NASA Ocean Color Research Team Meeting, Silver Spring, Maryland 5-7 May 2014 II. Objectives Establish a high-quality long-term observational time series.

Slides:

Advertisements

Similar presentations

A33C-0161 On the New Satellite Aerosol Measurements for Atmospheric Applications: VIIRS Aerosol Products Summary Different match-up criteria also were.

Advertisements

MODIS Atmosphere Solar Reflectance Issues 1. Aqua VNIR focal plane empirical re-registration status Ralf Bennartz, Bob Holz, Steve Platnick 2 1 U. Wisconsin,

What’s new in MODIS Collection 6 Aerosol Deep Blue Products? N. Christina Hsu, Rick Hansell, MJ Jeong, Jingfeng Huang, and Jeremy Warner Photo taken from.

1 A Temporally Consistent NO 2 data record for Ocean Color Work Wayne Robinson, Ziauddin Ahmad, Charles McClain, Ocean Biology Processing Group (OBPG)

Characterization of radiance uncertainties for SeaWiFS and Modis-Aqua Introduction The spectral remote sensing reflectance is arguably the most important.

AERONET-OC: Gloria Istanbul, November Giuseppe Zibordi.

Evaluation of atmospheric correction algorithms for MODIS Aqua in coastal regions Goyens, C., Jamet, C., and Loisel, H. Atmospheric correction workshop.

Error bar estimates Estimates of the uncertainties on input LwN Estimates of the error model Estimates of the uncertainties on outputs Chla, bbp,cdm (Co-variance.

Radiometric Calibration of Current and Future Ocean Color Satellite Sensors R. Foster, S. Hlaing, A. Gilerson, S. Ahmed Robert Foster, ME, LEED AP Optical.

Seasonal to Interannual Variability in Phytoplankton Biomass and Diversity on the New England Shelf: In Situ Time Series for Validation and Exploration.

Seasonal to Interannual Variability in Phytoplankton Biomass and Diversity on the New England Shelf Heidi M. Sosik Hui Feng In Situ Time Series for Validation.

Menghua Wang NOAA/NESDIS/ORA E/RA3, Room 102, 5200 Auth Rd.

European Geosciences Union General Assembly 2006 Vienna, Austria, 02 – 07 April 2006 Paper’s objectives: 1. Contribute to the validation of MODIS aerosol.

1 Calibration Adjustments for the MODIS Aqua 2015 Ocean Color Reprocessing Gerhard Meister, NASA Code 616 OBPG (Ocean Biology Processing Group) 5/18/2015.

PACE AEROSOL CAL/VAL Cameron McNaughton Golder Associates Ltd.

Seasonal to Interannual Variability in Phytoplankton Biomass and Diversity on the New England Shelf Heidi M. Sosik Hui Feng In Situ Time Series for Validation.

Surface Reflectance over Land: Extending MODIS to VIIRS Eric Vermote NASA GSFC Code 619 MODIS/VIIRS Science Team Meeting, May.

S. Ahmed 1*, A. Gilerson 1, T. Harmel 2, S. Hlaing 1, A. Tonizzo 1, A. Weidemann 3, R. Arnone 3 1 Evaluation of atmospheric correction procedures for ocean.

In situ science in support of satellite ocean color objectives Jeremy Werdell NASA Goddard Space Flight Center Science Systems & Applications, Inc. 6 Jun.

Aircraft spiral on July 20, 2011 at 14 UTC Validation of GOES-R ABI Surface PM2.5 Concentrations using AIRNOW and Aircraft Data Shobha Kondragunta (NOAA),

A Comparison of Particulate Organic Carbon (POC) from In situ and Satellite Ocean Color Data Off the Coast of Antarctica Amanda Hyde Antonio Mannino (advisor)

Atmospheric Correction Algorithms for Remote Sensing of Open and Coastal Waters Zia Ahmad Ocean Biology Processing Group (OBPG) NASA- Goddard Space Flight.

VALIDATION OF SUOMI NPP/VIIRS OPERATIONAL AEROSOL PRODUCTS THROUGH MULTI-SENSOR INTERCOMPARISONS Huang, J. I. Laszlo, S. Kondragunta,

SeaDAS Training ~ NASA Ocean Biology Processing Group 1 Level-2 ocean color data processing basics NASA Ocean Biology Processing Group Goddard Space Flight.

Menghua Wang, NOAA/NESDIS/ORA Atmospheric Correction using the MODIS SWIR Bands (1240 and 2130 nm) Menghua Wang (PI, NASA NNG05HL35I) NOAA/NESDIS/ORA Camp.

