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Satellite Applications at the Climate Prediction Center

Explore how the Climate Prediction Center uses satellite data for real-time monitoring, climate modeling, and climate products such as hazards outlooks and health forecasts.

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Satellite Applications at the Climate Prediction Center

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  1. Satellite Applications at The Climate Prediction Center Wayne Higgins Acting Director, National Centers for Environmental Prediction April 11, 2013 Acknowledgments: P. Xie, J. Gottschalck, K.Mo, C. Long, M. Rosencrans, W. Thiaw, Y. Xue, S.-K. Yang

  2. Outline • The Demand for Climate Services • CPC Role • History of CPC use of satellite data • CPC Applications • Real-time monitoring • Climate modeling (diagnostics and verification) • Climate products (hazards outlooks; FEWS, health)

  3. The Rising Demand for Climate Services Commerce Coasts Recreation Ecosystems Hydropower Farming Health Private Sector There is an urgent and growing need for reliable, trusted, transparent and timely climate information across all sectors of our economy.

  4. CPC Mission • Operational Requirements: • Deliver national outlook products: temperature, precipitation, drought, hurricanes,.. • Span weeks, months, seasons, years • Embrace collaborative forecasting with other NCEP Service Centers, NOAA line offices, other agencies and labs • Ensure real-time, on-time, all the time (since ‘79) • Real-time monitoring (satellite applications) Temperature Outlook

  5. CPC is a Pioneer in Climate Applications of Satellite Data • Two basic types of satellite data applications • Direct use of satellite data • Integrated (e.g. combine data from individual platforms / sensors into climate analyses) • Key contributions • 1983: GOES Precipitation Index • 1985: Outgoing Longwave Radiation • 1988: Sea Surface Temperature Analysis • 1994: Ultraviolet Index • 1996: Gauge-Satellite Merged Precipitation Analysis • 1999: Full-Res Global GEO IR Images • 2002: Hi-Res Global Satellite Precipitation Estimates

  6. Monitoring the Atmosphere Outgoing LongwaveRadiation • Retrieved from Advanced Very High Resolution Radiometer • (AVHRR) observations from NOAA polar orbiters • Used as a proxy for atmospheric convection • Monitoring Applications • Climate Variability (e.g. El Niño / La Niña) • Monsoons • Droughts and Floods Precipitation • CPC MORPhing (CMORPH) Technique integrates precipitation information from passive microwave sensors aboard low earth orbiting satellites and infrared observations from geostationary satellites. • 30 min temporal resolution • 1/8 deg horizontal resolution • Testing pole to pole product (shown here) • Applications • Model Verification • Diagnostic studies

  7. Monitoring the Oceans • Sea Surface Temperature • Optimal Interpolation (OI) version 2 from NCDC • - Blended analysis using in situ and satellite obs. • - Time period: Nov 1981 to present • - Temporal resolution: weekly • - Spatial resolution: 1 deg • - Applications: monitoring ENSO, IOD, • PDO, AMO, TAV and trend • Also used for model verification and diagnostic studies • Sea Surface Height • Gridded Absolute Dynamic Topography • - Merged analysis using multiple satellite obs. • - Time period: Oct 92 – present • - Temporal resolution: daily • - Spatial resolution: 1/4 deg • - Applications: monitoring ENSO, IOD, PDO, trend • Also used for model verification and diagnostic studies

  8. Monitoring the Land Surface EVAPORATIVE STRESS INDEX U.S. DROUGHT MONITOR May 8, 2012 3-month composite ending May 5, 2012 Standardized ET/PET anomalies Drought class < -2s-1s0+1s > +2s • Mo (NOAA) and Anderson (USDA) developed the Evaporative Stress Index for drought monitoring using GOES satellite data. The index was developed within a thermal remote sensing energy balance framework. • Advantages: • A good index for monitoring rapid drought onset • Compares well with the U. S. Drought Monitor and the North American Land Data Assimilation System • Independent of land models

  9. Stratospheric Ozone Monitoring TOTAL OZONE ANOMALIES • SBUV datasets allow CPC to monitor the global ozone depletion that occurred in the 1980s and early 1990’s and the status of ozone recovery since the mid 1990’s. • Increased UV radiation at the surface results from ozone depletion. The environment, food supply, and human health communities are concerned about the impacts of increased UV radiation. 2012 Antarctic Ozone Hole • CPC monitors the ozone layer in real-time and historically. • Ozone observations from the SBUV/2 instrument are analyzed daily to monitor short term depletion events such as the “ozone hole” over Antarctica.

  10. Stratospheric Temperature Monitoring • CPC monitors long term trends of satellite derived temperatures in the stratosphere. • There is stronger cooling in the upper stratosphere. • Satellite temperature trends are validated using rocketsondes, lidars, and microwave instruments.

  11. Climate Model Forecast Verification Mean Diurnal Cycle for Selected Regions Amplitude of the Diurnal Cycle of Precipitation STD DEV of 24 HOURLY VALUES • The spatial distribution is similar, but the amplitude is weaker in CFSR than in obs. • Over land, the reanalyses peak around local noon, earlier than the obs. • Over oceans the reanalyses capture the phase , but with less amplitude than the obs.

  12. Hazards Outlooks Satellite derived OLR and precip data contribute to CPC operational hazards outlooks by: Providing additional monitoring and prediction products to the forecaster Quantitative evaluation of outlooks U.S. Hazards Outlook

  13. FEWS Applications for Humanitarian Relief Satellite derived products: precipitation, soil moisture, and numerical model forecasts are analyzed to prepare regional hazard outlooks for food security. Information is used to assess climate impacts on agriculture and water resources Drought risk areas are shaded in yellow and brown. Enables USAID to develop strategies for humanitarian relief in affected areas.

  14. UV Index and Human Health • A UV Index Forecast is generated daily at NCEP from the GFS. Global forecast grids are generated for each hour out to 5 days at 1 hr freq. • NWS and EPA jointly inform the public of the dangers of over exposure to the Sun’s UV radiation. • NWS provides forecasts; EPA distributes the forecasts, UV radiation information, and precautionary steps to prevent over exposure. • The UV Index forecasts are derived from forecasts of total column ozone, surface albedo (snow cover), clouds and aerosols • . Absorption of UV Radiation by Ozone Layer

  15. Summary • Satellite data has been indispensable for CPC climate information products. • NESDIS and CPC should continue to enhance and sustain applications of satellite data. • Collaboration between CPC and NESDIS/STAR is strong and will help ensure improved satellite applications for climate • In situ – satellite blended analysis of sea surface salinity • Next generation global OLR and SW radiation data sets • Pole-to-pole global precipitation (rainfall and snowfall) analyses • GOES-R high-resolution (2km) real-time (<=1hr) CMORPH • CPC is working with NESDIS on products from the S-NPP (e.g. total and profile ozone products and OLR) to pave the way for future JPSS products.

  16. Future Plans • Develop monitoring products through cross-LO collaboration by integrating information from multiple sources (i.e. satellite + insitu + model) • Global convection & radiation budgets (LW, SW, cloudiness, cloud type) • Global and regional water budgets and hydrological cycle (precip, evap, water vapor, stream flow, soil moisture, SSS) • Global ocean and marine (SST, SSH, salinity, ocean color) • Develop applications in support of the climate goal societal challenge projects (water, extremes, coasts, marine ecosystems). • Improve delivery of tools to facilitate applications by users. • ….

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