Vol. 27, issue 08, article # 1

Belov V.V., Tarasenkov M.V., Abramochkin V.N., Ivanov V.V., Fedosov A.V., Gridnev Yu.V., Troitskii V.O., Dimaki V.A. Atmospheric bistatic communication channels with scattering. Part 2. Field experiments of 2013. // Optika Atmosfery i Okeana. 2014. V. 27. No. 08. P. 659-664 [in Russian].
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Abstract:

Results of field experiments on the influence of atmospheric conditions and some instrumental characteristics on the quality of information transfer in a bistatic opto-electronic communication system (OECS) operating in the visible range of wavelengths are considered. The length of the atmospheric channel reaches 17 km. Radiation of a copper bromide vapor laser with a wavelength of 510.6 nm is used as a signal source.
It is demonstrated that bistatic or over-the-horizon OECSs can operate under conditions of both cloudy and cloudless atmosphere. Average values and standard deviations of communication errors are estimated under various atmospheric-optical conditions considering variations of some characteristics of individual system units.

Keywords:

bistatic opto-electronic communication systems, field experiments, optical and meteorological state of the atmosphere

References:

1. Belov V.V., Tarasenkov M.V., Abramochkin V.N., Ivanov V.V., Fedosov A.V., Troickij V.O., Shijanov D.V. Atmosfernye bistaticheskie kanaly svjazi s rassejaniem. Part 1. Metody issledovanija // Optika atmosf. i okeana. 2013. V. 26, N 4. P. 261–267.
2. Dimaki V.A., Suhanov V.B., Troickij V.O., Filonov A.G., Shestakov D.Ju. Lazer na bromide medi s komp'juternym upravleniem impul'sno-periodicheskogo, cugovogo i zhdushhego rezhimov // Pribory i tehn. jeksperim. 2008. N 6. P. 119–122.
3. Belov V.V., Matvienko G.G., Pak R.Ju., Shijanov D.V., Kirpichenko R.Ju., Kurjachij M.I., Pustynskij I.N., Shurygin Ju.A. Aktivnye TV-sistemy videnija s selekciej fonov rassejanija // Datchiki i sistemy. 2012. N 3. P. 25–30.
4. Zuev V.E., Bela n B.D., Zadde G.O. Opticheskaja pogoda. Novosibirsk: Nauka, 1990. 192 p.
5. Arshinov M.Ju., Belan B.D., Davydov D.K., Ivlev G.A., Kozlov A.V., Pestunov D.A., Pokrovskij E.V., Tolmachev G.N., Fofonov A.V. Posty dlja monitoringa parnikovyh i okisljajushhih atmosferu gazov // Optika atmosf. i okeana. 2007. V. 20, N 1. P. 53–61.
6. Phalagov Ju.A., Uzhegov V.N. Statisticheskij metod razdelenija kojefficientov obshhego oslablenija IK- radiacii na komponenty // Optika atmosf. 1988. V. 1, N 10. P. 3–11.
7. Phalagov Ju.A., Uzhegov V.N., Shhelkanov N.N. Avtomatizirovannyj mnogovolnovoj izmeritel' spektral'noj prozrachnosti prizemnoj atmosfery // Optika atmosf. i okeana. 1992. V. 5, N 6. P. 667–671.
8. Uzhegov V.N., Rostov A.P., Phalagov Ju.A. Avtomatizirovannyj trassovyj fotometr // Optika atmosf. i okeana. 2013. V. 26, N 7. P. 590–594.
9. Kneizys F.X., Shettle E.P., Anderson G.P., Abreu L.W., Chetwynd J.H., Selby J.E.A., Clough S.A., Gallery W.O. User Guide to LOWTRAN-7. ARGL-TR-86-0177. ERP 1010. Hansom AFB. MA 01731.
10. Bucholtz A. Rayleigh-scattering calculations for the terrestrial atmosphere // Appl. Opt. 1995. V. 34, iss. 15. P. 2765–2773.
11. Soboleva N.A., Melamid A.E. Fotojelektronnye pribory // M.: Vyssh. shkola, 1974. 376 p.

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