THE ANALYTICAL REVIEW OF EXISTING INSTRUMENTAL STABILIZING COMPLEXES
Abstract
Instrumental stabilizing complexes are applied in modernization of existed and developing of the new light armoured vehicles (Armored Personnel Carrier, Infantry Combat Vehicle, Airborne Combat Vehicle etc.). They are intended for stabilized aiming and tracking in horizontal and vertical planes of ground, airborne and waterborne targets for effective firing from place position, in the movement and floating position. The analytical review of existing instrumental stabilizing complexes (including modes of operation, distinctive characteristics, comprehensiveness, physical and operational characteristics), developed in Ukraine, is given.
References
PJSC "RPA" Kiev Automatics Plant". (2018, April). Retrieved from: http://www.kza.com.ua/
Tsuruk, V.G., & Bezvesil'naya, O.M. (2015). Scientific, technological, organizational and implementing bases for the creation of a new complex of armored light armor stabilizers. Kiev: "Priorities".
Tsuruk, V.G., Bezvesil'naya, O.M., Kvasnikov, V.P., & Chikovani V.V. (2014). Armament guidance and stabilization. Kiev: "Priorities".
Tsuruk, V.G., Bezvesil'naya, O.M., Malyarov, S.P., Talanchuk, P.M., & Chepyuk, L.O. (2016). Scientific fundamentals of construction of precision sensitive element of the complex of light armored equipment armament stabilizer . Kiev: "Priorities".
Bondaruk, V.A., Malyarov, S.P., Tsuruk, V.G., & Yankelevich, G.E. (2011) Patent for invention No. 93974. Ukraine.
Malyarov, S.P., Tsuruk, V.G., & Nikolayenko, A.V. (2012). Patent for invention No. 97783. Ukraine.
Malyarov, S.P., Tsuruk, V.G., & Nikolayenko, A.V. (2013). Patent for invention No. 101747. Ukraine. [8] Bezvesil'naya, E.N. (1990). Investigation of the errors of a mechanical information-measuring system. Soviet Applied Mechanics, vol 4, 70-74.Technological Complexes №1 (15), 2018
Bezvesil'naya, E.N. (1990). Errors of a gyroscopic linear-acceleration sensor. Soviet Applied Mechanics, vol 3, 62-65.
Bezvesil'naya, E.N. (1989). Increase of the accuracy of a gyroscopic meter of navigation parameters. Soviet Applied Mechanics, vol 25, № 6, 100-107.
Bezvesilna, O., Korobiichuk, I., Tkachuk, A., Nowicki, M., & Szewczyk, R. (2016). Piezoelectric gravimeter of the aviation gravimetric system Piezoelectric gravimeter of the aviation gravimetric system. Advances in Intelligent Systems and Computing.753-761.
Bezvesilna, O., Korobiichuk, I., Tkachuk, A., Nowicki M., & Szewczyk, R.(2016). Design of Piezoelectric Gravimeter for Automated Aviation Gravimetric System. International Journal of Automation, Mobile Robotics & Entelligent Systems, Vol.10, 43-47.
Bezvesilna, O., Tkachuk, A., Nechai, S., Chepyuk, L., & Khylchenko, T. (2017). Introducing the principle of constructing an aviation gravimetric system with any type of gravimeter. Eastern-European journal of enterprise technologies, vol. 1/7 (85), 45-56.
Bezvesilna, O.M., & Chepyuk, L.O.(2015). String gravimeter of automated aviation gravimetric system. Zhytomyr: Zhytomyr State Technological University.
Bezvesilna, O., Korobiichuk, I., Tkachuk, A., Praczukowska, A., & Khylchenko T.(2016, May). Two-channel MEMS gravimeter for the automated aircraft gravimetric system. Systems, Control and Information Technology (pp. 481-488) Warsaw.
Bezvesilna, O., Tkachuk, A., Nechai, S., & Khylchenko, T. (2016). Simulation of influence of perturbation parameters on the new dual-channel capacitive MEMS gravimeter performance. Eastern-European journal of enterprise technologies 6/7 (84), 50-57.
Kharkiv Regional State Administration. (2016, January). Retrieved from: https://kharkivoda.gov.ua
Ministry of Defence of Ukraine.(2016, January). Retrieved from: https:// www.mil.gov.ua.
Project "Broneesite".(2016, January). Retrieved from: http://armor.kiev.ua/
UkrOboronProm.(2016, May). Retrieved from: http://ukroboronprom.com.ua/uk/
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