ISCCP Calibration 25 th Anniversary Symposium July 23, 2008 NASA GISS Christopher L. Bishop Columbia University New York, New York.

Slides:

Advertisements

Similar presentations

NOAA National Geophysical Data Center

Advertisements

1 Evaluating climate model using observations of tropical radiation and water budgets Richard P. Allan, Mark A. Ringer Met Office, Hadley Centre for Climate.

Preliminary Study of Lunar Calibration for Geostationary Imagers Japanese Multi-functional Transport SATellite-2 (MTSAT-2) incorporates the special device.

1 Satellite Imagery Interpretation. 2 The SKY Biggest lab in the world. Available to everyone. We view from below. Satellite views from above.

TRMM Tropical Rainfall Measurement (Mission). Why TRMM? n Tropical Rainfall Measuring Mission (TRMM) is a joint US-Japan study initiated in 1997 to study.

Quantifying aerosol direct radiative effect with MISR observations Yang Chen, Qinbin Li, Ralph Kahn Jet Propulsion Laboratory California Institute of Technology,

Surface Skin Temperatures Observed from IR and Microwave Satellite Measurements Catherine Prigent, CNRS, LERMA, Observatoire de Paris, France Filipe Aires,

Institute of Meteorology and Water Management „Satellite Remote Sensing as a tool for monitoring of climate and environment Piotr Struzik Satellite Research.

Lunar Observations of Changes in the Earth’s Albedo (LOCEA) Alexander Ruzmaikin Jet Propulsion Laboratory, California Institute of Technology in collaboration.

Center for Satellite Applications and Research (STAR) Review 09 – 11 March 2010 NOAA Operational Geostationary Sea Surface Temperature Products from NOAA.

Remote Sensing Allie Marquardt Collow Met Analysis – December 3, 2012.

Metr 415/715 Monday May Today’s Agenda 1.Basics of LIDAR - Ground based LIDAR (pointing up) - Air borne LIDAR (pointing down) - Space borne LIDAR.

CALIBRATION AND RE-PROCESSING STATUS Calibration Status –VIS will be completed in September –IR will be completed in October –Microwave ready back to 98,

JMA’s GSICS and SCOPE-CM Activities (CGMS-41-JMA-WP-04) CGMS-41, Jul , 2013, Tsukuba, Japan 1 JMA / Meteorological Satellite Center.

Global NDVI Data for Climate Studies Compton Tucker NASA/Goddard Space Fight Center Greenbelt, Maryland

Global Studies of our Planet’s Vegetation New SeaWiFS Land NDVI and Channels 9/97->now…

Applications and Limitations of Satellite Data Professor Ming-Dah Chou January 3, 2005 Department of Atmospheric Sciences National Taiwan University.

1 CERES Results Norman Loeb and the CERES Science Team NASA Langley Research Center, Hampton, VA Reception NASA GSFC, Greenbelt, MD.

Satellite-derived Sea Surface Temperatures Corey Farley Remote Sensing May 8, 2002.

Overview of the “Geostationary Earth Radiation Budget (GERB)” Experience. Nicolas Clerbaux Royal Meteorological Institute of Belgium (RMIB) In collaboration.

Investigating the use of Deep Convective Clouds (DCCs) to monitor on-orbit performance of the Geostationary Lightning Mapper (GLM) using Lightning Imaging.

Estimating the radiative impacts of aerosol using GERB and SEVIRI H. Brindley Imperial College.

ISCCP at 30, April 2013 Backup Slides. ISCCP at 30, April 2013 NVAP-M Climate Monthly Average TPW Animation Less data before 1993.

July 2006GEWEX Cloud Assessment1 Assessment of cloud properties from Satellite Data: ISCCP,TOVS Path-B, UW HIRS Claudia Stubenrauch CNRS/IPSL - Laboratoire.

Investigations of Artifacts in the ISCCP Datasets William B. Rossow July 2006.

ASIC 3 May Broadband Breakout Group Recommendations Big 3 Crosscutting Earth Radiation Budget.

ISCCP SO FAR (at 30) GOALS ►Facilitate "climate" research ►Determine cloud effects on radiation exchanges ►Determine cloud role in global water cycle ▬

Prepared by Ken Knapp, NOAA/NCDC 3/19/2015.  ISCCP Background  Activities in 2014  Plans for 2015  Potential interactions with other SCOPE-CM projects.

