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Optoelectronic Communication in the Atmosphere Using Diff use Laser Radiation Experiments in the Field. L&E 25 (4) 2017

Light & Engineering 25 (4)

Volume 25
Date of publication 12/20/2017
Pages 41-49

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Optoelectronic Communication in the Atmosphere Using Diff use Laser Radiation Experiments in the Field. L&E 25 (4) 2017
Articles authors:
Vladimir N. Abramochkin, Vladimir V. Belov, Yuri V. Gridnev, Andrei N. Kudryavtsev, Mikhail V. Tarasenkov, Andrei V. Fedosov

Vladimir N. Abramochkin, Ph.D. in Physical and Mathematical Sciences. In 1992, graduated from the N.E. Zhukovsky Air Force Engineering Academy‎. Senior Researcher of IAO SB RAS. Research Interests: optoelectronic communication

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

Yuri V. Gridnev, engineer. In 1981, graduated from TPI. Researcher of IAO SB RAS. Research Interests: system programming

Andrei N. Kudryavtsev, engineer. In 2003, graduated from TUSUR. Senior electronic engineer of IAO SB RAS. Research Interests: laser power measurement instruments, laser strobing devices, electronic schemes, PFGA, microcontrollers, sodars

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

Andrei V. Fedosov, technician. Graduated from the Radioassembling college. Technician of IAO SB RAS. Research Interests: electronics

Abstract:
This article presents results of field experiments with bistatic optoelectronic communication systems (OECS) in the atmosphere using diffuse laser radiation. The work was performed in 2013–2016. The experiments were carried out in order to estimate communication quality (based on the control of probabilities and errors, as well as their root mean square deviations) and allow deriving the following conclusion: it is possible to create bistatic OECSs, which operate effectively in the atmosphere with hundreds of metres in UV and hundreds of kilometres in visible intervals of wave lengths, with orientation of the receiver axis both in a hemisphere containing the direction to the source and in a hemisphere containing the direction of propagation of non-diffused laser radiation.
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