Results of the Ongoing Monitoring of the Position of a Geostationary Telecommunication Satellite by the Method of Spatially Separated Basis Receiving of Digital Satellite Television Signals

The results of the ongoing monitoring of the position of geostationary telecommunication satellite Eutelsat-13B (13° East) are presented in the article. The results were obtained using a radio engineering complex (RC) of four stations receiving digital satellite television and a data processing cent...

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Bibliographic Details
Published in:Latvian journal of physics and technical sciences 2016-10, Vol.53 (5), p.5-16
Main Authors: Bushuev, F., Kaliuzhnyi, M., Sybiryakova, Y., Shulga, O., Moskalenko, S., Balagura, O., Kulishenko, V.
Format: Article
Language:English
Subjects:
Cartesian coordinates of geostationary satellites
DVB-S
radio interferometer
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Summary:The results of the ongoing monitoring of the position of geostationary telecommunication satellite Eutelsat-13B (13° East) are presented in the article. The results were obtained using a radio engineering complex (RC) of four stations receiving digital satellite television and a data processing centre. The stations are located in Kyiv, Mukachevo, Kharkiv and Mykolaiv. The equipment of each station allows synchronous recording (by the GPS) of fragments of DVB-S signal from the quadrature detector output of the satellite television receiver. Samples of the complex signal are archived and sent to the data processing center through the Internet. Here three linearly independent slant range differences (Δr) for three pairs of the stations are determined as a result of correlation processing of received signals. Every second measured values of Δr are used to calculate Cartesian coordinates (XYZ) of the satellite in the coordinate system WGS84 by multilateration method. The time series of Δr, , and obtained during continuous observations from March to May 2015 are presented in the article. Single-measurement errors of Δr, , and are equal to 2.6 m, 3540 m, 705 m and 455 m, respectively. The complex is compared with known analogues. Ways of reduction of measurement errors of satellite coordinates are considered. The radio engineering complex could be considered a prototype of a system of independent ongoing monitoring of the position of geostationary telecommunication satellites.
ISSN:0868-8257
2199-6156
0868-8257
DOI:10.1515/lpts-2016-0031