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CLARREO

April 12, 2024

CLARREO (Climate Absolute Radiance and Refractivity Observatory) is a high-priority NASA decadal survey mission, originally selected as such by the National Research Council in 2007.[1] The CLARREO mission is intended to provide a metrology laboratory in orbit to accurately quantify and attribute Earth's climate change (see List of climate research satellites). The mission is also designed to transfer its high accuracy to other spaceborne sensors. It would serve as a reference calibration standard in orbit,[2] making climate trends apparent in their data sets by 2055, within a 30-year time frame after its planned launch in the 2020s.[3] These measurements may go on to enable testing, validation, and improvement of climate model prediction.

Due to funding cuts in announced for the 2012 budget, the CLARREO mission was significantly scaled back, while remaining spaceborne projects were eyed to fill the gap.[4] In the President's financial year 2016 budget request, a smaller CLARREO Pathfinder (CPF) mission was provided $76.9M to demonstrate essential measurement technologies of the CLARREO Tier 1 Decadal Survey mission.[5] That funding will potentially support the flight of the Reflected Solar (RS) spectrometer, which is one piece of the full Decadal Survey-recommended mission, hosted on the International Space Station (ISS) from December 2023.[6] The Trump administration unsuccessfully tried several times to defund the mission.[7][8]

Mission concept edit

Below is the mission concept presented at the Mission Concept Review in November 2010.[9] CLARREO was then envisioned to consist of four observatories on two dual-manifested launches on Minotaur IV+ vehicles.

  • Three Instruments (two of each)
  • Four Observatories, two dual-manifested launches on Minotaur IV+ vehicles
    • July 2018: Two infrared observatories, each with GNSS-RO
    • May 2020: Two reflected solar observatories
  • 609 km polar orbits (90 degree inclination)

Alternative mission concepts were developed to accommodate reduced available funding. A CLARREO mission on the International Space Station, to include one each of the RS and IR spectrometers, was found to provide the best science value for the lowest feasible cost. Due to the ISS orbital inclination of 51.65 degrees, CLARREO on ISS measurements would not include the polar regions, resulting in the mission being unable to track global spectral benchmarks compared to the version of the mission presented at the Mission Concept Review.[10]

Pathfinder mission concept edit

In 2016, a Pathfinder mission to the full CLARREO mission received funding. "The allocated funds support the flight of a Reflected Solar (RS) spectrometer, hosted on the International Space Station (ISS) in the 2020 time frame. ... The CPF is a Class D mission with 1 year of operations on orbit and 1 year for analysis of acquired data." The mission is designed to demonstrate essential measurement technologies in orbit that can be used to reduce the risk of a full CLARREO mission. CLARREO Pathfinder has two primary objectives: to demonstrate high accuracy on orbit traceable to International Systems of Units (SI) and to transfer that accuracy to other spaceborne sensors.[11] Pathfinders threshold objective compared to the full baseline CLARREO mission is relaxed by a factor of two from 0.15% to 0.3% (k=1).[12]

Reference intercalibration edit

 
Fig. 1. The CLARREO RS spectrometer has the capability to match measurements from other spaceborne sensors spatially, temporally, spectrally, and angularly.[13] This approximate on-orbit data matching is enabled by CLARREO's ability to point its RS instrument in two dimensions.

Current satellite-based sensors are not designed to meet the accuracy requirements needed for climate change detection. Many sensors used for climate measurements were designed to meet operational weather needs and are not optimized for climate sampling. These sensors, along with older instruments designed for climate, lack the on-board ability to test for systematic errors on orbit. The CLARREO mission will meet these goals through careful consideration of the instrument design, calibration traceability at all stages of development and operation, with spectral, spatial and temporal sampling focused specifically on the creation of climate records.[14] Then after development of new cross-calibration methodologies[13] far more accurate than those achieved today,[15] CLARREO may serve as an in-orbit standard to provide reference intercalibration for missions like the broadband Clouds and the Earth's Radiant Energy System (CERES), operational sounders including the Cross-track Infrared Sounder (CrIS) and Infrared Atmospheric Sounding Interferometer (IASI), and imagers such as the Visible Infrared Imaging Radiometer Suite (VIIRS) and Advanced Very-High-Resolution Radiometer (AVHRR).[16]

