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MODIS & VIIRS Ocean Science Team Break-out Report MODIS Science Team Meeting 19-22 May 2015, Silver Spring, MD.

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Presentation on theme: "MODIS & VIIRS Ocean Science Team Break-out Report MODIS Science Team Meeting 19-22 May 2015, Silver Spring, MD."— Presentation transcript:

1 MODIS & VIIRS Ocean Science Team Break-out Report MODIS Science Team Meeting 19-22 May 2015, Silver Spring, MD

2 May 20 Ocean Break-out Agenda

3 May 21

4 MODIS & VIIRS Ocean Processing Status

5 2014.0 Multi-Mission Ocean Reprocessing Scope OC from CZCS, OCTS, SeaWiFS, MERIS, MODIS(A/T), and VIIRS SST from MODIS Motivation 1.improve interoperability and sustainability of the product suite by adopting modern data formats, standards, and conventions 2.incorporate algorithm updates and advances from community and last MODIS Science Team developed since 2010 (last alg. update). 3.incorporate knowledge gained in instrument-specific radiometric calibration and updates to vicarious calibration Status OC from OCTS & VIIRS done, MODISA in progress SST from MODISA and MODIST done (not yet released)

6 Product Development and Documentation

7 Standard, Evaluation, and Test Products a standard product is one that the SIPS is committed to maintain, and the DAAC is committed to archive and distribute, at the ultimate discretion of Program Management an evaluation product is one that the SIPS/DAAC may produce and distribute, if resources allow, to support community assessment of a new product or alternative product algorithm a test product is one that the SIPS may produce to support the algorithm PI in implementation verification and product testing in practice, OC standard products are made at Level-2 and Level-3, while eval products are made only at Level-3 (usually from Level-3 Rrs dailies).

8 OC Implementation NASA Standard Processing Code L2GEN Level-1 to Level-2 (common algorithms) SeaWiFS L1A MODISA L1B MODIST L1B OCTS L1A MOS L1B OSMI L1A CZCS L1A MERIS L1B OCM-1 L1B OCM-2 L1B VIIRS L1A GOCI L1B OLI L1T Level-2 to Level-3 Level-2 Scene observed radiances ancillary data water-leaving reflectances & derived prods Level-3 Global Product vicarious calibration gain factors predicted at-sensor radiances in situ water-leaving radiances (MOBY) sensor-specific tables: Rayleigh, aerosol, etc. 8 

9 SST Implementation NASA Standard Processing Code L2GEN Level-1 to Level-2 (common algorithms) MODISA L1B MODIST L1B VIIRS L1A Level-2 to Level-3 Level-2 Scene observed radiances ancillary data brightness temps & derived SST prods Level-3 Global Product sensor-specific tables: radiance/temperature 9 

10 Product Documentation MODIS has historically required that every standard product have associated with it an Algorithm Theoretical Basis Document (ATBD) The original MODIS ATBDs are extremely out of date and in many cases they are not relevant to current standard products This is largely due to the fact that the MODIS processing was awarded to the NASA OBPG in 2004 with the mandate to adopt the SeaWiFS heritage processing, as documented in SeaWiFS TMs It is also the case that the ocean algorithms are predominantly sensor-independent, evolved from broad community contributions To satisfy NASA Program Management and better serve the research community, we need to establish a new set of product documentation for the current standard product suite of MODIS & VIIRS, and maintain that level of documentation going forward To that end, Ocean SIPS is developing a set of online documents that can be easily updated and will include dynamic links to ensure that implementation and validation information remains current

11 Product and Algorithm Description Document standardized elements Product Summary –defines what it is and what it’s for Algorithm Description –as detailed as necessary to ensure full traceability to algorithm basis and heritage (e.g., links to published literature) –if applicable to multiple sensors, include any sensor-specific modifications required (e.g., adjustments for band passes) –algorithm failure conditions and associated product flags Implementation –how is the product distributed (product suite, file-types, encoding) –direct links to source code and/or software flow charts

12 Assessment –validation analyses (e.g., direct link to dynamic match-ups) –uncertainties References –links to previous ATBD(s) or TM(s), if relevant –links to published literature (DOIs) Product History –document version (date) –product change log Product and Algorithm Description Document standardized elements

13 Product and Algorithm Description Documents

14 Algorithm Description

15 Implementation Details

16 Assessment

17 Product Lifecycle from concept to standard product 1.PI develops new algorithm or modification, demonstrates feasibility, perhaps publishes results. 2.If PI and Ocean Team Leader agree, PI works with SIPS to implement in NASA processing code and to develop a test plan for verification and large-scale testing. 3.If PI is satisfied with implementation tests, and SIPS confirms that required computing resources are available, evaluation products and documentation will be produced and distributed, and the algorithm will be incorporated into SeaDAS. a.PI works with SIPS to develop or update the Product Description Document (to be hosted under “evaluation products”). b.SIPS/DAAC begins production and distribution of product c.PI performs assessment of results (validation, global dist., trends) 4.Before the next mission reprocessing opportunity, PI/SIPS/DAAC and Program Management review the performance evaluation, documentation, and appropriateness for standard production.