Evaluation of radiative properties of low and high clouds in different regimes using satellite measurements Bing Lin 1, Pat Minnis 1, and Tai-Fang Fan.

Estimation of Potential Evapotranspiration from Merged CERES and MODIS Observations Anand Inamdar & A. French Arid Land Agricultural Research Center (ALARC/ARS/USDA)

Center for Satellite Applications and Research (STAR) Review 09 – 11 March 2010 Requirement: Provide information to air quality decision makers and improve.

Satellites Storm “Since the early 1960s, virtually all areas of the atmospheric sciences have been revolutionized by the development and application of.

Interannual Variability and Decadal Change of Solar Reflectance Spectra Zhonghai Jin Costy Loukachine Bruce Wielicki (NASA Langley research Center / SSAI,

Preliminary results from the new AVHRR Pathfinder Atmospheres Extended (PATMOS-x) Data Set Andrew Heidinger a, Michael Pavolonis b and Mitch Goldberg a.

Overview of Climate Observational Requirements for GOES-R Herbert Jacobowitz Short & Associates, Inc.

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

TS 15 The Great Salt Lake System ASLO 2005 Aquatic Sciences Meeting Climatology and Variability of Satellite-derived Temperature of the Great Salt Lake.

MOLLY E. BROWN, PHD NASA GODDARD GIMMS Group Challenges of AVHRR Vegetation Data for Real Time Applications.

How Convection Currents Affect Weather and Climate.

1 SBUV/2 Calibration Lessons Over 30 Years: Liang-Kang Huang, Matthew DeLand, Steve Taylor Science Systems and Applications, Inc. (SSAI) / NASA.

A Rising Expectation for ISCCP to produce Long-Term Climate Data Records on Satellite Cloud Climatology over 30 years prepared by Toshiyuki KURINO, JMA.

Visible vicarious calibration using RTM

Thomas C. Stone U.S. Geological Survey, Flagstaff, AZ USA GSICS Research Working Group Meeting EUMETSAT 24−28 March 2014 Using the Moon as a Radiometric.

VIS/NIR reference instrument requirements

Benjamin Scarino, David R

Sébastien Wagner, Tim Hewison In collaboration with D. Doelling (NASA)

Extending DCC to other bands and DCC ray-matching

Second GSICS Users’Workshop:

In the past thirty five years NOAA, with help from NASA, has established a remote sensing capability on polar and geostationary platforms that has proven.

Spectral Band Adjustment Factor (SBAF) Tool

Meteorological Satellite Center Japan Meteorological Agency

Vicarious calibration by liquid cloud target

JMA’s GSICS and SCOPE-CM activities Presented to CGMS-43 Working Group II session, agenda item 3 (from MTSAT-2) Japan Meteorological Agency.

GEO-CAPE to TEMPO GEO-CAPE mission defined in 2007 Earth Science Decadal Survey Provide high temporal & spatial resolution observations from geostationary.

Verifying the DCC methodology calibration transfer

Using SCIAMACHY to calibrate GEO imagers

On the use of Ray-Matching to transfer calibration

Introduction of the SCIAMACHY SBAF web tool

ISCCP and GSICS NOAA/NCEI Ken Knapp (& ISCCP Team)

Geostationary Sounders

Characterizing DCC as invariant calibration target

In the past thirty five years NOAA, with help from NASA, has established a remote sensing capability on polar and geostationary platforms that has proven.

Implementation of DCC at JMA and comparison with RTM

Inter-calibration of the SEVIRI solar bands against MODIS Aqua, using Deep Convective Clouds as transfer targets Sébastien Wagner, Tim Hewison In collaboration.

Inter-satellite Calibration of HIRS OLR Time Series

KMA Agency Report NMSC/KMA

GSICS Data and Products Servers

G16 vs. G17 IR Inter-comparison: Some Experiences and Lessons from validation toward GEO-GEO Inter-calibration Fangfang Yu, Xiangqian Wu, Hyelim Yoo and.

