Source: http://ao.iao.ru/en/content/vol.29-2016/iss.11
Timestamp: 2019-04-20 12:51:11+00:00

Document:
Antoshkin L.V., Botygina N.N., Bol'basova L.A., Emaleev O.N., Konyaev P.A., Kopylov E.A., Kovadlo P.G., Kolobov D.Yu., Kudryashov A.V., Lavrinov V.V., Lavrinova L.N., Lukin V.P., Chuprakov S.A., Selin A.A., Shikhovtsev A.Yu. Adaptive optics system for solar telescope operating under strong atmospheric turbulence. // Optika Atmosfery i Okeana. 2016. V. 29. No. 11. P. 895–904 [in Russian].
Antoshkin L.V., Botygina N.N., Bolbasova L.A., Emaleev O.N., Konyaev P.A., Kopylov E.A., Kovadlo P.G., Kolobov D.Yu., Kudryashov A.V., Lavrinov V.V., Lavrinova L.N., Lukin V.P., Chuprakov S.A., Selin A.A. and Shikhovtsev A.Yu. Adaptive Optics System for Solar Telescope Operating under Strong Atmospheric Turbulence. // Atmospheric and Oceanic Optics, 2017, V. 30. No. 03. pp. 291–299.
Nosov V.V., Lukin V.P., Nosov E.V., Torgaev A.V. Structure of air turbulent motion inside Primary mirror shaft at Siberian lidar station of IAO SB RAS. Experiment and simulation. // Optika Atmosfery i Okeana. 2016. V. 29. No. 11. P. 905–910 [in Russian].
Аntipov O.L., Kanev F.Yu., Lukin V.P., Makenova N.A. Dependence of the effectiveness of multichannel radiation turbulent distortion compensation on the method of phase control. Increase of the effectiveness under control of amplitude. // Optika Atmosfery i Okeana. 2016. V. 29. No. 11. P. 911–917 [in Russian].
Antipov O.L., Kanev F.Yu., Lukin V.P. and Makenova N.A. Dependence of the Effectiveness of Multichannel Radiation Turbulent Distortion Compensation on the Method of Phase Control: Increase of Efficiency with Amplitude Control. // Atmospheric and Oceanic Optics, 2017, V. 30. No. 03. pp. 284–290.
Bol'basova L.A., Lukin V.P. Analytical models of vertical profile of the structure parameter of atmospheric refractive index for adaptive optics. // Optika Atmosfery i Okeana. 2016. V. 29. No. 11. P. 918–925 [in Russian].
Antoshkin L.V., Lavrinov V.V., Lavrinova L.N. Numerical analysis of the evolution of phase fluctuations of a light field at the entrance aperture of an adaptive optics system. // Optika Atmosfery i Okeana. 2016. V. 29. No. 11. P. 926–933 [in Russian].
Bogachev V.A., Garanin S.G., Starikov F.A., Shnyagin R.A. Numerical simulation of sensorless adaptive phase correction of regular, vertical, and incoherent multimode laser beams. // Optika Atmosfery i Okeana. 2016. V. 29. No. 11. P. 934–941 [in Russian].
Bogachev V.A., Garanin S.G., Starikov F.A. and Shnyagin R.A. Numerical Simulation of Sensorless Adaptive Phase Correction of Regular, Vortical, and Incoherent Multimode Laser Beams. // Atmospheric and Oceanic Optics, 2017, V. 30. No. 02. pp. 191–197.
Venediktov V.Yu., Venediktov D.V., Gorelaya A.V., Dmitrieva A.D., Dmitriev D.I., Kudryashov A.V., Lovchy I.L., Tsvеtkоv A.D., Shalymov E.V., Sheldakova Yu.V., Shubеnkоva E.V. The study of propagation and adaptive optics correction of a laser beam along an atmospheric path protected from external influence. // Optika Atmosfery i Okeana. 2016. V. 29. No. 11. P. 942–948 [in Russian].
Yagnyatinskiу D.A., Lyakhov D.M., Borshevnikov A.N., Fedoseуev V.N. The control algorithm for adaptive optics system based on the focal spot radius minimizing. // Optika Atmosfery i Okeana. 2016. V. 29. No. 11. P. 949–953 [in Russian].
Yagnyatinskiy D.A., Lyakhov D.M., Borshevnikov A.N. and Fedoseyev V.N. A Control Algorithm for an Adaptive Optics System Based on the Focal Spot Radius Minimization. // Atmospheric and Oceanic Optics, 2017, V. 30. No. 02. pp. 198–202.
Dzеdolik I.V., Pеreskokov V.S. Topology of plazmon-polariton vortices on adaptive mirror. // Optika Atmosfery i Okeana. 2016. V. 29. No. 11. P. 954–959 [in Russian].
Dzedolik I.V. and Pereskokov V.S. Topology of Plasmon-Polariton Vortices on an Adaptive Mirror. // Atmospheric and Oceanic Optics, 2017, V. 30. No. 02. pp. 203–208.
Kabanov D.M., Zhamsueva G.S., Zayakhanov A.S., Kornienko G.I., Naguslaev S.A., Pavlov A.N., Panchenko M.V., Pestunov D.A., Sakerin S.M., Shmirko K.A. About results of two-site measurements of the aerosol optical depth of the atmosphere in certain regions of Russia. // Optika Atmosfery i Okeana. 2016. V. 29. No. 11. P. 960–971 [in Russian].
Tartakovsky V.A. Influence of solar activity on the temperature in the surface layer. // Optika Atmosfery i Okeana. 2016. V. 29. No. 11. P. 972–979 [in Russian].
Tartakovsky V.A. The Effect of Solar Activity on the Temperature in the Ground Layer. // Atmospheric and Oceanic Optics, 2017, V. 30. No. 03. pp. 269–276.
Chulichkov A.I., Andreev M.S., Golitsyn G.S., Elansky N.F., Medvedev A.P., Postylyakov O.V. On determination of height of cloud base using ground-based stereophotography. // Optika Atmosfery i Okeana. 2016. V. 29. No. 11. P. 980–986 [in Russian].
Chulichkov A.I., Andreev M.S., Golitsyn G.S., Elansky N.F., Medvedev A.P. and Postylyakov O.V. On Cloud Bottom Boundary Determination by Digital Stereo Photography from the Earth’s Surface. // Atmospheric and Oceanic Optics, 2017, V. 30. No. 02. pp. 184–190.
Vorob'ev V.V. The applicability of asymptotic formulas for recovery of "optical" turbulence parameters from data of the lidar sensing. II. Results of the numerical calculations. // Optika Atmosfery i Okeana. 2016. V. 29. No. 11. P. 987–993 [in Russian].
Vorob’ev V.V. On the Applicability of Asymptotic Formulas of Retrieving “Optical” Turbulence Parameters from Pulse Lidar Sounding Data: II–Results of Numerical Simulation. // Atmospheric and Oceanic Optics, 2017, V. 30. No. 02. pp. 162–168.
Kurakov S.A., Zuev V.V. Unmanned aerial vehicle for measuring vertical profiles of the meteorological parameters in the atmospheric boundary layer. // Optika Atmosfery i Okeana. 2016. V. 29. No. 11. P. 994–999 [in Russian].

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