陆地总初级生产力遥感估算精度分析

林尚荣; 李静; 柳钦火

doi:10.11834/jrs.20186456

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陆地总初级生产力遥感估算精度分析
Overview on estimation accuracy of gross primary productivity with remote sensing methods
2018年22卷第2期页码：234-254
纸质出版日期： 2018-3 ，

录用日期： 2017-9-12
DOI： 10.11834/jrs.20186456

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林尚荣, 李静, 柳钦火. 2018. 陆地总初级生产力遥感估算精度分析. 遥感学报, 22(2): 234–254

Lin S R, Li J and Liu Q H. 2018. Overview on estimation accuracy of gross primary productivity with remote sensing methods. Journal of Remote Sensing, 22(2): 234–254
林尚荣, 李静, 柳钦火. 2018. 陆地总初级生产力遥感估算精度分析. 遥感学报, 22(2): 234–254 DOI： 10.11834/jrs.20186456.

Lin S R, Li J and Liu Q H. 2018. Overview on estimation accuracy of gross primary productivity with remote sensing methods. Journal of Remote Sensing, 22(2): 234–254 DOI： 10.11834/jrs.20186456.

摘要

准确估算陆地总初级生产力GPP(Gross Primary Productivity)数值对碳循环过程模拟有重要影响。本文介绍了多种基于植被指数以及基于光能利用率的遥感GPP算法，综述了不同算法在其研究区域的估算精度；并分析了MODIS/GPP以及BESS/GPP两种遥感GPP产品在不同植被类型的估算精度。通过对比全球碳通量站网络GPP数据表明，MODIS/GPP产品在全球估算结果具显著相关性(

=0.59)及中等标准误差(RMSE=2.86 gC/m

/day)，估算精度较高的植被类型有落叶阔叶林，草地等；估算精度较低类型包括常绿阔叶林，稀树草原等。本文对GPP产品中存在的不确定性进行分析，通过综述前人研究中发现的遥感估算GPP方法中存在的问题，指出可能的提高卫星遥感GPP产品估算精度的方法及发展趋势。

Abstract

Gross primary productivity (GPP) is an important parameter in describing terrestrial ecosystem productivity. This review surveys the existing remote sensing GPP estimation algorithms including vegetation index based and light use efficiency based models and their accuracies

and summarizes two 1 km spatial resolution GPP product accuracy under eight different vegetation types. MOD17

which is the most commonly used GPP product

provides global-scale spatio-temporal continuous data. A strong correlation exists between global-scale MODIS/GPP and in-situ measurement (

=0.59) with medium estimation accuracy (RMSE=2.86 gC/m

/day). Estimation accuracy is high in deciduous broadleaved and evergreen coniferous forests but low in evergreen broadleaved forests and savanna. Finally

we analyze the uncertainties in GPP estimation and verification with the remote sensing method and suggest possible approaches to improve the accuracy of GPP estimation and its development tendency.

关键词

陆地总初级生产力遥感陆地生态系统模型MODIS/GPP产品BESS/GPP产品碳循环全球变化

Keywords

gross primary productivityterrestrial ecosystem modelremote sensing GPP algorithmMODIS/GPP productBESS/GPP productterrestrial carbon cycleglobal change

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