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利用谷歌地球引擎中的哨兵-3 OLCI目录对欧洲的基本植被特征进行量化。

Quantifying Fundamental Vegetation Traits over Europe Using the Sentinel-3 OLCI Catalogue in Google Earth Engine.

作者信息

Reyes-Muñoz Pablo, Pipia Luca, Salinero-Delgado Matías, Belda Santiago, Berger Katja, Estévez José, Morata Miguel, Rivera-Caicedo Juan Pablo, Verrelst Jochem

机构信息

Image Processing Laboratory (IPL), University of Valencia, 46980 Paterna, Spain.

Institut Cartografic i Geologic de Catalunya (ICGC), Parc de Montjüic, 08038 Barcelona, Spain.

出版信息

Remote Sens (Basel). 2022 Mar 10;14(6):1347. doi: 10.3390/rs14061347.

DOI:10.3390/rs14061347
PMID:36016907
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7613398/
Abstract

Thanks to the emergence of cloud-computing platforms and the ability of machine learning methods to solve prediction problems efficiently, this work presents a workflow to automate spatiotemporal mapping of essential vegetation traits from Sentinel-3 (S3) imagery. The traits included leaf chlorophyll content (LCC), leaf area index (LAI), fraction of absorbed photosynthetically active radiation (FAPAR), and fractional vegetation cover (FVC), being fundamental for assessing photosynthetic activity on Earth. The workflow involved Gaussian process regression (GPR) algorithms trained on top-of-atmosphere (TOA) radiance simulations generated by the coupled canopy radiative transfer model (RTM) SCOPE and the atmospheric RTM 6SV. The retrieval models, named to S3-TOA-GPR-1.0, were directly implemented in Google Earth Engine (GEE) to enable the quantification of the traits from TOA data as acquired from the S3 Ocean and Land Colour Instrument (OLCI) sensor.Following good to high theoretical validation results with normalized root mean square error (NRMSE) ranging from 5% (FAPAR) to 19% (LAI), a three fold evaluation approach over diverse sites and land cover types was pursued: (1) temporal comparison against LAI and FAPAR products obtained from Moderate Resolution Imaging Spectroradiometer (MODIS) for the time window 2016-2020, (2) spatial difference mapping with Copernicus Global Land Service (CGLS) estimates, and (3) direct validation using interpolated in situ data from the VALERI network. For all three approaches, promising results were achieved. Selected sites demonstrated coherent seasonal patterns compared to LAI and FAPAR MODIS products, with differences between spatially averaged temporal patterns of only 6.59%. In respect of the spatial mapping comparison, estimates provided by the S3-TOA-GPR-1.0 models indicated highest consistency with FVC and FAPAR CGLS products. Moreover, the direct validation of our S3-TOA-GPR-1.0 models against VALERI estimates indicated with regard to jurisdictional claims in good retrieval performance for LAI, FAPAR and FVC. We conclude that our retrieval workflow of spatiotemporal S3 TOA data processing into GEE opens the path towards global monitoring of fundamental vegetation traits, accessible to the whole research community.

摘要

得益于云计算平台的出现以及机器学习方法高效解决预测问题的能力,这项工作提出了一种工作流程,用于从哨兵-3(S3)图像中自动进行关键植被特征的时空映射。这些特征包括叶片叶绿素含量(LCC)、叶面积指数(LAI)、光合有效辐射吸收比例(FAPAR)和植被覆盖度(FVC),它们是评估地球光合活动的基础。该工作流程涉及高斯过程回归(GPR)算法,这些算法是基于由耦合冠层辐射传输模型(RTM)SCOPE和大气RTM 6SV生成的大气顶(TOA)辐射模拟进行训练的。名为S3-TOA-GPR-1.0的反演模型直接在谷歌地球引擎(GEE)中实现,以便能够从S3海洋和陆地颜色仪器(OLCI)传感器获取的TOA数据中量化这些特征。在归一化均方根误差(NRMSE)范围从5%(FAPAR)到19%(LAI)的良好到高度理论验证结果之后,针对不同地点和土地覆盖类型采用了三重评估方法:(1)在2016 - 2020时间窗口内与从中分辨率成像光谱仪(MODIS)获得的LAI和FAPAR产品进行时间比较,(2)与哥白尼全球陆地服务(CGLS)估计值进行空间差异映射,以及(3)使用来自VALERI网络的插值实地数据进行直接验证。对于所有这三种方法,都取得了有前景的结果。与LAI和FAPAR MODIS产品相比,选定地点展示出连贯的季节模式,空间平均时间模式之间的差异仅为6.59%。在空间映射比较方面,S3-TOA-GPR-1.0模型提供的估计值表明与FVC和FAPAR CGLS产品具有最高的一致性。此外,我们的S3-TOA-GPR-1.0模型针对VALERI估计值的直接验证表明,在LAI、FAPAR和FVC的反演性能方面具有良好的管辖声明。我们得出结论,我们将S3 TOA数据进行时空处理并输入GEE的反演工作流程为全球监测基础植被特征开辟了道路,整个研究界都可以使用。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c361/7613398/6c3ac4320d2c/EMS152682-f009.jpg
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