The launch occurred at 0302UTC from the LC9 Launch Complex of the Taiyuan Satellite Launch Center, Shanxi Province. Operated by the CMA (China Meteorological Administration) and NSMC (National Satellite Meteorological Center), the FY-3 series represents the second generation of Chinese polar-orbiting meteorological satellites and are cooperative program between CMA and CNSA (China National Space Administration). The FY-3 series provides global air temperature, humidity profiles, and meteorological parameters such as cloud and surface radiation required in producing weather forecasts, especially in making medium numerical forecasting.
The satellites monitor large-scale meteorological disasters, weather-induced secondary natural hazards and environment changes, providing geophysical parameters for scientific research in climate change and its variability, climate diagnosis and predictions. The FY-3 series renders global and regional meteorological information for aviation, ocean navigation, agriculture, forestry, marine activities, hydrology and many other economic sectors.
The program was initially approved in 1998, while the engineering development of the first satellite began the following year. The collection of atmospheric data for intermediate—and long-term—weather forecasting and global climate research are the main aspects of the series. The FY-3 series satellites are designed and developed by the Shanghai Aerospace Administration. The vehicle structure is a hexahedron of 4.4m x 2.0m x 2.0m in the stowed configuration, and 4.4m x 10m x 3.8m in the deployed state. The total spacecraft launch mass is estimated to be 2,450kg.
The satellite structure is based on a separated bay design, combined structure of center supporting cylinder and guest board for service module and propulsion module, and a combined structure of baffle plate and truss. Thermal control relies mainly on passive thermal control assisted by active thermal control.
The satellite features one solar panel mounted on one side of the satellite’s main body, making the span length of the satellite 10m in its flight configuration). The solar array is 22.464m2 with an output power of 2.48kW (EOL), average = 1100W. Two NiCd battery units (36 cells) each of 50Ah capacity provide power in ecliptic orbit phases. The attitude control of the satellite employs three-axis stabilization (bias momentum control) with a pointing precision of 50 m on the ground. The ADCS (Attitude Determination and Control Subsystem) employs a star sensor for attitude sensing.
The FY-3 bus contains three major modules: a service module, a payload module, and a propulsion module. The spacecraft design life is three years.
The ground swath of the onboard optical-mechanical scanners is 3,000 km with a 250 m resolution in the High Resolution Picture Transmission (HRPT) mode. The satellite has two X-band transmitters (one real-time and one delayed) and an L-band transmitter (real-time). The onboard data management computer, altitude and orbital control computer—and all the remote-sensing sensors—were connected via a MIL-STD-1553B data bus system, which allows autonomous management of data collection and calculating of orbital parameters by the onboard computers.
The instruments on board the satellites can be divided on three missions: sounding, ozone and imaging. The instruments used for sounding are the IRAS (Infrared Atmospheric Sounder), the MWTS (Microwave Temperature Sounder) and the MWHS (Microwave Humidity Sounder).
The IRAS is used to obtain atmospheric temperature profiles, atmospheric humidity profiles, to determine total ozone content, cirrus, aerosol, etc. The MWTS is used for atmospheric temperature profile, rainfall, cloud liquid water, surface parameters, etc. Finally, the MWHS is used for Atmospheric humidity profile, water vapor, rainfall, cloud liquid water, etc.
The instruments used for the ozone mission are the TOU (Total Ozone Unit) the SBUS (Solar Backscatter Ultraviolet Sounder). The TOU is used to determine the total ozone distribution, while SBUS is used for determine the ozone profile and the total ozone amount.
Finally, the instruments that are used for imaging are the VIRR (Visible and Infrared Radiometer), the MERSI (Medium Resolution Spectral Imager) and the MWRI Microwave Radiation Imager).
NSMC and CMA are responsible for receiving, processing the data of Chinese and foreign meteorological satellites, and distributing the data and information products to users for application. Other responsibilities include establishing the ground segment of the Chinese meteorological satellite observation system, conducting applied research in satellite meteorology, making plans and programs for developing Chinese meteorological satellite system based on the national requirements.
The FY-3 ground segment is comprised with five receiving stations. One of the stations is located on Kiruna, Sweden. The FY-3 data products will be transmitted via DVB-S (Digital Video Broadcast-Satellite).
Situated in the Kelan County in the northwest part of the Shanxi Province, the Taiyuan Satellite Launch Center (TSLC) is also known by the Wuzhai designation. It is used mainly for polar launches (meteorological, Earth resources and scientific satellites). The launch center has two single-pad launch complexes, a technical area for rocket and spacecraft preparations, a communications centre, a mission command and control centre, and a space tracking centre.
The launch vehicles were assembled on the launch pad by using a crane at the top of the umbilical tower to hoist each stage of the vehicle in place. Satellites were airlifted to the Taiyuan Wusu Airport about 300km away, and then transported to the centre by road.
The TT&C Centre, also known as Lüliang Command Post, is headquartered in the city of Taiyuan, It has four subordinate radar tracking stations in Yangqu (Shanxi), Lishi (Shanxi), Yulin (Shaanxi), and Hancheng (Shaanxi).