Mission selection edit

The 2007 National Research Council (NRC) Decadal Survey report,[1] "Earth Science and Applications from Space: National Imperatives for the Next Decade and Beyond," provides the basis for the future direction of NASA's space-based Earth observation system. Missions were ranked according to scientific merit, contributions to long-term observational records, societal benefits, affordability, and technological readiness. The four missions recommended for earliest implementation by NASA were classified as “Tier 1” missions and included CLARREO. The NRC Decadal Survey concluded that the single most critical issue for current climate change observations was their lack of accuracy and low confidence in observing the small climate change signals over decade time scales. CLARREO observations of climate change on decadal scales address this issue by achieving the required levels of accuracy and traceability to SI standards for a set of observations sensitive to a wide range of key climate change observations.

Decadal Survey recommendations represent the community's input on the future direction of space-based Earth science; therefore, NASA will continue to engage the scientific community to refine mission requirements during the planning for CLARREO.

Science applications edit

CLARREO could make highly accurate decadal change observations that are traceable to International Systems of Units (SI) standards. For example, at solar wavelengths this is intended to be confirmed after launch using comparison of actual data to theoretical simulations of lunar/solar radiance generated within a high-fidelity sensor model,[17] although it is unclear how such a non-experimental approach will ensure SI traceability.[citation needed] The Earth observations then made by CLARREO have sensitivity to the most critical but least understood climate radiative forcings, responses, and feedbacks, such as:

  • Infrared spectra to infer temperature and water vapor feedbacks, cloud feedbacks, and decadal change of temperature profiles, water vapor profiles, clouds, and greenhouse gas radiative effects
  • GNSS-RO to infer decadal change of temperature profiles
  • Solar reflected spectra to infer cloud feedbacks, snow/ice albedo feedbacks, and decadal change of clouds, radiative fluxes, aerosols, snow cover, sea ice, and land use[18]

Societal benefits edit

 
Fig. 3. Reproduced estimates of time needed after climate mission launch to detect predicted CRF climate trends with 95% confidence, at different calibration accuracies.

After inter-calibrating with CLARREO ISS/Pathfinder and its newly relaxed accuracy objective of 0.6% (k=2)[12] from 2020 onwards, the resulting measurements may be able to detect climate change signals by the year 2039 (move Red curve to year 20 or '2020', rather than 0 start point in Fig. 3). However, since this will occur near a decade after year 31 or '2031' in Fig. 3 which is the NASA estimate of when CERES will detect such trends without the aid of CLARRE0 (grey dashed line), Pathfinder will likely be of much reduced benefit to climate science compared to the original 0.3% (k=2) concept[19] in response to the 2007 decadal survey (with a 2013 launch date[20]).

Team edit

CLARREO was originally recommended as a joint NASA/NOAA mission[21] where NOAA would contribute the total and spectral solar irradiance measurements and the Earth energy budget climate data records by flying the Total Solar Irradiance Sensor (TSIS) and the Clouds and the Earth's Radiant Energy System (CERES) sensors. The NASA portion involved the measurement of spectrally resolved thermal IR and reflected solar radiation at high absolute accuracy. However, recent events have put such allocations in question.[22]

A team led by NASA Langley Research Center, with contributions from other NASA Centers, government organizations, academia, and NASA HQ, developed a mission concept that passed its Mission Concept Review (MCR) on November 17, 2010.[23] Although the FY2012 budget cuts placed the full CLARREO mission into an extended pre-Phase A status, a CLARREO Science Definition Team, which had already been competitively selected, has continued to advance the science and technology development of the mission.[24]

