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  5. Methodical approach of determination of effective nomenclature of decimators of perspective shock pilotless aviation complexes

Methodical approach of determination of effective nomenclature of decimators of perspective shock pilotless aviation complexes

V. Petrov, I. Kashaev, I. Klyushnikov, A. Kudriavtsev
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Description: In the article methodical approach of determination of effective nomenclature is examined existing and perspective the guided and out of control decimators for shock pilotless aviation complexes. Essence of methodical approach consists in a types election and caliber of facilities defeats which it is planned to apply from a concrete pilotless aircraft on a model aim. A few variants of the applied decima-tors and advantage are examined gives oneself up to such for which an amount of necessary fire influences (or the required dress of pilotless aircrafts) on the achievement of the set norm of defeat of model aim is minimum. Efficiency of fire influences depends on de-scriptions of exactness of hit of decimator and descriptions of striking action of decimator in aim on an aim. Basis for determination of the required dress of pilotless aircrafts is hit of single aim (or to the elementary aim from composition group) probability. The order of calculation of hit of aim probability has distinctions at application out of control and guided aviation rockets and bombs. Hit of aim probability will depend on probability of hit of decimator and law of his defeat in aim. Probability of hitting the mark settles accounts in accordance with the integral of probability (by the function of Laplace) and depends on the sizes of aim, errors of aiming and aiming. It is known from the theory of efficiency of battle application, that at fire influence on an aim a few out of control aviation decimators between them are functionally dependent and independent connections. The degree of this cross-correlation dependence is determined by the ballistic (aerodynamic) internalss of decimators, terms of their upcast or starting (height, speed, type of trajectory of flight) and amount of them in a volley. An order over of forming of basic data is brought in the article, account of descriptions of fire influences - indexes of exactness of hit and striking action of decimators on an aim, calculation of index of efficiency. On results calculations the ranged row of variants of decimators is formed on every model aim.

Keywords: decimator, fire influence, exactness of hit, striking action, required dress of pilotless aircrafts.


1.Magas, G.A. (2015), “Tendencіyi rozvitku zbrojnoyi borot'bi u suchasnih umovah” [Trends in the development of armedstruggle in modern conditions], Collection of Sciences. Works of the National Academy of the State Border Guard Service of Ukraine, No. 1 (63), pp. 79-95.
2.US Department of Defense (2011), United States Department of Defense Fiscal Year 2011 – 2036. Unmanned SystemsIntegrated Roadmap, available at: www.fas.org/irp/program/collect/usroadmap2011.pdf.
3.Vacca, Alessia and Onishi, Hiroko (2017), Military weapons, surveillance or mapping tools for environmentalmonitoring? The need for legal framework is required, Transportation Research Procedia, pp. 51-62, available at: www.researchgate.net/publication/317421629.pdf.
4.Department of Defense (2013), Unmanned Systems Integrated Roadmap FY2013-2038, Washington, available at:www.fas.org/irp/program/collect/usroadmap2011.pdf.
5.James Franklin McDonald Jr. (2013), Critical Technologies: The United States Department of Defense Efforts to ShapeTechnology Development after the Cold War – A Discourse and Network Analysis, available at: www.vtechworks.lib.vt.edu/bitstream/handle/10919/56625/McDonald_JF_D_2014.pdf?sequence=1.
6.(2017), U.S.-China Economic and Security Review Commission. Staff Research Backgrounder June 13, 2013. China’sMilitary Unmanned Aerial Vehicle Industry, available at: www.uscc.gov/ sites/default/ iles/Research/China%27s%20Military%20UAV%20Industry_14%20June%202013.pdf.
7.(2011), “Udarnye BPLA SSHA – nastoyashchee i budushchee” [Impact UAVs USA – present and future], Army Bulle-tin, available at: www.army-news.ru/2011/03/udarnye-bpla-ssha/.
8.(2015), “Novosti BPLA industrii” [UAV industry news], available at: www.indelauav.com/news.html.
9.(1984), “Rukovodstvo po boevomu primeneniyu aviacionnyh sredstv porazheniya nazemnyh (morskih) ob"ektov. Chast'III, kniga 1” [Guide to the combat use of aviation means of destruction of ground (sea) objects. Part III, Book 1], Voenizdat, Moscow, 256 p.
10.(1989), “Shturmanskoe obespechenie” [Navigation software], VVA im. Yu.A. Gagarina, Monino, Moscow, 502 p.
11.Korochkin, O.A. (2004), “Avіacіjnі zasobi urazhennya і ustanovki avіacіjnogo ozbroеnnya” [Aircraft damage and in-stallation of aviation weapons], HUPS, Kharkіv, 186 p.
12.Milgram, Yu.G. and Popov, I.S. (1970), “Boevaya ehffektivnost' aviacionnoj tekhniki i issledovanie operacij” [Thecombat effectiveness of aircraft and operations research], VVIA, Moscow, 499 p.
13.Milgram, Yu.G. (1968), “Issledovanie operacij i algoritmizaciya boevyh dejstvij” [Operations Research and Algor-?thmization of Hostilities] VVIA, Moscow, 461 p.

 Petrov, V.M., Kashaiev, I.O., Kliushnikov, I.M. and Kudriavtsev, A.F. (2019), “Metodychnyi pidkhid do vyznachennia efektyvnoi nomenklatury zasobiv urazhennia perspektyvnykh udarnykh bezpilotnykh aviatsiinykh kompleksiv” [Methodical approach of determination of effective nomenclature of decimators of perspective shock pilotless aviation complexes], Scientific Works of Kharkiv National Air Force University, Vol. 2(60), pp. 59-66. https://doi.org/10.30748/zhups.2019.60.08.