Publications

Pelucchi, P; Servera, JV; Stier, P; Camps-Valls, G (2025). Invertible Neural Networks for Probabilistic Aerosol Optical Depth Retrieval. IEEE TRANSACTIONS ON GEOSCIENCE AND REMOTE SENSING, 63, 4102813.

Abstract
Satellite remote sensing is the primary source of global aerosol observations, providing essential data for understanding aerosol-climate interactions and constraining global climate models. To solve the inverse problem at the heart of the retrieval process, traditional algorithms must make simplifications and often cannot quantify uncertainty. In this study, we explore the use of invertible neural networks (INNs) for retrieving aerosol optical depth (AOD) from spectral top-of-atmosphere (TOA) reflectance. INNs can handle the inherent uncertainty of underdetermined inverse problems. They model the forward and inverse processes simultaneously while learning additional random latent variables used to recover full nonparametric posterior distributions for the inverse predictions. We develop location-specific INNs for MODIS sensor data, training on synthetic datasets generated by combining atmospheric reflectance from MODIS dark target (DT) lookup tables (LUTs) and surface reflectance from a MODIS bidirectional reflectance product. The INNs successfully emulate the forward problem and achieve accurate AOD inversion results on synthetic test sets (RMSE approximate to 0.05). The posterior distributions obtained are reliable (mean absolute calibration error (MACE) approximate to 2.5%), efficiently providing informative predictive uncertainty estimates. In addition, the INNs' invertible architecture is found to promote physically consistent predictions and uncertainties. To further validate them in a real-world context, the INNs are applied to MODIS L1B reflectance observations to produce full-resolution AOD estimates with pixel-level uncertainties. The retrievals are compared to collocated ground measurements from the Aeronet network. The INNs obtain good accuracy in all tested locations in line with the operational DT AOD product (RMSE approximate to 0.1, 74% within DT expected error (EE) bounds). The INNs are also able to retrieve AOD over bright surfaces where DT cannot be applied. Despite uncovered limitations out-of-distribution, the INNs show consistent skill in target domains across diverse land surfaces. The INNs' unique modeling and uncertainty quantification features have the potential to enhance aerosol and climate studies in various real-world contexts.

DOI:
10.1109/TGRS.2025.3540173

ISSN:
1558-0644