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Space project "IONOSAT – MICRO": readiness for implementation. Space Science and Technology. 2022 ;28(6):03-11.
. Atmospheric gravity waves among other physical mechanisms of seismic-ionospheric coupling. Space Science and Technology. 2020 ;26(3):55-80.
Information system for data collection, processing, and distribution in Geospace projects. Space Science and Technology. 2020 ;26(1):37-47.
. Selection of wave disturbances on background of trends in satellite thermosphere observation’s data. Space Sci. & Technol. 2018 ;24(6):57-68.
. Commentary on the paper “Spatio-temporal dynamics of traveling ionospheric disturbances” by Tyrnov O.F., Fedorenko Yu.P., Dorohov V.L. Space Science and technology. 2017 ;23(2):48-51.
. Space mission “CLUSTERION”: investigation of the dynamical processes in the ionesphere using a cluster of “YUZHSAT” satellites. Kosm. nauka tehnol. 2017 ;23(6):25-33.
. Height of the penetration into the ionosphere for internal atmosphere gravity waves. Kosm. nauka tehnol. 2014 ;20(4):31-41.
An approximate dispersion equation for atmosphere gravity waves. Kosm. nauka tehnol. 2011 ;17(1):43-46.
Planetary distribution of middle-scale atmosphere gravity waves according to satellite measurements. Kosm. nauka tehnol. 2010 ;16(1):40-45.
. Coupling of the weather system in the atmosphere and in space. Kosm. nauka tehnol. 2008 ;14(5):006-036.
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