References edit

  1. ^ a b National Research Council, Earth Science and Applications from Space: National Imperatives for the Next Decade and Beyond. National Academies Press, Washington, D.C., 426pp, 2007.[page needed]
  2. ^ Fox, Nigel; Kaiser-Weiss, Andrea; Schmutz, Werner; Thome, Kurtis; Young, Dave; Wielicki, Bruce; Winkler, Rainer; Woolliams, Emma (October 28, 2011). "Accurate radiometry from space: an essential tool for climate studies". Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences. 369 (1953): 4028–4063. Bibcode:2011RSPTA.369.4028F. doi:10.1098/rsta.2011.0246. PMID 21930564. S2CID 25431087.
  3. ^ Wielicki, Bruce A.; Young, D. F.; Mlynczak, M. G.; Thome, K. J.; Leroy, S.; Corliss, J.; Anderson, J. G.; Ao, C. O.; Bantges, R.; Best, F.; Bowman, K.; Brindley, H.; Butler, J. J.; Collins, W.; Dykema, J. A.; Doelling, D. R.; Feldman, D. R.; Fox, N.; Huang, X.; Holz, R.; Huang, Y.; Jin, Z.; Jennings, D.; Johnson, D. G.; Jucks, K.; Kato, S.; Kirk-Davidoff, D. B.; Knuteson, R.; Kopp, G.; Kratz, D. P.; Liu, X.; Lukashin, C.; Mannucci, A. J.; Phojanamongkolkij, N.; Pilewskie, P.; Ramaswamy, V.; Revercomb, H.; Rice, J.; Roberts, Y.; Roithmayr, C. M.; Rose, F.; Sandford, S.; Shirley, E. L.; Smith, W. L.; Soden, B.; Speth, P. W.; Sun, W.; Taylor, P. C.; Tobin, D.; Xiong, X. (October 1, 2013). "Achieving Climate Change Absolute Accuracy in Orbit". Bulletin of the American Meteorological Society. 94 (10): 1519–1539. Bibcode:2013BAMS...94.1519W. doi:10.1175/BAMS-D-12-00149.1.
  4. ^ LaRC, Denise Lineberry (June 6, 2013). "Budget issues delay Earth science mission".
  5. ^ "FY 2016 President's Budget Request Summary" (PDF). www.nasa.gov.
  6. ^ Atkinson, Joe (September 15, 2016). "CLARREO Pathfinder Undergoes Successful Mission Concept Review". NASA. Retrieved July 19, 2017.
  7. ^ Trump, Donald J. (March 13, 2017). "America First-A Budget Blueprint to Make America Great Again" (PDF). Office of Management and Budget. Retrieved July 19, 2017 – via National Archives.
  8. ^ Voosen, Paul (September 28, 2018). "NASA climate mission Trump tried to kill moves forward". Science. doi:10.1126/science.aav5703. S2CID 186784212.
  9. ^ CLARREO Science Definition Team (January 21, 2011). (PDF). Archived from the original (PDF) on October 15, 2011. Retrieved July 18, 2012.
  10. ^ . clarreo.larc.nasa.gov. Archived from the original on October 4, 2008. Retrieved July 19, 2017.
