Hybrid cloud and error masking to improve the quality of deterministic satellite sea surface temperature retrieval and data coverage

• Published in: Remote sensing of environment Vol. 174; pp. 266 - 278
• Main Authors: Koner, Prabhat K., Harris, Andrew, Maturi, Eileen
• Format: Journal Article
• Language: English
• Published: Elsevier Inc 01.03.2016
• Subjects: algorithms; Bayesian cloud detection; Cloud detection; GOES-13 imager; Marine; Modified total least squares; radiative transfer; Radiative transfer model; remote sensing; satellites; Sea surface temperature; Spectral differences method; surface water temperature; Cloud detection; Spectral differences method; Radiative transfer model; Bayesian cloud detection; GOES-13 imager; Sea surface temperature; Modified total least squares
• ISSN: 0034-4257; 1879-0704
• DOI: 10.1016/j.rse.2015.12.015

In the infrared region, the quality of sea surface temperature (SST) retrievals critically depends on the cloud detection scheme. More than 5 million matchups, where the surface and top of atmosphere measurements are available, have been carefully analyzed to understand clouds related errors and to develop the advanced cloud detection scheme for improvement of satellite SST quality. The effectiveness of a Bayesian cloud detection (BCD) scheme, operationally implemented at the NOAA Office of Satellite Product Operations (OSPO) for the GOES-Imager, has been examined using an experimental filter and it is found that this scheme is not optimal. Thus, a new algorithm for cloud and error masking (CEM) scheme is proposed for physical SST retrievals. This is based on a quasi-deterministic approach combined with an approximated radiative transfer model and the functional spectral differences at pixel level. Although, traditionally the validation of cloud detection algorithms have often been reported qualitatively using visual inspection of imagery, we have made a quantitative validation of the cloud algorithm for its intended purpose by determining the quality of satellite SST retrievals against in situ data. Results show that CEM can reduce the root mean square error in SST by an average of 22% while increasing the data coverage by an average of 38% compared to the operationally implemented BCD at OSPO, as assessed over a period of fifty months. •Most of the prevalent cloud verification methods are qualitative (visual inspection).•Proposed quantitative method for verification of cloud amount using RT calculation•Demonstrated new cloud detection scheme to outperform over Bayesian cloud detection•Established a deterministic inverse method (MTLS) for operational SST retrievals•Needed for a paradigm shift to open new frontiers in satellite products