4.7 Article

Validation of baseline and modified Sentinel-2 Level 2 Prototype Processor leaf area index retrievals over the United States

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Publisher

ELSEVIER
DOI: 10.1016/j.isprsjprs.2021.02.020

Keywords

GBOV; LAI; MSI; NEON; SL2P; SL2P-D

Funding

  1. European Commission Joint Research Centre, part of the Global Component of the European Union's Copernicus Land Monitoring Service [FWC 932059]
  2. National Science Foundation
  3. National Science Foundation through the NEON Program
  4. Natural Resources Canada
  5. Canadian Space Agency
  6. European Union [101004242]

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The study shows that SL2P performs well in agricultural environments but poorly in heterogeneous canopies like forests. The modified version SL2P-D exhibits reduced bias and higher number of valid retrievals compared to SL2P.
The Sentinel-2 Level 2 Prototype Processor (SL2P) is made available to users for the retrieval of vegetation biophysical variables including leaf area index (LAI) from Multispectral Instrument (MSI) data within the Sentinel Application Platform (SNAP). A limited number of validation exercises have indicated SL2P LAI retrievals frequently meet user requirements over agricultural environments, but perform comparatively poorly over heterogeneous canopies such as forests. Recently, a modified version of SL2P was developed, using the directional area scattering factor (DASF) to constrain retrievals as an alternative to regularisation (SL2P-D). Whilst SL2P makes use of prior information on expected canopy conditions, SL2P-D is trained using uniform distributions of input parameters to define radiative transfer model (RTM) simulations. Using in situ measurements available through the Copernicus Ground Based Observations for Validation (GBOV) service, we performed an extensive validation of SL2P and SL2P-D LAI retrievals over 19 sites throughout the United States. For effective LAI (LAI(e)), SL2P demonstrated good overall performance (RMSD = 0.50, NRMSD = 31%, bias = -0.10), with all LAI retrievals meeting the Sentinels for Science (SEN4SCI) uncertainty requirements over homogeneous canopies (cultivated crops, grasslands, pasture/hay and shrub/scrub), whilst underestimation occurred over heterogeneous canopies (deciduous forest, evergreen forest, mixed forest, and woody wetlands). SL2P-D retrievals demonstrated reduced bias, slightly improving overall performance when compared with SL2P (RMSD = 0.48, NRMSD = 30%, bias = -0.05), indicating its retrieval approach appears to offer some advantages over regularisation using prior information, especially at LAI(e) > 3. Additionally, SL2P-D resulted in 32% more valid retrievals than SL2P, with the largest differences observed at LAI(e) < 1. Validation against in situ measurements of LAI as opposed to LAIe yielded similar patterns but poorer performance (RMSD = 1.08 to 1.13, NRMSD = 49% to 52%, bias = -0.64 to -0.68) because the RTM used by SL2P and SL2P-D does not account for foliage clumping. In addition to the retrievals themselves, we examined the relationship between predicted uncertainties and observed differences in retrieved and in situ LAI. With respect to LAI(e), SL2P's predicted uncertainties were conservative, underestimating observed differences in only 35% of cases, whilst those for LAI were unbiased.

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