Optimal Exploitation of the Sentinel-2 Spectral Capabilities for Crop Leaf Area Index Mapping

Optimal Exploitation of the Sentinel-2 Spectral Capabilities for Crop Leaf Area Index Mapping

The continuously increasing demand of accurate quantitative high quality information on land surface properties will be faced by a new generation of environmental Earth observation (EO) missions. One current example, associated with a high potential to contribute to those demands, is the multi-spect...

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Bibliographic Details
Published in:Remote sensing (Basel, Switzerland) Vol. 4; no. 3; pp. 561 - 582
Main Authors: Richter, Katja, Hank, Tobias B., Vuolo, Francesco, Mauser, Wolfram, D’Urso, Guido
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-03-2012
Subjects:
artificial neural networks
leaf area index
look-up table
model inversion
Neural networks
optimal spectral sampling
Optimization techniques
PROSAIL model
Radiation
Radiative transfer
Remote sensing
Satellites
Sensors
Sentinel-2
Variables
Vegetation
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Summary:The continuously increasing demand of accurate quantitative high quality information on land surface properties will be faced by a new generation of environmental Earth observation (EO) missions. One current example, associated with a high potential to contribute to those demands, is the multi-spectral ESA Sentinel-2 (S2) system. The present study focuses on the evaluation of spectral information content needed for crop leaf area index (LAI) mapping in view of the future sensors. Data from a field campaign were used to determine the optimal spectral sampling from available S2 bands applying inversion of a radiative transfer model (PROSAIL) with look-up table (LUT) and artificial neural network (ANN) approaches. Overall LAI estimation performance of the proposed LUT approach (LUTN50) was comparable in terms of retrieval performances with a tested and approved ANN method. Employing seven- and eight-band combinations, the LUTN50 approach obtained LAI RMSE of 0.53 and normalized LAI RMSE of 0.12, which was comparable to the results of the ANN. However, the LUTN50 method showed a higher robustness and insensitivity to different band settings. Most frequently selected wavebands were located in near infrared and red edge spectral regions. In conclusion, our results emphasize the potential benefits of the Sentinel-2 mission for agricultural applications.
ISSN:2072-4292
2072-4292
DOI:10.3390/rs4030561