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Download OS E2E STUDY C. Mugerin – ARGANS LTD
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OS E2E STUDY C. Mugerin – ARGANS LTD SMOS AlgoVal #14 Barcelona, 29-30 Jan. 2009 Outlines • • • • • • • • MIRE case study Algorithm validation plan Software environment Perfect TB L1OP reconstruction SEPS geometry issues L1OP reconstructed TB with SEPS rotation Conclusion MIRE case study MIRE case study Algorithm validation plan • • • • • SSS retrieval Front effect Coast effect Ice effect Cardioid Software environment • SEPS v1.6 – – – – – • Updated scenarios directory: removed obsolete scenarios, new FTT scenario generated with a different orbit file; DPGS L0 data header have been updated: correlator layer and SEPS-GS version; Back-lobes correction due to respect L1PP version 1.6 definitions, to mitigate SPR 389; Error Budget activities: • SEPS-GS ‘Error’ and ‘No Error’ modes improved, SPR 384; • New SRN section on this subject; Corrected the following SPR: • SPR 290 Only under windows and using Matlab 6.5 is the ionospheric correction still being simulated by the Iri95 routine; L1PP 1.6.0 – – Flat target transformation Gibbs 1 error correction Perfect TB SSS Perfect TB SSS error Perfect TB SSS Perfect TB SSS error Perfect TB SST Perfect TB UN10 Perfect TB VN10 L1OP reconstruction SSS L1OP reconstruction SSS error L1OP reconstruction SSS L1OP reconstruction SSS error SEPS GEOMETRY ISSUES SEPS geometric rotation SEPS geo-localization Extracted from SO-DS-DME-L1PP-0009 L1OP RECONSTRUCTED TB WITH SEPS ROTATION SEPS rotation SSS SEPS rotation SSS error SEPS rotation SSS SEPS rotation SSS error SEPS rotation SSS Retrieval with L1 rotation Retrieval with SEPS rotation SEPS rotation SSS residuals maps SEPS rotation SSS residuals histograms SEPS rotation SSS retrieval cross-plot SEPS rotation AlgoVal #13 Extracted from L1PP TB corrections strategies November 20, 2008 Conclusion • • • • • All the blame was wrongly put on the bias in TB reconstruction. A large improvement resulted from the use the geometrical angles coming from SEPS. Now that the “correct” angles are used in the SSS retrieval, what is left as for the SSS bias is strongly believed to be coming from TB reconstruction bias. The good news is that the bad areas are perfectly correlated now with the shift in the azimuth: the worse the shift the worse the retrieved SSS bias. These are larger error around the poles and extremely small at the equator relative to the error map from the perfect instrument. Additionally the VB map deformation if it is confirmed might take part in the explanation of the change of bias on TB depending on proportion of land. A quick test would be to generate a mat file with the angles coming from L1 and them instead of calling ORINC in SEPS-ACRI to load directly these data so that SEPS can proceed with the correct angles. If Gibbs 2 algorithm is called in L1 processor which makes use of the geometrical angle more error might be introduced than corrected. The residual TB map that will be processed might contain in the end more heterogeneities than the original one… Based on those elements, the calculation of the geometrical angle in SEPS should be corrected if it is not done in version 2.0. Furthermore it seems that in the end the geometric rotation has to be a CFI itself. It is a purely geometrical concept which has little to do with the underlying science. Therefore a CFI would allow every module to speak the same language. In those circumstances the full potential of L2OS algorithm cannot be assessed. Though time might be too short to consider a full upgrade of all components of the end-to-end chain, it should be stressed out that without an accurate simulator that can accurately predict what can be expected from the science implemented in the processors, it would be tedious to decide whether or not the actual accuracy coming out of the real instrument are optimal.
