EOF分析在海岸地貌与沉积学研究中的应用进展
Progress in Applications of the EOF Analysis in the Research of Coastal Geomorphology and Sedimentology
查看参考文献79篇
文摘
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海岸地貌形成演化的过程和机制是当今海岸地貌与沉积学研究的核心任务.但是,对于海岸带这样高维数非线性系统行为的认识与研究还很有限,因而预测海岸地区地貌演变与沉积物输运就变得比较困难,尤其是动力数值模型在较大时空尺度上的模拟并不理想.数据驱动模型可以一定程度上解决这一问题,并且在数据驱动模型构建之前,经验正交函数(EOF)分析技术能够有效提取、定量表达数据中的主要型式与它们的时空演变,以及不同型式之间是如何相互联系的.这不但有助于构建数据驱动模型进行模拟,更有益于理解这些主控因素是如何影响海岸地貌演化的.进而不断丰富对于海岸地貌演化的过程与机制的认识.故本文在系统整理大量国内外文献的基础上.首先简要介绍了EOF分析的基本原理.然后从砂质和淤泥质海岸剖面的时空变化特征、河口近岸海底冲淤变化的时空演变特征和预测、海岸海洋地区沉积物粒度分布特征和输运等几个方面综述EOF分析在这些研究中的应用进展,同时比较分析研究实例中的问题,进而分析当前研究中的不足,提出应该主要从提高海岸地貌与沉积数据的野外获取手段与时空分辨率,拓宽可供EOF分析的时间或非时间序列的数据类型:深人挖掘EOF分析结果所显示出的海岸地貌与沉积现象中的物理过程与机制.以期为特定时空尺度的海岸地貌与沉积数值模拟提供有价值的参考信息:多与其他线性或非线性分析技术联合使用以作深入分析解释或模拟这三方面来做进一步改进,为实现EOF分析在海岸地貌与沉积学研究中的深入应用与发展提供借鉴. |
其他语种文摘
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The processes and mechanisms of coastal geomorphological evolution are the main tasks of the current research on coastal geomorphology and sedimentology. However, for the coastal zones that are high-dimensional and non-linear systems, their behavior has not been understood well, so predicting sediment transport and coastal geomorphological evolution in these areas are difficult tasks. The physically based prediction models are not modelling well, especially at larger temporal and spatial scales. Data-driving models can resolve such problems to a certain extent, and prior to the establishment of data-driving models, the EOF analysis technique can detect and quantify dominant patterns in the data and their evolution in time and space effectively, as well as how different patterns are related to each other. Thus, it is possible to obtain valuable information on the behavior of coastal zones that may be used not only for developing data-driving models, but also for increasing the understanding of the factors governing the geomorphological evolution, so it can improve the understanding of the processes and mechanisms of coastal geomorphological evolution. Based on a great deal of domestic and oversea references, this paper firstly introduces the principle of the EOF analysis technique, then makes a review of the progress in applications of the EOF analysis in studies of coastal geomorphological and sedimentary problems as the following aspects, characteristics of temporal and spatial changes on sandy and muddy coast profiles, characteristics of temporal and spatial changes of nearshore submarine erosion/accretion and their predictions, distribution of sediments grain sizes and sediments transportation et al., it also analyzes problems and deficiencies in the study cases, and proposes that the current research work should pay more attention to the following three main aspects in order to realize the deeper applications and development of the EOF analysis in the research of coastal geomorphology and sedimentology. First, the temporal and spatial resolution of field data and collection measures must be upgraded; the data types analyzed should be broadened. Second, the processes and mechanisms of coastal geomorphological evolution which the EOF analysis has revealed must be digged deeply in order to provide valuable information for numerical simulation at a certain scale. Third, the EOF analysis technique should be used with other linear or non-linear analysis methods for further data analysis or simulations. |
来源
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地理科学进展
,2009,28(2):174-186 【核心库】
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关键词
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EOF分析
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海岸地貌与沉积学
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时空变化特征
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过程和机制
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海岸地貌演变预测
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地址
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1.
南京大学,地理与海洋科学学院, 江苏, 南京, 210093
2.
南京信息工程大学,大气科学学院,海洋科学系, 江苏, 南京, 210044
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语种
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中文 |
文献类型
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研究性论文 |
ISSN
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1007-6301 |
学科
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自然地理学 |
基金
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加拿大国际发展署(CIDA)资助
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文献收藏号
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CSCD:3575821
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