Your search keyword '"Vergely, Jean-Luc"' showing total 2 results

1. Satellite and In Situ Sampling Mismatches: Consequences for the Estimation of Satellite Sea Surface Salinity Uncertainties.

Author

Thouvenin-Masson, Clovis, Boutin, Jacqueline, Vergely, Jean-Luc, Reverdin, Gilles, Martin, Adrien C. H., Guimbard, Sébastien, Reul, Nicolas, Sabia, Roberto, Catany, Rafael, and Hembise Fanton-d'Andon, Odile

Subjects

DISTRIBUTION (Probability theory), SALINITY, REGIONS of freshwater influence, GAUSSIAN distribution, STANDARD deviations, OCEAN

Abstract

Validation of satellite sea surface salinity (SSS) products is typically based on comparisons with in-situ measurements at a few meters' depth, which are mostly done at a single location and time. The difference in term of spatio-temporal resolution between the in-situ near-surface salinity and the two-dimensional satellite SSS results in a sampling mismatch uncertainty. The Climate Change Initiative (CCI) project has merged SSS from three satellite missions. Using an optimal interpolation, weekly and monthly SSS and their uncertainties are estimated at a 50 km spatial resolution over the global ocean. Over the 2016–2018 period, the mean uncertainty on weekly CCI SSS is 0.13, whereas the standard deviation of weekly CCI minus in-situ Argo salinities is 0.24. Using SSS from a high-resolution model reanalysis, we estimate the expected uncertainty due to the CCI versus Argo sampling mismatch. Most of the largest spatial variability of the satellite minus Argo salinity is observed in regions with large estimated sampling mismatch. A quantitative validation is performed by considering the statistical distribution of the CCI minus Argo salinity normalized by the sampling and retrieval uncertainties. This quantity should follow a Gaussian distribution with a standard deviation of 1, if all uncertainty contributions are properly taken into account. We find that (1) the observed differences between Argo and CCI data in dynamical regions (river plumes, fronts) are mainly due to the sampling mismatch; (2) overall, the uncertainties are well estimated in CCI version 3, much improved compared to CCI version 2. There are a few dynamical regions where discrepancies remain and where the satellite SSS, their associated uncertainties and the sampling mismatch estimates should be further validated. [ABSTRACT FROM AUTHOR]

Published

2022

2. Results of the Dragon 4 Project on New Ocean Remote Sensing Data for Operational Applications.

Author

Gibert, Ferran, Boutin, Jacqueline, Dierking, Wolfgang, Granados, Alba, Li, Yan, Makhoul, Eduard, Meng, Junmin, Supply, Alexandre, Vendrell, Ester, Vergely, Jean-Luc, Wang, Jin, Yang, Jungang, Xiang, Kunsheng, Yin, Xiaobin, and Zhang, Xi

Subjects

REMOTE sensing, SEA ice drift, WIND speed measurement, MESOSCALE eddies, MICROWAVE radiometers, SEA ice, GLACIAL drift

Abstract

This paper provides an overview of the Dragon 4 project dealing with operational monitoring of sea ice and sea surface salinity (SSS) and new product developments for altimetry data. To improve sea ice thickness retrieval, a new method was developed to match the Cryosat-2 radar waveform. Additionally, an automated sea ice drift detection scheme was developed and tested on Sentinel-1 data, and the sea ice drifty capability of Gaofen-4 geostationary optical data was evaluated. A second topic included implementation and validation of a prototype of a Fully-Focussed SAR processor adapted for Sentinel-3 and Sentinel-6 altimeters and evaluation of its performance with Sentinel-3 data over the Yellow Sea; the assessment of sea surface height (SSH), significant wave height (SWH), and wind speed measurements using different altimeters and CFOSAT SWIM; and the fusion of SSH measurements in mapping sea level anomaly (SLA) data to detect mesoscale eddies. Thirdly, the investigations on the retrieval of SSS include simulations to analyse the performances of the Chinese payload configurations of the Interferometric Microwave Radiometer and the Microwave Imager Combined Active and Passive, SSS retrieval under rain conditions, and the combination of active and passive microwave to study extreme winds. [ABSTRACT FROM AUTHOR]

Published

2021