  11. ^ . nasa.gov. NASA. c. 2016. Archived from the original on May 21, 2016. Retrieved March 16, 2017.
  12. ^ a b
  13. ^ a b Roithmayr, Carlos M.; Lukashin, Constantine; Speth, Paul W.; Kopp, Greg; Thome, Kurt; Wielicki, Bruce A.; Young, David F. (October 2014). "CLARREO Approach for Reference Intercalibration of Reflected Solar Sensors: On-Orbit Data Matching and Sampling". IEEE Transactions on Geoscience and Remote Sensing. 52 (10): 6762–6774. Bibcode:2014ITGRS..52.6762R. doi:10.1109/TGRS.2014.2302397. hdl:2060/20150019879. S2CID 5041148.
  14. ^ Young, David F. (May 4, 2016). (PDF). CLARREO Mission Website. Archived from the original (PDF) on November 18, 2016. Retrieved July 19, 2017.
  15. ^ Goldberg, M.; Ohring, G.; Butler, J.; Cao, C.; Datla, R.; Doelling, D.; Gärtner, V.; Hewison, T.; Iacovazzi, B.; Kim, D.; Kurino, T.; Lafeuille, J.; Minnis, P.; Renaut, D.; Schmetz, J.; Tobin, D.; Wang, L.; Weng, F.; Wu, X.; Yu, F.; Zhang, P.; Zhu, T. (April 1, 2011). "The Global Space-Based Inter-Calibration System". Bulletin of the American Meteorological Society. 92 (4): 467–475. Bibcode:2011BAMS...92R.467G. doi:10.1175/2010BAMS2967.1.
  16. ^ (PDF). January 21, 2011. Archived from the original (PDF) on October 15, 2011.
  17. ^ (PDF). Archived from the original (PDF) on February 25, 2015. Retrieved January 15, 2023.
  18. ^ (PDF). March 28, 2011. Archived from the original (PDF) on October 15, 2011.
  19. ^ Wielicki, Bruce A.; Doelling, David R.; Young, David F.; Loeb, Norman G.; Garber, Donald P.; MacDonnell, David G. (2008). "Climate Quality Broadband and Narrowband Solar Reflected Radiance Calibration Between Sensors in Orbit". IGARSS 2008 - 2008 IEEE International Geoscience and Remote Sensing Symposium. doi:10.1109/IGARSS.2008.4778842. ISBN 978-1-4244-2807-6. S2CID 1365813.
  20. ^ "Home" (PDF).
  21. ^ Klamper, Amy (September 7, 2009). "NASA's Langley Research Center Selected to Lead CLARREO Mission". Space News. Retrieved December 3, 2022.
  22. ^ "NASA Satellite Crash Complicates Gloomy Climate Budget Picture". March 9, 2011.
  23. ^ Finneran, Michael (November 23, 2010). "CLARREO Passes First Big Test". Langley Research Center.
  24. ^ Wielicki, Bruce A. (October 28, 2014). (PDF). CLARREO Mission Website. Archived from the original (PDF) on December 20, 2014. Retrieved July 19, 2017.