Discussion Way Forward for Multispectral IR

Representing Climate Data II

Presentation transcript:

ISCCP Calibration 25 th Anniversary Symposium July 23, 2008 NASA GISS Christopher L. Bishop Columbia University New York, New York

ISCCP Flow Diagram

ISCCP Calibration Overview Collect visible and IR data from radiometers onboard NOAA Polar Orbiter, GOES, METEOSAT, GMS, etc Normalize all geostationary satellites to the afternoon polar orbiter Monitor polar orbiter for drift over time Normalize succeeding instruments to the original standard Tie the relative standard to an absolute standard using aircraft campaigns

Current Steps in ISCCP Calibration Procedure 1.Geo-to-Leo Normalization using co-located and coincident full resolution radiances 2.Leo-to-Leo Normalization using long-term statistics of the global and target distributions of clear-sky radiances over ocean and land 3.Compare co-located and coincident Geo-to-Leo retrievals of surface and cloud properties 4.Monitoring Radiance Statistics at sub-monthly time scale 5.Monitoring long-term statistics of Cumulus-Cirrus and Stratus-Deep Convection amounts as well as all physical quantities retrieved

Co-located & Coincident Measurements

ISCCP Calibration Flow Chart ISCCP Vis Calibration Flow Chart

ISCCP AVHRR Monitor Flow Chart ISCCP AVHRR Vis Monitor Flow Chart

World “targets”

NOAA PM Equator X Time

NOAA AM EqX Time

Orbit Drift and Solar Zenith Angles

June JUNEJUNE

December DECEMBERDECEMBER

PINATUBO EFFECT

Bilinear

N7/N9 Regression NOAA-7/NOAA-9 Overlap Data Linear Regression Includes most of the brightness range | Demonstrates linearity over range No spectral shifts between instruments | More stable than a “single pixel”

Sahara 3 Calibrations

Whitlock

VIS Monitor PM Orbiters

ISCCP NOAA IR Calibration Using 10 th and 90 th percentiles of water pixels: Normalize to NOAA-9 IR No correction for drift over time Warm end / cold end

NOAA-17 IR

NOAA-18 IR

IR all sats, nom & abs data

IR all sats absolute data

IR AM&PM Warm Anomalies

IR AM&PM Cold Anomalies

IR Afternoon both fits

IR Afternoon warm end

IR Afternoon cold end

Calibration Effect on Cloud Amount

Calibration and Other Effects on Surface Properties Surface ReflectanceSurface Temperature Known TOVS ChangesNo VIS Standard for Geos Pinatubo??

NOAA DS STATS NOAA DS

Future Considerations Mean properties of Earth are more nearly constant over decadal time scale than the calibration of the radiometers Relative calibration uncertainties of radiances used in ISCCP –Vis: +/ absolute, +/- 3-5% relative –IR: +/- 2K absolute, +/ % relative Estimate the absolute calibration uncertainty to be about 10% for VIS and 2% for IR Lessons learned: –Real decadal scale changes of Earth much smaller than uncertainties in calibration and cannot be reliably detected without significant improvement of instrument calibration –Given infrequent aircraft campaigns it difficult to distinguish real inter-annual variability from short-tem calibration changes –need onboard calibration for all channels Still may not be sufficient (IR differences of 1K) Vicarious target calibration procedures still needed as backup/confirmation –Need to plan transition from one instrument to the next

IMPROVEMENTS POSSIBLE 1.Survey Radiance Statistics for Individual Images (shorter time scales) 2.Explicit Spectral Treatment 3.Bi-directional models for land surface 4.Explicit Use of Deep Convective Cloud Albedo 5.Cross-reference to Other Instruments with better Absolute Calibrations

CURRENT INVESTIGATIONS 1)Re-visiting calibration with improved techniques/algorithms 1)Better Cloud Detection (ie., DX vs static histograms 2)Better Radiative Transfer codes 3)Include water vapor, aerosol climatologies 4)Improved processing techniques (angle models, both SW channels) 5)25+ years experience 2)Comparisons to MODIS data 3)New collaborative effort – kickoff meeting May 2, )Columbia/CCNY/GISS Bishop, Rossow (See 1, 2 above; integrate findings) 2)Langley - Stackhouse, Wielicki, Kato, Doelling (Deep Convective Cloud) 3)U of Washington – Hinkleman (Deep Convective Cloud) 4)USGS Flagstaff – Stone (Lunar) “Extending the Cloud and Radiation Climate Record: Climate Calibration of the ISCCP/SRB Narrowband Imagers from 1983 to 2007” Hinkleman, PI