BackForwardInstrument:  IGOR (COSMIC) 

Instrument details
Acronym IGOR (COSMIC)
Full name Integrated GPS Occultation Receiver
Purpose Temperature/humidity sounding with highest vertical resolution, space weather
Short description Measuring the phase delay due to refraction during occultation between GPS and LEO
Background Consolidated technology
Scanning Technique Limb scanning from the satellite altitude to close-to-surface by time sampling – Azimuth: 90° sectors fore- and aft-
Resolution About 300 km horizontal, 0.5 km vertical
Coverage / Cycle 1 GNSS constellation tracked. Comprehensive of 6 satellites: 2500 soundings/day; average spacing 450 km; global coverage (300 km spacing) in 2 days
Mass 4.6 kg Power 16 W Data Rate 17 kbps

 

Providing Agency NSPO
Instrument Maturity Flown on an R&D satellite
Utilization Period: 2006 to 2020
Last update: 2022-07-18
Detailed characteristics
Satellites this instrument is flying on

Note: a red tag indicates satellites no longer operational, a green tag indicates operational satellites, a blue tag indicates future satellites

Instrument classification
  • Earth observation instrument
  • Active and radio-occultation sensor
  • GNSS radio-occultation
WIGOS Subcomponents
  • Subcomponent 1
  • GNSS radio occultation (basic constellation)
  • GNSS radio occultation sounder (basic constellation)
Mission objectives
Primary mission objectives
  • Atmospheric temperature
  • Height of the top of PBL
  • Height of the tropopause
  • Specific humidity
  • Temperature of the tropopause
Evaluation of Measurements

The following list indicates which measurements can typically be retrieved from this category of instrument. To see a full Gap Analysis by Variable, click on the respective variable.

Note: table can be sorted by clicking on the column headers
Note: * Primary mission objective.
VariableRelevance for measuring this variableOperational limitationsExplanation
Atmospheric temperature*1 - primaryInaccurate in low troposphere.Flown in a satellite cluster. Two directional antennas, one GNSS system tracked, about 500 soundings/day per satellite
Geoid4 - fairHighly indirect.Radio-occultation processing implies precise orbitography. Geoid derived from multi-temporal analysis
Gravity field5 - marginalHighly indirect.Radio-occultation processing implies precise orbitography. Gravity field derived from multi-temporal analysis
Height of the top of PBL*1 - primaryNo specific limitation.Flown in a satellite cluster. Two directional antennas, one GNSS system tracked, about 500 soundings/day per satellite. PBL top measured as discontinuity of the refraction index
Height of the tropopause*1 - primaryNo specific limitation.Flown in a satellite cluster. Two directional antennas, one GNSS system tracked, about 500 soundings/day per satellite. Tropopause height measured as discontinuity of the refraction index
Specific humidity*2 - very highInaccurate in high troposphere.Flown in a satellite cluster. Two directional antennas, one GNSS system tracked, about 500 soundings/day per satellite
Temperature of the tropopause*1 - primaryNo specific limitation.Flown in a satellite cluster. Two directional antennas, one GNSS system tracked, about 500 soundings/day per satellite
Atmospheric density1 - primaryNo specific limitation.Measuring atmospheric density
Electron Density1 - primaryNo specific limitation.Flown in a satellite cluster. Two directional antennas, one GNSS system tracked, about 500 soundings/day per satellite
Ionospheric Total Electron Content (TEC)2 - very highNo specific limitation.Flown in a satellite cluster. Two directional antennas, one GNSS system tracked, about 500 soundings/day per satellite
Ionospheric Scintillation4 - fairNo specific limitation.Flown in a satellite cluster. Two directional antennas, one GNSS system tracked, about 500 soundings/day per satellite