External links edit

 
Wikimedia Commons has media related to CLARREO.

April 12, 2024
clarreo, climate, absolute, radiance, refractivity, observatory, high, priority, nasa, decadal, survey, mission, originally, selected, such, national, research, council, 2007, mission, intended, provide, metrology, laboratory, orbit, accurately, quantify, attr. CLARREO Climate Absolute Radiance and Refractivity Observatory is a high priority NASA decadal survey mission originally selected as such by the National Research Council in 2007 1 The CLARREO mission is intended to provide a metrology laboratory in orbit to accurately quantify and attribute Earth s climate change see List of climate research satellites The mission is also designed to transfer its high accuracy to other spaceborne sensors It would serve as a reference calibration standard in orbit 2 making climate trends apparent in their data sets by 2055 within a 30 year time frame after its planned launch in the 2020s 3 These measurements may go on to enable testing validation and improvement of climate model prediction Due to funding cuts in announced for the 2012 budget the CLARREO mission was significantly scaled back while remaining spaceborne projects were eyed to fill the gap 4 In the President s financial year 2016 budget request a smaller CLARREO Pathfinder CPF mission was provided 76 9M to demonstrate essential measurement technologies of the CLARREO Tier 1 Decadal Survey mission 5 That funding will potentially support the flight of the Reflected Solar RS spectrometer which is one piece of the full Decadal Survey recommended mission hosted on the International Space Station ISS from December 2023 6 The Trump administration unsuccessfully tried several times to defund the mission 7 8 Contents 1 Mission concept 1 1 Pathfinder mission concept 2 Reference intercalibration 3 Mission selection 4 Science applications 5 Societal benefits 6 Team 7 References 8 External linksMission concept editBelow is the mission concept presented at the Mission Concept Review in November 2010 9 CLARREO was then envisioned to consist of four observatories on two dual manifested launches on Minotaur IV vehicles Three Instruments two of each Infrared IR Spectrometer Reflected Solar RS Spectrometer Global Navigation Satellite System Radio Occultation GNSS RO Four Observatories two dual manifested launches on Minotaur IV vehicles July 2018 Two infrared observatories each with GNSS RO May 2020 Two reflected solar observatories 609 km polar orbits 90 degree inclination Alternative mission concepts were developed to accommodate reduced available funding A CLARREO mission on the International Space Station to include one each of the RS and IR spectrometers was found to provide the best science value for the lowest feasible cost Due to the ISS orbital inclination of 51 65 degrees CLARREO on ISS measurements would not include the polar regions resulting in the mission being unable to track global spectral benchmarks compared to the version of the mission presented at the Mission Concept Review 10 Pathfinder mission concept edit In 2016 a Pathfinder mission to the full CLARREO mission received funding The allocated funds support the flight of a Reflected Solar RS spectrometer hosted on the International Space Station ISS in the 2020 time frame The CPF is a Class D mission with 1 year of operations on orbit and 1 year for analysis of acquired data The mission is designed to demonstrate essential measurement technologies in orbit that can be used to reduce the risk of a full CLARREO mission CLARREO Pathfinder has two primary objectives to demonstrate high accuracy on orbit traceable to International Systems of Units SI and to transfer that accuracy to other spaceborne sensors 11 Pathfinders threshold objective compared to the full baseline CLARREO mission is relaxed by a factor of two from 0 15 to 0 3 k 1 12 Reference intercalibration edit nbsp Fig 1 The CLARREO RS spectrometer has the capability to match measurements from other spaceborne sensors spatially temporally spectrally and angularly 13 This approximate on orbit data matching is enabled by CLARREO s ability to point its RS instrument in two dimensions Current satellite based sensors are not designed to meet the accuracy requirements needed for climate change detection Many sensors used for climate measurements were designed to meet operational weather needs and are not optimized for climate sampling These sensors along with older instruments designed for climate lack the on board ability to test for systematic errors on orbit The CLARREO mission will meet these goals through careful consideration of the instrument design calibration traceability at all stages of development