Light & Engineering 27 (2)

Volume 27
Date of publication 04/22/2019

The Statistical Evaluations Of Transmission Characteristics, Limits Of Ranges And Speeds Of Transmission Of Information Via The Pulsed Atmospheric Bistatic Optical Channels. L&E 27 (2) 2019

Articles authors:

Mikhail V. Tarasenkov, Egor S. Poznakharev, Vladimir V. Belov

Mikhail V. Tarasenkov, Ph.D. in Phys. and Math. Science. He graduated from the Tomsk State University (TSU) in 2007. Senior researcher at the Zuev Institute of atmospheric optics. Research interests: analysis of regularities of image formation through the atmosphere, atmospheric correction of images in the visible and UV radiation ranges, theoretical research on communication channels outside the line of sight

Egor S. Poznakharev, student of the TSU. Engineer of the Zuev Institute of atmospheric optics. Research interests: theoretical and experimental research on communication channels outside the line of sight

Vladimir V. Belov, Prof., Dr. of Phys.math. Sciences, graduated from Tomsk State University in 1971. At present, he is the Head of laboratory of V.E. Zuev Institute of Atmospheric Optics of Russian Academy of Sciences (SB), Honoured Scientist of the Russian Federation, his research interests: the theory of optical radiation transfer in scattering and absorbing media, the theory of laser sensing, the theory of vision, atmospheric correction of aerospace images of the earth’s surface, the Monte Carlo method, multiple scattering

Abstract:

The simulation program by the Monte Carlo method of pulse reactions of bistatic atmospheric aerosol-gas channels of optical-electronic communication systems (OECS) is created on the basis of the modified double local estimation algorithm. It is used in a series of numerical experiments in order to evaluate statistically the transfer characteristics of these channels depending on the optical characteristics of an atmosphere plane-parallel model for wavelengths ? = 0.3, 0.5, and 0.9 µm at a meteorological visibility range SM = 10 and 50 km. The results are obtained for a set of basic distances between the light source and the light receiver up to 50 km and for the angular orientations of the optical axes of a laser radiation beam and of the receiving system in a wide range of their values. The dependences of the pulse reactions maximum values over-the-horizon channels of the OECS on the variations of these parameters are established.

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