Physics-based Machine Learning Emulator of At-sensor Radiances for Solar-induced Fluorescence Retrieval in the O -A Absorption Band

The successful operation of airborne and space-based spectrometers in recent years holds the promise to map solar-induced fluorescence (SIF) accurately across the globe. Machine learning (ML) can play an important role in this effort, but its application to SIF retrieval methods is in part hindered...

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Bibliographic Details
Published inIEEE journal of selected topics in applied earth observations and remote sensing pp. 1 - 10
Main Authors Pato, Miguel, Buffat, Jim, Alonso, Kevin, Auer, Stefan, Carmona, Emiliano, Maier, Stefan, Muller, Rupert, Rademske, Patrick, Rascher, Uwe, Scharr, Hanno
Format Journal Article
LanguageEnglish
Published IEEE 09.09.2024
Subjects
Absorption
Atmospheric modeling
Geometry
hyperspectral sensors
Instruments
machine learning
Optical surface waves
Polynomials
radiative transfer
solar-induced fluorescence
Terrestrial atmosphere
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Summary:The successful operation of airborne and space-based spectrometers in recent years holds the promise to map solar-induced fluorescence (SIF) accurately across the globe. Machine learning (ML) can play an important role in this effort, but its application to SIF retrieval methods is in part hindered by the need for time-consuming radiative transfer modelling to account for atmospheric effects. In this work, we address this difficulty and develop a fast and accurate physics-based ML emulator of at-sensor radiances around the O <inline-formula><tex-math notation="LaTeX">_{2}</tex-math></inline-formula>-A absorption band for the space-based DESIS and the airborne HyPlant spectrometers. Different ML models are trained on an extensive set of simulated spectra encompassing a wide range of atmosphere, geometry, surface and sensor configurations. A fourth-degree polynomial model is found to perform best, presenting errors at or below 10% of typical SIF at-sensor radiances and a prediction time per sample spectrum of 10-20 <inline-formula><tex-math notation="LaTeX">\mu</tex-math></inline-formula> s. Using data acquired with the HyPlant instrument, the proposed model is also shown to be able to match very closely the measured spectra. We illustrate how to improve further the accuracy of the emulator and how to generalize it to other sensors using the particular case of ESA's FLEX space mission. Our findings suggest that physics-based emulators can be efficiently used for the development of ML-based SIF retrieval methods by generating large training data sets in short time and by enabling a fast simulation step for self-supervised retrieval schemes.
ISSN:1939-1404
2151-1535
DOI:10.1109/JSTARS.2024.3457231