and operation with spectral spatial and temporal sampling focused specifically on the creation of climate records 14 Then after development of new cross calibration methodologies 13 far more accurate than those achieved today 15 CLARREO may serve as an in orbit standard to provide reference intercalibration for missions like the broadband Clouds and the Earth s Radiant Energy System CERES operational sounders including the Cross track Infrared Sounder CrIS and Infrared Atmospheric Sounding Interferometer IASI and imagers such as the Visible Infrared Imaging Radiometer Suite VIIRS and Advanced Very High Resolution Radiometer AVHRR 16 Mission selection editThe 2007 National Research Council NRC Decadal Survey report 1 Earth Science and Applications from Space National Imperatives for the Next Decade and Beyond provides the basis for the future direction of NASA s space based Earth observation system Missions were ranked according to scientific merit contributions to long term observational records societal benefits affordability and technological readiness The four missions recommended for earliest implementation by NASA were classified as Tier 1 missions and included CLARREO The NRC Decadal Survey concluded that the single most critical issue for current climate change observations was their lack of accuracy and low confidence in observing the small climate change signals over decade time scales CLARREO observations of climate change on decadal scales address this issue by achieving the required levels of accuracy and traceability to SI standards for a set of observations sensitive to a wide range of key climate change observations Decadal Survey recommendations represent the community s input on the future direction of space based Earth science therefore NASA will continue to engage the scientific community to refine mission requirements during the planning for CLARREO Science applications editCLARREO could make highly accurate decadal change observations that are traceable to International Systems of Units SI standards For example at solar wavelengths this is intended to be confirmed after launch using comparison of actual data to theoretical simulations of lunar solar radiance generated within a high fidelity sensor model 17 although it is unclear how such a non experimental approach will ensure SI traceability citation needed The Earth observations then made by CLARREO have sensitivity to the most critical but least understood climate radiative forcings responses and feedbacks such as Infrared spectra to infer temperature and water vapor feedbacks cloud feedbacks and decadal change of temperature profiles water vapor profiles clouds and greenhouse gas radiative effects GNSS RO to infer decadal change of temperature profiles Solar reflected spectra to infer cloud feedbacks snow ice albedo feedbacks and decadal change of clouds radiative fluxes aerosols snow cover sea ice and land use 18 Societal benefits edit nbsp Fig 3 Reproduced estimates of time needed after climate mission launch to detect predicted CRF climate trends with 95 confidence at different calibration accuracies After inter calibrating with CLARREO ISS Pathfinder and its newly relaxed accuracy objective of 0 6 k 2 12 from 2020 onwards the resulting measurements may be able to detect climate change signals by the year 2039 move Red curve to year 20 or 2020 rather than 0 start point in Fig 3 However since this will occur near a decade after year 31 or 2031 in Fig 3 which is the NASA estimate of when CERES will detect such trends without the aid of CLARRE0 grey dashed line Pathfinder will likely be of much reduced benefit to climate science compared to the original 0 3 k 2 concept 19 in response to the 2007 decadal survey with a 2013 launch date 20 Team editCLARREO was originally recommended as a joint NASA NOAA mission 21 where NOAA would contribute the total and spectral solar irradiance measurements and the Earth energy budget climate data records by flying the Total Solar Irradiance Sensor TSIS and the Clouds and the Earth s Radiant Energy System CERES sensors The NASA portion involved the measurement of spectrally resolved thermal IR and reflected solar radiation at high absolute accuracy However recent events have put such allocations in question 22 A team led by NASA Langley Research Center with contributions from other NASA Centers government organizations academia and NASA HQ developed a mission concept that passed its Mission Concept Review MCR on November 17 2010 23 Although the FY2012 budget cuts placed the full CLARREO mission into an extended pre Phase A status a CLARREO Science Definition Team which had already been competitively selected has continued to advance the