Retrieving Coastal Optical Properties from MERIS S. Ladner 1, P. Lyon 2, R. Arnone 2, R. Gould 2, T. Lawson 1, P. Martinolich 1 1) QinetiQ North America,

Monitoring Bio-Optical Processes Using NPP-VIIRS And MODIS-Aqua Ocean Color Products Robert Arnone (1), Sherwin Ladner (2), Giulietta Fargion (3), Paul.

High Resolution MODIS Ocean Color Fred Patt 1, Bryan Franz 1, Gerhard Meister 2, P. Jeremy Werdell 3 NASA Ocean Biology Processing Group 1 Science Applications.

Evaluation of VIIRS ocean color data using measurements from the AERONET-OC sites Samir Ahmed* a, Alex Gilerson a, Soe Hlaing a, Ioannis Ioannou a, Menghua.

Ocean Color Radiometer Measurements of Long Island Sound Coastal Observational platform (LISCO): Comparisons with Satellite Data & Assessments of Uncertainties.

Soe Hlaing *, Alex Gilerson, Samir Ahmed Optical Remote Sensing Laboratory, NOAA-CREST The City College of the City University of New York 1 A Bidirectional.

Menghua Wang, NOAA/NESDIS/STAR Remote Sensing of Water Properties Using the SWIR- based Atmospheric Correction Algorithm Menghua Wang Wei Shi and SeungHyun.

Center for Satellite Applications and Research (STAR) Review 09 – 11 March 2010 Image: MODIS Land Group, NASA GSFC March 2000 Image: MODIS Land Group,

MODIS Ocean Color Processing Chuck McClain* Processing Approach Calibration/Validation Gene Feldman* Data Processing & Distribution MODIS Team Meeting/

MODIS OCEAN QA Browse Imagery (MQABI Browse Tool) NASA Goddard Space Flight Center Sept 4, 2003

Center for Satellite Applications and Research (STAR) Review 09 – 11 March 2010 Image: MODIS Land Group, NASA GSFC March 2000 Presented by Menghua Wang.

Optical Water Mass Classification for Interpretation of Coastal Carbon Flux Processes R.W. Gould, Jr. & R.A. Arnone Naval Research Laboratory, Code 7333,

QA filtering of individual pixels to enable a more accurate validation of aerosol products Maksym Petrenko Presented at MODIS Collection 7 and beyond Retreat.

Menghua Wang, NOAA/NESDIS/ORA Refinement of MODIS Atmospheric Correction Algorithm Menghua Wang (PI, NASA NNG05HL35I) NOAA/NESDIS/ORA Camp Springs, MD.

As components of the GOES-R ABI Air Quality products, a multi-channel algorithm similar to MODIS/VIIRS for NOAA’s next generation geostationary satellite.

1 N. Christina Hsu, Deputy NPP Project Scientist Recent Update on MODIS C6 Deep Blue Aerosol Products and Beyond N. Christina Hsu, Corey Bettenhausen,

Synergy of MODIS Deep Blue and Operational Aerosol Products with MISR and SeaWiFS N. Christina Hsu and S.-C. Tsay, M. D. King, M.-J. Jeong NASA Goddard.

VIIRS Product Evaluation at the Ocean PEATE Frederick S. Patt Gene C. Feldman IGARSS 2010 July 27, 2010.

Validation of Coastwatch Ocean Color products S. Ramachandran, R. Sinha ( SP Systems NOAA/NESDIS) Kent Hughes and C. W. Brown ( NOAA/NESDIS/ORA,

Azimuthal Variation of Hurricane Waves (1) Problem: How do ocean waves in the vicinity of a hurricane vary in height, wavelength, propagation direction.

Center for Satellite Applications and Research (STAR) Review 09 – 11 March 2010 Satellite Observation and Model Simulation of Water Turbidity in the Chesapeake.

SeaWiFS Calibration & Validation Strategy & Results Charles R. McClain SeaWiFS Project Scientist NASA/Goddard Space Flight Center February 11, 2004.

IOP algorithm OOXX Jeremy Werdell & Bryan Franz NASA Ocean Biology Processing Group 25 Sep 2010, Anchorage, AK

Center for Satellite Applications and Research (STAR) Review 09 – 11 March 2010 Image: MODIS Land Group, NASA GSFC March 2000 Image: MODIS Land Group,

Intercomparison of satellite retrieved aerosol optical depth over ocean G. Myhre, F. Stordal, M. Johnsrud, A. Ignatov, M.I. Mishchenko, I.V. Geogdzhayev,

Seasonal to Interannual Variability in Phytoplankton Biomass and Diversity on the New England Shelf Heidi M. Sosik Hui Feng In Situ Time Series for Validation.

