两种普适性尺度转换方法比较与分析研究

吴骅; 姜小光; 习晓环; 李传荣; 李召良

doi:10.11834/jrs.20090235

基础理论 | 浏览量 : 0 下载量: 1511 CSCD: 23 更多指标

PDF
导出
分享
收藏
专辑

两种普适性尺度转换方法比较与分析研究
Comparison and analysis of two general scaling methods for remotely sensed information
2009年13卷第2期页码：183-189
纸质出版日期： 2009 ，
DOI： 10.11834/jrs.20090235

扫描看全文

[1]吴骅,姜小光,习晓环,李传荣,李召良.两种普适性尺度转换方法比较与分析研究[J].遥感学报,2009,13(02):183-189.

Comparison and analysis of two general scaling methods for remotely sensed information[J]. Journal of Remote Sensing, 2009,13(2):183-189.
[1]吴骅,姜小光,习晓环,李传荣,李召良.两种普适性尺度转换方法比较与分析研究[J].遥感学报,2009,13(02):183-189. DOI： 10.11834/jrs.20090235.

Comparison and analysis of two general scaling methods for remotely sensed information[J]. Journal of Remote Sensing, 2009,13(2):183-189. DOI： 10.11834/jrs.20090235.

摘要

着重阐述了地表空间信息尺度转换的必要性和方法。首先从尺度转换成因分析入手

介绍了两种普适性的尺度转换模型

即泰勒级数展开模型和计算几何模型

并对这两个模型的适用性进行了分析。借助叶面积指数的反演

针对林地、农田、水体3种不同下垫面的试验样区进行了模型的分析比较。结果表明

在拥有小尺度（高分辨率）数据时

泰勒级数模型能够很好的刻画尺度效应

使得尺度效应改正后的相对误差小于1%

获取更为准确的地表参数反演值。遥感尺度转换方法、技术为获取不同尺度的地学信息

为资源调查和环境灾害监测等相关领域的应用提供真实可靠的多尺度数据支持。

Abstract

With the development of quantitative remote sensing

the scaling problems attract more and more attention. The discrepancy between observation scale

model scale and land surface process scale may lead to different conclusions. Now

how to effectively scale remotely sensed information at different scales already becomes one of the most important research focuses of remote sensing. The aim of our research is to compare and analyze two general scaling methods

the Taylor Series Expansion Model （TSM） and the Computational Geometry Model （CGM）

and apply them to the scaling of leaf area index （LAI）. Firstly

the necessity and importance of scaling are analyzed. Secondly

based on the research of description for the same object using different scale data

the mechanism of scaling effects is presented. Then

the two general models

TSM and CGM

are briefly introduced and their advantages and disadvantages are discussed in detail. Finally

through the retrieval of leaf area index

the two models are comprehensively compared and analyzed in three distinct landscapes. The result shows that the relative scaling error increases with the heterogeneity of land surface. The relative scaling error is 2% in the relatively homogeneous woodland; however

it arises up to 7% in crop-water mixed areas. Apparently

the TSM can better characterize the scale effect and obtain more accurate surface parameters when both small scale （high resolution） data and large scale （low resolution） data are available. The relative scaling error can be reduced to less than 1% for all these test landscapes when TSM is used in scaling. In contrast

CGM can not produce rational result and the relative error is still large. It may be due to using inappropriate weights or data ranges in the model. More study about CGM is needed. On the whole

it is necessary to select the suitable scaling model according to the practical applications. The scaling makes the remote sensing products at different scales comparable and the surface parameter retrieval results more accurate. Scaling technique will provide a powerful technical support for applications in resources survey

environment and disaster monitoring

and other relevant fields.