science and technology development of the mission 24 References edit a b National Research Council Earth Science and Applications from Space National Imperatives for the Next Decade and Beyond National Academies Press Washington D C 426pp 2007 page needed Fox Nigel Kaiser Weiss Andrea Schmutz Werner Thome Kurtis Young Dave Wielicki Bruce Winkler Rainer Woolliams Emma October 28 2011 Accurate radiometry from space an essential tool for climate studies Philosophical Transactions of the Royal Society A Mathematical Physical and Engineering Sciences 369 1953 4028 4063 Bibcode 2011RSPTA 369 4028F doi 10 1098 rsta 2011 0246 PMID 21930564 S2CID 25431087 Wielicki Bruce A Young D F Mlynczak M G Thome K J Leroy S Corliss J Anderson J G Ao C O Bantges R Best F Bowman K Brindley H Butler J J Collins W Dykema J A Doelling D R Feldman D R Fox N Huang X Holz R Huang Y Jin Z Jennings D Johnson D G Jucks K Kato S Kirk Davidoff D B Knuteson R Kopp G Kratz D P Liu X Lukashin C Mannucci A J Phojanamongkolkij N Pilewskie P Ramaswamy V Revercomb H Rice J Roberts Y Roithmayr C M Rose F Sandford S Shirley E L Smith W L Soden B Speth P W Sun W Taylor P C Tobin D Xiong X October 1 2013 Achieving Climate Change Absolute Accuracy in Orbit Bulletin of the American Meteorological Society 94 10 1519 1539 Bibcode 2013BAMS 94 1519W doi 10 1175 BAMS D 12 00149 1 LaRC Denise Lineberry June 6 2013 Budget issues delay Earth science mission FY 2016 President s Budget Request Summary PDF www nasa gov Atkinson Joe September 15 2016 CLARREO Pathfinder Undergoes Successful Mission Concept Review NASA Retrieved July 19 2017 Trump Donald J March 13 2017 America First A Budget Blueprint to Make America Great Again PDF Office of Management and Budget Retrieved July 19 2017 via National Archives Voosen Paul September 28 2018 NASA climate mission Trump tried to kill moves forward Science doi 10 1126 science aav5703 S2CID 186784212 CLARREO Science Definition Team January 21 2011 CLARREO Mission Overview 2011 PDF Archived from the original PDF on October 15 2011 Retrieved July 18 2012 CLARREO clarreo larc nasa gov Archived from the original on October 4 2008 Retrieved July 19 2017 About the CLARREO Pathfinder Mission nasa gov NASA c 2016 Archived from the original on May 21 2016 Retrieved March 16 2017 a b NASA gov a b Roithmayr Carlos M Lukashin Constantine Speth Paul W Kopp Greg Thome Kurt Wielicki Bruce A Young David F October 2014 CLARREO Approach for Reference Intercalibration of Reflected Solar Sensors On Orbit Data Matching and Sampling IEEE Transactions on Geoscience and Remote Sensing 52 10 6762 6774 Bibcode 2014ITGRS 52 6762R doi 10 1109 TGRS 2014 2302397 hdl 2060 20150019879 S2CID 5041148 Young David F May 4 2016 CLARREO Science Team Report pdf PDF CLARREO Mission Website Archived from the original PDF on November 18 2016 Retrieved July 19 2017 Goldberg M Ohring G Butler J Cao C Datla R Doelling D Gartner V Hewison T Iacovazzi B Kim D Kurino T Lafeuille J Minnis P Renaut D Schmetz J Tobin D Wang L Weng F Wu X Yu F Zhang P Zhu T April 1 2011 The Global Space Based Inter Calibration System Bulletin of the American Meteorological Society 92 4 467 475 Bibcode 2011BAMS 92R 467G doi 10 1175 2010BAMS2967 1 CLARREO Mission Overview PDF January 21 2011 Archived from the original PDF on October 15 2011 GSFC RS Technology Demonstration Instrument PDF Archived from the original PDF on February 25 2015 Retrieved January 15 2023 CLARREO Extended Pre Phase A White Paper PDF March 28 2011 Archived from the original PDF on October 15 2011 Wielicki Bruce A Doelling David R Young David F Loeb Norman G Garber Donald P MacDonnell David G 2008 Climate Quality Broadband and Narrowband Solar Reflected Radiance Calibration Between Sensors in Orbit IGARSS 2008 2008 IEEE International Geoscience and Remote Sensing Symposium doi 10 1109 IGARSS 2008 4778842 ISBN 978 1 4244 2807 6 S2CID 1365813 Home PDF Klamper Amy September 7 2009 NASA s Langley Research Center Selected to Lead CLARREO Mission Space News Retrieved December 3 2022 NASA Satellite Crash Complicates Gloomy Climate Budget Picture March 9 2011 Finneran Michael November 23 2010 CLARREO Passes First Big Test Langley Research Center Wielicki Bruce A October 28 2014 Wielicki CLARREO SDT Meeting Intro Oct 28 2014 pdf PDF CLARREO Mission Website Archived from the original PDF on December 20 2014 Retrieved July 19 2017 External links edit nbsp Wikimedia Commons has media related to CLARREO https web archive org web 20120301162617 http clarreo larc nasa gov index php NASA gov NASA gov Retrieved from https en wikipedia org w index php title CLARREO amp oldid 1184042900, wikipedia, wiki, book, books, library,

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