
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Functional principal component analysis for incomplete space–time data

Abstract

Environmental signals, acquired, e.g., by remote sensing, often present large gaps of missing observations in space and time. In this work, we present an innovative approach to identify the main variability patterns, in space–time data, when data may be affected by complex missing data structures. We formalize the problem in the framework of functional data analysis, proposing an innovative method of functional principal component analysis (fPCA) for incomplete space–time data. The functional nature of the proposed method permits to borrow information from measurements observed at nearby spatio-temporal locations. The resulting functional principal components are smooth fields over the considered spatio-temporal domain, and can lead to interesting insights in the spatio-temporal dynamic of the phenomenon under study. Moreover, they can be used to provide a reconstruction of the missing entries, also under severe missing data patterns. The proposed model combines a weighted rank-one approximation of the data matrix with a roughness penalty. We show that the estimation problem can be solved using a majorize–minimization approach, and provide a numerically efficient algorithm for its solution. Thanks to a discretization based on finite elements in space and B-splines in time, the proposed method can handle multidimensional spatial domains with complex shapes, such as water bodies with complicated shorelines, or curved spatial regions with complex orography. As shown by simulation studies, the proposed space–time fPCA is superior to alternative techniques for Principal Component Analysis with missing data. We further highlight the potentiality of the proposed method for environmental problems, by applying space–time fPCA to the study of the lake water surface temperature (LWST) of Lake Victoria, in Central Africa, starting from satellite measurements with large gaps. LWST is considered one of the fundamental indicators of how climate change is affecting the environment, and is recognized as an essential climate variable.

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来源期刊
Environmental and Ecological Statistics
Environmental and Ecological Statistics 环境科学-环境科学
CiteScore
5.90
自引率
2.60%
发文量
27
审稿时长
>36 weeks
期刊介绍: Environmental and Ecological Statistics publishes papers on practical applications of statistics and related quantitative methods to environmental science addressing contemporary issues. Emphasis is on applied mathematical statistics, statistical methodology, and data interpretation and improvement for future use, with a view to advance statistics for environment, ecology and environmental health, and to advance environmental theory and practice using valid statistics. Besides clarity of exposition, a single most important criterion for publication is the appropriateness of the statistical method to the particular environmental problem. The Journal covers all aspects of the collection, analysis, presentation and interpretation of environmental data for research, policy and regulation. The Journal is cross-disciplinary within the context of contemporary environmental issues and the associated statistical tools, concepts and methods. The Journal broadly covers theory and methods, case studies and applications, environmental change and statistical ecology, environmental health statistics and stochastics, and related areas. Special features include invited discussion papers; research communications; technical notes and consultation corner; mini-reviews; letters to the Editor; news, views and announcements; hardware and software reviews; data management etc.
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