Abstract
The estimation of biophysical variables from remote sensing data raises important challenges in terms of the acquisition technology and its limitations. In this way, some vegetation parameters, such as chlorophyll fluorescence, require sensors with a high spectral resolution that constrains the spatial resolution while significantly increasing the subpixel land-cover heterogeneity. Precisely, this spatial variability often makes that rather different canopy structures are aggregated together, which eventually generates important deviations in the corresponding parameter quantification. In the context of the Copernicus program (and other related Earth Explorer missions), this article proposes a new statistical methodology to manage the subpixel spatial heterogeneity problem in Sentinel-3 (S3) and FLuorescence EXplorer (FLEX) by taking advantage of the higher spatial resolution of Sentinel-2 (S2). Specifically, the proposed approach first characterizes the subpixel spatial patterns of S3/FLEX using inter-sensor data from S2. Then, a multivariate analysis is conducted to model the influence of these spatial patterns in the errors of the estimated biophysical variables related to chlorophyll which are used as fluorescence proxies. Finally, these modeled distributions are employed to predict the confidence of S3/FLEX products on demand. Our experiments, conducted using multiple operational S2 and simulated S3 data products, reveal the advantages of the proposed methodology to effectively measure the confidence and expected deviations of different vegetation parameters with respect to standard regression algorithms. The source codes of this work will be available at https://github.com/rufernan/PixelS3.
Highlights
S UPPORTED by the increasing availability of data from different Earth observation (EO) missions and programs [1], Manuscript received November 11, 2020; revised January 11, 2021 and February 21, 2021; accepted March 9, 2021
The European Space Agency (ESA) develops the so-called Earth Explorer missions that are focused on addressing specific scientific challenges to advance the understanding of Earth systems and novel EO capabilities
1) Synthetic Inter-Sensor Dataset (SID): This collection includes a total of 22 real multispectral instrument (MSI) images and their corresponding simulated Ocean and Land Color Instrument (OLCI) counterparts in order to sort out the lack of actual ground-truth biophysical measurements
Summary
S UPPORTED by the increasing availability of data from different Earth observation (EO) missions and programs [1], Manuscript received November 11, 2020; revised January 11, 2021 and February 21, 2021; accepted March 9, 2021. Being one of the most important European initiatives, the Copernicus program [5] works for providing global monitoring data from space that are useful for environmental and security applications. The European Space Agency (ESA) develops the so-called Earth Explorer missions that are focused on addressing specific scientific challenges to advance the understanding of Earth systems and novel EO capabilities. Different Sentinel concepts and Earth Explorer missions have been designed to guarantee the operational provision of RS data for dealing with current and future challenges, as well as societal needs [6]
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