Assessing the Climate Monitoring Utility of Radio Occultation Data: From CHAMP to FORMOSAT-3/COSMIC

Radio Occultation (RO) data, using Global Positioning System (GPS) signals, deliver high quality observations of the atmosphere, which are well suited for monitoring global climate change. The special climate utility of RO data arises from their accuracy and long-term stability due to self-calibrati...

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Bibliographic Details
Published in:TAO : Terrestrial, atmospheric, and oceanic sciences atmospheric, and oceanic sciences, 2009-02, Vol.20 (1), p.155
Main Authors: Foelsche, Ulrich, Pirscher, Barbara, Borsche, Michael, Kirchengast, Gottfried, Wickert, Jens
Format: Article
Language:English
Subjects:
Calibration
CHAMP (experiment)
Climate
Climate change
Climate monitoring
Climatology
Consistency
Constellation Observing System for Meteorology, Ionosphere and Climate
Data
Environmental assessment
Global climate
Global positioning systems
GPS
Ionosphere
Lapse rate
Lower stratosphere
Meteorology
Missions
Monitoring
Positioning systems
Radio
Radio occultation
Sampling
Sampling error
Satellite navigation systems
Satellite observation
Satellites
Self calibration
Signal quality
Stability
Subtraction
Tropical climate
Tropical tropopause
Tropopause
Upper troposphere
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Summary:Radio Occultation (RO) data, using Global Positioning System (GPS) signals, deliver high quality observations of the atmosphere, which are well suited for monitoring global climate change. The special climate utility of RO data arises from their accuracy and long-term stability due to self-calibration. Launched in 2000, the German research satellite CHAMP (CHAllenging Minisatellite Payload for geoscientific research) provides the first opportunity to create RO based climatologies. Overlap with data from the Taiwan/US FORMOSAT-3/COSMIC (Formosa Satellite Mission 3/Constellation Observing System for Meteorology, Ionosphere and Climate, F3C) mission allows the testing for consistency of climatologies derived from different satellites.We show initial results for zonal mean climatologies as well as tropical tropopause parameters based on F3C RO data. Our results indicate excellent agreement between RO climatologies from different F3C satellites as well as between data from different RO missions. After subtraction of the estimated respective sampling error, seasonal temperature climatologies derived from different F3C satellites are in agreement to within < 0.1 K almost everywhere in the considered domain between 8 and 35 km altitude. Monthly mean tropical tropopause (lapse rate) temperatures and altitudes derived from four different RO missions show remarkable consistency (< 0.2 - 0.5 K, < 50 - 100 m) and indicate that data from different RO missions can indeed be combined without need for inter-calibration. F3C final constellation sampling error estimation shows a small oscillating local time related error (±0.03 K amplitude) in the extratropics.
ISSN:1017-0839
2311-7680
DOI:10.3319/TAO.2008.01.14.01(F3C)