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The Geostationary Lightning Mapper (GLM) for GOES-R: Overview and Status

The Geostationary Lightning Mapper (GLM) for GOES-R: Overview and Status. Steven Goodman NOAA/NESDIS/GOES-R Program Office, Greenbelt, MD 20771  http://www.goes-r.gov. Southern Thunder 2009 Cocoa Beach, FL. 2007. 2008. 2009. 2010. 2011. 2012. 2013. 2014. 2015. 2016. 2017. 2018.

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The Geostationary Lightning Mapper (GLM) for GOES-R: Overview and Status

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  1. The Geostationary Lightning Mapper (GLM) for GOES-R: Overview and Status Steven Goodman NOAA/NESDIS/GOES-R Program Office, Greenbelt, MD 20771  http://www.goes-r.gov Southern Thunder 2009 Cocoa Beach, FL

  2. 2007 2008 2009 2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020 2021 2022 2023 2024 2025 2026 2027 2028 Calendar Year Backup GOES 10 Satellite is operational beyond design life GOES 11 GOES West On-orbit GOES storage GOES 12 GOES East Operational GOES 13 On-orbit Spare GOES O GOES P GOES R GOES S As of January 5, 2009 GOES-R Timetable

  3. GOES-R Instruments For each instrument- designed for 5 yr ground storage, 5-yr on-orbit storage, and 10-yr operational life 3

  4. GOES-R Improvements vs Current GOES

  5. GOES-R 34 Baseline Products GOES-R 34 Additional Products (Option 2) Aerosol Particle Size Aerosol Detection (incl Smoke & Dust) Suspended Matter / Optical Depth Aircraft Icing Threat Volcanic Ash: Detection & Height Cloud Ice Water Path Cloud & Moisture Imagery Cloud Imagery: Coastal Cloud Optical Depth Cloud Layers / Heights and Thickness Cloud Particle Size Distribution Cloud Liquid Water Cloud Top Phase Cloud Type Cloud Top Height Convective Initiation Cloud Top Pressure Enhanced “V” / Overshooting Top Detection Cloud Top Temperature Low Cloud and Fog Hurricane Intensity Turbulence Visibility Lightning Detection: Events, Groups & Flashes Probability of Rainfall Rainfall Rate / QPE Rainfall Potential Legacy Vertical Moisture Profile Total Water Content Legacy Vertical Temperature Profile Derived Stability Indices Absorbed Shortwave Radiation: Surface Total Precipitable Water Downward Longwave Radiation: Surface GOES-R Product Set- 68 Clear Sky Masks Upward Longwave Radiation: Surface Upward Longwave Radiation: TOA Radiances Ozone Total Downward Solar Insolation: Surface SO2 Detection Reflected Solar Insolation: TOA Flood/Standing Water Derived Motion Winds Ice Cover/Landlocked Fire / Hot Spot Characterization Snow Depth Land Surface (Skin) Temperature Surface Albedo Snow Cover Sea Surface Temperature Surface Emissivity Energetic Heavy Ions Vegetation Fraction: Green Magnetospheric Electrons and Protons: Low Energy Vegetation Index Magnetospheric Electrons and Protons: Medium & High Energy Currents Solar and Galactic Protons Currents: Offshore Geomagnetic Field Sea & Lake Ice: Age Solar Flux: EUV Sea & Lake Ice: Concentration Solar Flux: X-Ray Sea & Lake Ice: Extent Solar Imagery: X-Ray Sea & Lake Ice: Motion ABI SUVI EXIS GLM SEISS Magnetometer

  6. Co-Chairs: Steven Goodman (GPO)‏ William Koshak (NASA/MSFC-AWG)‏ Richard Blakeslee (NASA/MSFC-R3, PG) AWG Application Team: Douglas Mach (UAH-AWG) Walter Petersen (NASA/MSFC-R3) Robert Boldi (UAH-R3) Dennis Buechler (UAH-R3, PG) Larry Carey (UAH-R3) Monte Bateman (USRA-AWG) Eugene “Bill” McCaul (USRA-R3) Donald MacGorman (OAR/NSSL-R3) Henry Fuelberg (GRA FSU- R3) Eric Bruning (CICS-AWG, PG) Rachel Albrecht (CICS-R3) Product Development Team: STAR AIT: Shanna Sampson Zhohui Cheng Walter Wolf AWG Lightning Team Members AWG- Algorithm Working Group R3- GOES-R Risk Reduction (Enhanced Apps) AIT- Algorithm Integration Team PG- Proving Ground

  7. ABI scans about 5 times faster than the current GOES imager There are two anticipated scan modes for the ABI: - Full disk images every 15 minutes + 5 min CONUS images + mesoscale. or - Full disk every 5 minutes.

  8. “Franklin” Mesoscale images every 30 seconds for rapidly changing phenomena (thunderstorms, hurricanes, fires, etc). Current GOES can not offer these rapid scans while still scanning other important regions

  9. TRMM/LIS-Lightning: May 1999 Stroud, OK F3 Tornado Mapping Storm Initiation, Growth, Decay Total lightning increases as storm intensifies – can increase lead time for warning of severe and tornadic storms GOES-R GLM Perspective 1-min total lightning activity

  10. GLM Proxy Data from OKLMA

  11. GLM Proxy Data from DCLMADC Regional Storms November 16, 2006 LMA 1 km resolution LMA @ GLM 10 km resolution GLM Testbeds at Huntsville, AL; Norman, OK; Sterling, VA; KSC, FL

  12. Summary: Natural Hazards and Lightning • Tornadoes • Hailstorms • Wind • Thunderstorms • Floods • Hurricanes • Volcanoes • Forest Fires • Air Quality/NOx Many Opportunities with GOES-R Using GLM Alone or in Combination with Other Measurements (ABI, Radar, Other Satellite, Other Lightning)

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