18 Ocean Color Products Discussion

19 R2014.0 Changes to OC Standard Product Suite 1.R rs ( ) 2.Ångstrom 3.AOT 4.Chlorophyll a 5.K d (490) 6.POC 7.PIC 8.CDOM_index 9.PAR 10.iPAR 11.nFLH Level-2 OC Product calibration updates, ancillary data updates, improved land/water masking, terrain height, other minor fixes = 412, 443, 469, 488, 531, 547, 555, 645, 667, 678 new algorithm (Hu et al. 2012) coefficient update no change updated algorithm and LUT remove product (redundant with new IOP suite) consolidated algorithm, minor fixes MODIS-only, no change MODIS-only, flagging changes (allow negatives) Algorithm Changes 12. IOPs added suite of inherent optical property products (Werdell et al. 2013)

20 R2014.0 VIIRS OC Standard Product Suite 1.R rs ( ) 2.Ångstrom 3.AOT 4.Chlorophyll a 5.K d (490) 6.POC 7.PIC 8. 9.PAR 10. 11. Level-2 OC Product Spectral water-leaving reflectance and derived aerosol optical properties = 410, 443, 486, 551, 671 Phytoplankton chlorophyll concentration Marine diffuse attenuation at 490nm Particulate organic carbon concentration Particulate inorganic carbon concentration Daily mean photosynthetically available radiation Algorithm Reference 12. IOPs Suite of inherent optical property products (Werdell et al. 2013)

21 Expanded Product Suite - IOPs 21 VIIRS = 410, 443, 486, 551, 671 MODIS = 412, 443, 469, 488, 531, 547, 555, 645, 667, 678 proposed IOP product suite a( )total absorption at all visible wavelengths b b ( )total backscatter at all visible wavelengths a ph ( )phytoplankton absorption at all vis. wavelengths a dg (443) absorption due to colored-detritus at 443nm S dg exponential spectral slope for a dg b bp (443)particle backscattering at 443nm S bp power-law spectral slope for b bp uncertainties uncertainties in a dg, a ph, b bp at 443nm rationale provides total a and b b for input to IOP-based derived product algorithms (e.g., Lee et al. spectral K d, euphotic depth) provides sufficient information to compute full spectral component absorption and scattering coefficients and uncertainties

22 Current Evaluation Products Produced at Level-3 only (from daily binned Rrs) 22 ProductsAlgorithm Chl, a dg (443), b bp (443)Maritorena (GSM) IOPs (a(443), a ph (443), a dg (443), b bp (443)) Lee (QAA) K d (412),K d (443),K d (490)Lee ZeuLee ZeuMorel K PAR Morel

23 USR d (z)/USR(0 - ) K d (USR) [m -1 ] PAR d (z)/PAR(0 - ) K d (PAR) [m -1 ] (Lee et al 2013) PAR: 400-700 nm USR: 400-560 nm Stop producing K d (PAR)

24 SST Coordination Discussion

25 SST Discussion Three SST PIs selected for VIIRS: 1.Andy Harris : A Deterministic Inverse Method for SST Retrieval from VIIRS 2.Frank Wentz: Analysis and Mitigation of Atmospheric Crosstalk (using AMSR-2 microwave measurements) 3.Peter Minnett: Sea-Surface Temperature from VIIRS-Extending the MODIS Time Series For Climate Data Records. All are directed to deriving accurate SST from VIIRS; three very different approaches to achieve the same goal. Good progress has been made by all groups in the first months of the projects.

26 Next steps All projects require independent in situ measurements to validate the different approaches to correct for the effects of the intervening atmosphere. Subsurface measurements provided by drifting and moored buoys provide the most numerous validating measurements. A provisional set of matchups between VIIRS brightness temperatures (from NOAA CLASS) has been developed at RSMAS. –This will be shared with the other groups. Ocean SIPS plans to generate NASA VIIRS BT’s; and a more comprehensive match-up data base will be generated. Additional variables in the new match-up data base will be included to enhance its utility. –SST groups will coordinate with Ocean SIPS for contents of new database The breakout session was a very useful way of each group sharing ideas and reporting progress. A dialogue with the Ocean SIPS has begun

27 Questions?

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