New Aerosol Models for Ocean Color Retrievals Zia Ahmad NASA-Ocean Biology Processing Group (OBPG) MODIS Meeting May 18-20, 2011.

NASA’s Coastal and Ocean Airborne Science Testbed (COAST) L. Guild 1, J. Dungan 1, M. Edwards 1, P. Russell 1, J. Morrow 2, S. Hooker 3, J. Myers 4, R.

MODIS Atmosphere Products: The Importance of Record Quality and Length in Quantifying Trends and Correlations S. Platnick 1, N. Amarasinghe 1,2, P. Hubanks.

International Ocean Color Science Meeting, Darmstadt, Germany, May 6-8, 2013 III. MODIS-Aqua normalized water leaving radiance nLw III.1. R2010 vs. R2012.

Center for Satellite Applications and Research (STAR) Review 09 – 11 March 2010 Marine Environmental Responses to the Saemangeum Reclamation Project in.

NASA, CGMS-44, 7 June 2016 Coordination Group for Meteorological Satellites - CGMS SURFACE PRESSURE MEASUREMENTS FROM THE ORBITING CARBON OBSERVATORY-2.

International GHRSST User Symposium Santa Rosa, California, USA 28-29th May 2009 MODIS Sea-Surface Temperatures Peter J Minnett & Robert H. Evans With.

Incorporating Satellite Time-Series data into Modeling Watson Gregg NASA/GSFC/Global Modeling and Assimilation Office Topics: Models, Satellite, and In.

Ocean Sciences The oceans cover 3/4 of the Earth’s surface. They provide the thermal memory for the global climate system, and are a major reservoir of.

Date of download: 6/22/2016 Copyright © 2016 SPIE. All rights reserved. Schematic representation of the near-infrared (NIR) structured illumination instrument,

Dimitry Van der Zande – RBINS Kevin Ruddick - RBINS

Fourth TEMPO Science Team Meeting

Paper under review for JGR-Atmospheres …

IMAGERY DERIVED CURRENTS FROM NPP Ocean Color Products 110 minutes!

Estimating PM2.5 using MODIS and GOES aerosol optical depth retrievals in IDEA Hai Zhang , Raymond M. Hoff1 , Shobha Kondragunta2.

G. Myhre, F. Stordal, M. Johnsrud, A. Ignatov, M. I. Mishchenko, I. V

Recent activities of OCR-VC

Igor Appel Alexander Kokhanovsky

Assessment of Satellite Ocean Color Products of the Coast of Martha’s Vineyard using AERONET-Ocean Color Measurements Hui Feng1, Heidi Sosik2 , and Tim.

Presentation transcript:

NASA Ocean Color Research Team Meeting, Silver Spring, Maryland 5-7 May 2014 II. Objectives Establish a high-quality long-term observational time series dedicated to satellite ocean color product validation at a NW Atlantic coastal site (MVCO) for the ocean color community Extend and analyze the existing AERONET-OC times series at MVCO for coastal ocean color validation Quantify major uncertainties in satellite ocean color retrievals, and understand temporal and spatial variability of these uncertainties Identify the potential causes (e.g. due to misrepresentative aerosol models or in- water algorithms) leading to these uncertainties Examine coastal validation (and calibration) approaches Explore potential satellite ocean color atmospheric corrections Location, Platform, Instrument The Air-Sea Interaction Tower (ASIT) is located about 3 km offshore in 15.6 m of water. The SeaPRISM is deployed on ASIT at the Martha's Vineyard Coastal Observatory (latitude=41.3; longitude=70.57). IV. Cross validation of MODIS-Aqua aerosol properties by Ocean Color (OCN) and Atmosphere (ATM) teamsIII. Validation of satellite water leaving radiance product from different missions reprocessing SeaWiFS reprocessing 2010 MODIS-Aqua reprocessing 2012 MODIS-Aqua SWIR-based Vs. NIR-based atmosphere correction SWIR based atmospheric correction does not help to improve nLw retrieval performance (Not shown ) Method Data Sources - MODIS-ATM on Aqua: Collection 5 - MODIS-OC on Aqua: *reprocessing (from 2002 to 2010) *reprocessing (from 2011 to 2013) - AERONET Level-2 data from 11 coastal sites (4 over oceans) - Years Collocation Temporal variability Distributions (TOP), (MIDDLE) and (BOTTOM): Distributions of aerosol optical thickness AOT(550), AOT(870), and Ångström exponent α(550, 870) Scatter plot s TOP: MODIS-OCN vs. MODIS-ATM AOT(550); MIDDLE: MODIS-ATM vs. AERONET AOT(870); BOTTOM: MODIS-OCN vs. AERONET Ångström exponent α(550, 870) I. Introduction The optical complexity of waters and atmospheres in coastal environments leads to potential issues in the quality of satellite ocean color and aerosol products. Uncertainties of satellite retrievals in the coastal region result from inaccuracies in the atmospheric correction and in-water constituent retrieval algorithms. Quantifying these uncertainties (i.e. satellite product validation) requires a comprehensive methodology, including high-quality in-situ measurements, retrieval algorithm assessment, and match up analysis. Thus, since early 2004, an automatic radiance measurement system, AEROENT-Ocean Color (AEROENT-OC, SeaPRISM) has been deployed at the Air-Sea Interaction Tower (ASIT) near the Martha's Vineyard Coastal Observatory (See Figure at left) This study presents the following parts: 1) an inter-validation of MODIS-Aqua ocean color products by reprocessing (R2013.0;R and R2010), and SeaWiFS R2010 in terms of AERONET-OC measurements as a reference (III); 2) a cross validation of MODIS-Aqua aerosol products by Ocean Color and Atmosphere research team algorithms based on the northeast coastal AERONET measurements (IV); and 3) a validation of MVCO QAA-retrieved absorption components from SeaPRISM radiance measurements vs. directly measured ones (V). Summary is given in VI. VI. Summary This reports a collaborative ten-year effort for satellite ocean color and aerosol product validation using AERONET-OC (i.e. SeaPRIMS ) measurements at MVCO and other sites along the US eastern coastal region. We show that The MVCO SeaPRISM site has provided valuable time series for coastal ocean color and aerosol cal/val efforts Use data makes it possible to validate key satellite ocean color and atmospheric products, Normalized water-leaving radiance nLw in 412nm is underestimated, and the improvement is apparently observable with progressive reprocessing (MODIS-Aqua) SWIR based atmosphere correction does not help to improve nLw retrieval performance at the MVCO site From the cross-validation of MODIS-OCN and MODIS-ATM aerosol retrievals generally shows aerosol optical thickness (AOT) from both MODIS products are highly correlated. Specifically compared to AERONET, both MODIS -ATM and -OCN AOT at either 550 or 870nm is under- and over- estimated at lower and higher AOT domains, respectively, the accuracy in Ångström exponent α(550, 870) retrievals remain quite low, but modes of both MODIS α(550, 870) closely match AEROENT measurements (this is a significant improvement). MODIS-OCN α(550, 870) exhibits a dynamic range more similar to that from AEROENT. SeaPRISM-radiance based QAA absorption component retrievals: a T, a dg, and a ph has been validated with in situ measurements, showing reasonably good performance, and capturing seasonal variability well. Acknowledgements This work has been supported by NASA Ocean Biology and Biogeochemistry program. MODIS-Aqua reprocessing R2012 vs. R2013 Scatter plots: satellite MODIS-retrieved nLw in R2012 (Blue dot) and R2013 (Red circle) vs. SeaPRISM nLw at 412, 443, 547, and 667nm ( from the left to the right). The statistics of correlation coefficient r 2, mean percentage error and absolute percentage errors, and number of match ups observations, are all given for each panel. Scatter plots of SeaWiFS-retrieved vs. AERONET-OC (SeaPRISM) measured nLw at 412, 443, 490,510, 555 and 670 nm from top left to bottom right. N =92 is the number of match-ups, and uncertainty measures of δ(%), |δ|(%) and r 2 are indicated. Products are from AERONET-OC Level-2 data and SeaWiFS R2010. Scatter plots of MODIS-retrieved vs. AERONET-OC (SeaPRISM) measured nLw at 412, 443, 488, 531, 547, and 667 nm from top left to bottom right. N =185 is the number of match-ups, and uncertainty measures of δ(%), |δ|(%) and r 2 are indicated. Products are from AERONET-OC Level-2 data and MODIS- Aqua R2012 in the period V.AERONET-OC based QAA vs. insitu absorptions Upper panels: Scatter plot showing the SeaPRISM QAA vs. in situ absorption components (left) a T (total absorption ), (mid) a dg and (right) a ph (wavelenthes are indicated by colors). Lower panels: in situ (blue) and the SeaPRISM QAA (red) absorptions : (left) a T, (mid) a dg and (right) a ph Time series: (top): a ph (443); (middle) a ph (547); (bottom) a dg (443); a ph. Red points are SeaPRISM QAA retrievals; Blue refers to in situ measurements; Black lines are 30 day binned SeaPRISM QAA retrievals.