Grouping Small Spacecraft for Global Meteorological Observations Using a Microwave Radiometer–Spectrometer

The current state of microwave radiometry for remote sensing of the Earth is considered. There are currently some 30 satellite microwave radiometers operating and supplying data in the world, while Russia has only one microwave radiometer (MTVZA-GYa) with a 65° sounding angle. We propose to create a...

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Veröffentlicht in:	Izvestiya. Atmospheric and oceanic physics 2021-12, Vol.57 (9), p.1222-1230
Hauptverfasser:	Kuzmin, A. V., Ermakov, D. M., Sadovskii, I. N., Sterlyadkin, V. V., Sharkov, E. A.
Format:	Artikel
Sprache:	eng
Schlagworte:	Atmospheric processes Climatology Earth and Environmental Science Earth orbits Earth Sciences Geophysics/Geodesy International Space Station Meteorological observations Meteorology & Atmospheric Sciences Microwave imagery Microwave radiometers Microwave radiometry Multinational space ventures Oceanography Physical Sciences Programs of Investigations of the Earth from Space Radiometers Radiometry Remote sensing Resolution Satellite data Satellites Science & Technology Space stations Space Vehicles Spacecraft Spatial discrimination Spatial resolution Systems Temporal resolution Weather forecasting
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container_end_page	1230
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container_title	Izvestiya. Atmospheric and oceanic physics
container_volume	57
creator	Kuzmin, A. V. Ermakov, D. M. Sadovskii, I. N. Sterlyadkin, V. V. Sharkov, E. A.
description	The current state of microwave radiometry for remote sensing of the Earth is considered. There are currently some 30 satellite microwave radiometers operating and supplying data in the world, while Russia has only one microwave radiometer (MTVZA-GYa) with a 65° sounding angle. We propose to create a constellation of small spacecraft for global meteorological observations on the basis of the MIRS microwave radiometer, which is being developed for the Konvergentsiya space experiment on the Russian Segment of the International Space Station. Optimal parameters for satellite data of the microwave space system are a spatial resolution of 10–12 km and a temporal resolution of 3–6 h for analyzing current atmospheric processes, improving the quality of weather forecast, and predicting emergency situations. This problem can be solved if there are 4 to 8 simultaneous satellites with onboard radiometers in a single orbit of the Earth.
doi_str_mv	10.1134/S000143382109053X
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Optimal parameters for satellite data of the microwave space system are a spatial resolution of 10–12 km and a temporal resolution of 3–6 h for analyzing current atmospheric processes, improving the quality of weather forecast, and predicting emergency situations. 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subjects	Atmospheric processes Climatology Earth and Environmental Science Earth orbits Earth Sciences Geophysics/Geodesy International Space Station Meteorological observations Meteorology & Atmospheric Sciences Microwave imagery Microwave radiometers Microwave radiometry Multinational space ventures Oceanography Physical Sciences Programs of Investigations of the Earth from Space Radiometers Radiometry Remote sensing Resolution Satellite data Satellites Science & Technology Space stations Space Vehicles Spacecraft Spatial discrimination Spatial resolution Systems Temporal resolution Weather forecasting
title	Grouping Small Spacecraft for Global Meteorological Observations Using a Microwave Radiometer–Spectrometer
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