Choosing the power of airborne transmitters in the space stations for digital satellite communication systems
Heading:
1Alexandrov, Ye.Ye., 2Rafalovich, OYa. 1National Technical University «Kharkiv Polytechnic Institute», Kharkiv, Ukraine 2National Technical University 'Kharkiv Polytechnic Institute ", Kharkiv, Ukraine |
Kosm. nauka tehnol. 1999, 5 ;(5):21–24 |
https://doi.org/10.15407/knit1999.05.021 |
Publication Language: Russian |
Abstract: The construction of effective configuration for satellite communication systems is discussed. As an example, we analyse the digital satellite communication system for the Voronezh − Kharkiv − Volgograd − Rostov-na-Donu region. Based on the proposed performance criterion, we found the optimal power of the airborne transmitter for the space stations of this communication system. Regional maps of the error probability for different configurations of satellite communication systems were constructed with the use of the developed algorithms and software.
|
Keywords: airborne transmitter, regional maps, satellite communication systems |
References:
1. Aleksandrov E. E., Mazmanishvili A. S., Rafalovich O. Ya. Raschet verojatnosti oshibki pri peredache fazomanipuliro-vannyh signalov v sistemah sputnikovoj svjazi dlja nekotoryh regionov Ukrainy. Vestnik nauki i tehniki, Is. 1, 48—52 (1997) [In Russian].
2. Kalashnikov N. I. Communication Systems, 428 p. (Radio i Sviaz', Moscow, 1988) [In Russian].
3. Kantor L. Ia., Timofeev V. V. Satellite communications and the geostationary orbit problem, 168 p. (Radio i Sviaz', Moscow, 1988) [In Russian].
4. Mazmanishvili A. S., Rafalovich O. Ya. Primer postroenija regional'nyh fazovyh kart verojatnosti oshibok dlja vybrannoj konfiguracii seti sputnikovoj svjazi. Elektron. Modelirovanie, 19 (5), 120—124 (1997) [In Russian].
5. Mazmanishvili A. S., Rafalovich O. Ya. Numerical noise-stability modeling of ukrainian regional satellite communucation networks. Kosm. nauka tehnol., 4 (1), 92–101 (1998) [In Russian].
https://doi.org/10.15407/knit1998.01.092
https://doi.org/10.15407/knit1998.01.092
6. Okunev Yu. B. Cifrovaja peredacha informacii fazomodulirovannymi signalami, 286 p. (Radio i Sviaz', Moscow, 1991) [In Russian].
7. Rafalovich O. Ya. Analiz cifrovyh sistem sputnikovoj svjazi po kriteriju pomehoustojchivosti priema-peredachi informacii. In: Radiotehnika. Vseukr. mezhved. nauch.-tehn. sb., Is. 104, 134—137 (1997) [In Russian].
8. Spilker J. Digital communications by satellite, Transl. from Eng., 592 p. (Svjaz', Moscow, 1979) [In Russian].
9. Bartholome P. Digital satellite networks in Europe. Proc. IEEE, 72 (11), 1469—1482 (1984).
10. Jansky D. M., Jeruchim M. C. Communications satellite in the geostationary orbit, 519 p. (Artech. House Inc., N.Y., 1983).
11. Jeruchim M. C. A survey of interference problems and applications to geostationary satellite networks. Proc. IEEE, 65 (3), 317—331 (1977).
12. Mileant A., Hinedi S. Overview of arraying techniques for deep space communications. IEEE Trans. Commun., Pt. 3, 42 (2-4), 1856—1865 (1994).
13. Pelton J. N. Satellite telenets: a techno-economic assessment of major trends for the future. Proc. IEEE, 72 (11), 1445—1456 (1984).
14. Wu W. W., Miller E. F., Pritchard W. L. Mobile satellite communications. Proc. IEEE, 82 (9), 1431 — 1448 (1994).