Timeline and Overview of the SRAL/MWR Processing Baselines of Sentinel-3.
|Baseline Collection 003||PB 2.27||PB 2.33/1.13*||PB 2.45|
|IPF versions||SRAL L1 (SR-1): 06.13
MWR L1 (MW-1): 06.04
SRAL/MWR L2 (SM-2): 06.12
|SRAL L1 (SR-1): 06.14
MWR L1 (MW-1): 06.07
SRAL/MWR L2 (SM-2): 06.14
* PB1.13: same IPF versions; it only includes some static Auxiliary Data Files (ADFs) which are specific to S3B
|SRAL L1 (SR-1): 06.16
MWR L1 (MW-1): 06.09
SRAL/MWR L2 (SM-2): 06.15
|Product Notice||L1 PN (2.27)
L2 PN (2.27)
|L1 PN (2.33)
L2 PN (2.33)
L1 PN (2.33/1.13)
L2 PN (2.33/1.13)
|L1 PN (2.45)
L2 PN (2.45)
|PB Deployment date (NRT)||14/02/2018||04/04/2018 (S3A, PB2.33)
06/12/2018 (S3B, PB 1.13)
(sensing time & server)
|Manifest file||ANX information is more accurately computed.||Correction of spurious gaps being reported on the manifest, due to the application of the land-sea mask.|
|SWH||SAR SWH calculated directly from SAMOSA retracker outputs, bypassing the composite sigma (sigma_c)||Update of LUT to improve SWH w.r.t. ECMWF’s model.|
|Sea Ice||Major improvement in sea retrievals and freeboard.|
|Dry tropo||Correction of 5 mm bias IR with respect to z.|
|New parameters||Elevation derived from OCOG retracking [elevation_ocog_20_ku]: expected to be useful near the coast, on icy surfaces and inland water bodies (such as the Great Lakes and Lake Victoria).
Geophysical corrections are applied to this field.
|Other fixes or changes in the PBs||
||Corrected C Band longitude and latitude:
Corrected LRM variables:
*PB 1.13 (S3B): Correction of issues noted during S3B commissioning:Bias is sigma0 w.r.t. to S3A in Ku and C bands
(this generated incorrect wind speed retrieval and incorrect flagging of rain).
Fine tuning of the MWR brightness temperatures in order to align it to S3A
(a few millimeters difference was visible in the radiometer wet tropospheric correction —now corrected).
|Changes to Ground Segment or Spacecraft||18/12/2017: New zone database used in operations to avoid small (sub/seconds) data gaps near the Greenwich meridian.||01/03/2018: New MWR calibration strategy reduces the number of occasions where the MWR values are set to default.
28/05/2018: Improved orbit quality in STC: since the STC orbits have been generated by CNES/SALP using GNSS data, as well as DORIS data. This allows for better orbit quality and fewer differences when comparing to the NTC orbits.
10/11/2018: Updated standard for CNES orbits (POE-F): since cycle 38 of S3A (STC and NTC) the orbits solutions generated by CNES/SALP use the new standard POE-F.
20/09/2018: Improved cut of the pole to pole pass (and pass numbering and ANX crossing time): the information on when to cut to the pole to pole passes (STC and NTC) is derived from several system components that were fixed at different points in time. Since 20/09/2018 the situation has been completely fixed for L1 and L2. The reprocessed dataset (up to 20/01/2018) is correct.
27/11/2018: Improved data quality at pass transition (STC and NTC): the data present in L1/L2 passes had a degradation at pass transition, due to the fact that adjacent granules were not provided to the processor. This degradation has been
corrected since 27/11/2018.
|17/01/2019: The KREMS safe zone for both S3A and S3B has been enlarged to avoid any damaged to the MWR instrument, currently there is a radius of 300 km around this radar facility. In this safe zone the radiometer is disabled and thus there is no wet tropospheric correction available from the radiometer, causing the SSHA to be set to a default value. A decrease of the safe zone radius is foreseen in the following weeks.|