Substantiation of Reliability Requirements for Mobility Means of Surface‐to‐Air Missile Systems

P.V. Open’ko; P.A. Drannyk; V.V. Kobzev; M.B. Brovko; G.S. Zalevsky

doi:10.3849/aimt.01122

Authors

P.V. Open’ko Department of Antiaircraft Missile Troops of Institute of Aviation and Air Defense, Ivan Cherniakhovskyi National Defense University of Ukraine, Kyiv, Ukraine
P.A. Drannyk Department of Antiaircraft Missile Troops of Institute of Aviation and Air Defense, Ivan Cherniakhovskyi National Defense University of Ukraine, Kyiv, Ukraine
V.V. Kobzev Air Force Scientific Center, Ivan Kozhedub Kharkiv National Air Force University, Kharkiv, Ukraine
M.B. Brovko Air Force Scientific Center, Ivan Kozhedub Kharkiv National Air Force University, Kharkiv, Ukraine
G.S. Zalevsky Air Force Scientific Center, Ivan Kozhedub Kharkiv National Air Force University, Kharkiv, Ukraine

DOI:

https://doi.org/10.3849/aimt.01122

Keywords:

effectiveness of the hierarchic system, mobility means,, reliability requirements, surfaceto- air missile system

Abstract

Common principles of substantiation of reliability requirements for vehicles (mobility means) of surface‐to‐air missile (SAM) systems are discussed. The principles mentioned include the impact of a hierarchically‐branched structure of SAM system and reliability of their vehicles on system effectiveness under the real conditions. As the complex measure of SAM system effectiveness the coefficient of effectiveness sustainment of SAM system combat (technical) mobility means is used, which is the ratio of system output effect characteristic taking into account reliability measures of mobility means to its value in case, when mobility means do not have failures. The coefficient used here is considered to be the function of mean distance between failures (MDBF) of mobility means and their number.

Author Biography

P.V. Open’ko, Department of Antiaircraft Missile Troops of Institute of Aviation and Air Defense, Ivan Cherniakhovskyi National Defense University of Ukraine, Kyiv, Ukraine

канд. техн. наук

References

LANETSKIY, B.N., LUK’YANCHUK, V.V., KIRILLOV, I.G. and NIKOLAEV, I.M.Order of Grounding the Operational and Tactical Requirements to the System of Surface‐to‐Air Missile Armaments and its Structural Components (in Russian). Systemi ozbroyenya i viyskovoi tehniki, 2014, no. 1(37), p. 51-55.

LANETSKIY, B.N., LUK’YANCHUK, V.V., LISOVENKO, V.V. and NIKOLAEV, I.M. Methodical Approach to Grounding the Requirements to Survival of Surface‐to‐Air Missile Complex in Conditions of the Fire Interdiction by Enemy (in Russian). Nauka i tehnika Pov-itryanyh Sil Zbroinih Sil Ukrainy, 2014, no. 2(15), p. 93-97.

ADMP‐01:2014, Guidance for Developing Dependability Requirements – Edition A Version 1.

ADMP‐02:2014, Guidance for Dependability In‐Servise – Edition A Version 1.

GADASIN, V.A. Estimation of the Effectiveness of Hierarchic Systems with Equal Objects with Due Regard for Reliability (in Russian). Izv. Akad. Nauk SSSR, Tekh. Kibern., 1976, no. 6, p. 108-113.

MARTIN, P.L. Electronic Failure Analysis Handbook. New York: McGraw‐Hill, 1999, 520 p.

POLOVKO, A.M. and GUROV, S.V. Fundamentals of Reliability Theory (in Russian). St. Petersburg: BHV‐Peterburg, 2006, 704 p.

KOVTUNENKO, A.P., ZUBAREV, V.V., LANETSKIY, B.N. and ZVEREV, A.A. Mathematical Modeling in Problems of Research of Reliability of a Technical Systems (In Russian). Kyiv: NAU, 2006, 236 p.

LANETSKIY, B.N., ZHUKOV, V.S. and ALEKSEEV, A.S. Fundamentals of Reliability Theory, Exploitation and Repair of Means of Antiaircraft Systems. Part 1 (In Ukrainian). Kharkiv: HVU, 2008, 510 p.

TOBIAS, P.A. and TRINDADE, D.C. Applied Reliability. Third Edition. Boca Raton: CRC Press, 2012, 600 p.

OHRING, M. and KASPRZAK, L. Reliability and Failure of Electronic Devices and Materials. Second Edition. Amsterdam: Elsevier, 2014, 758 p.

Military Directives, Handbooks and Standards Related to Reliability [on line]. Available from: <http://www.weibull.com/knowledge/milhdbk.htm>.

PARKER, S.R. Combat Vehicle Reliability Assessment Simulation Model (CVRASM). In Proceedings of the 23rd Conference on Winter Simulation. Wash-ington: IEEE Computer Society, 1991, p. 491-498.

NAIL, M., FENTON, N., FOREY, S. and HARRIS, R. Using Bayesian Belief Networks to Predict the Reliability of Military Vehicles. Computing & Control En-gineering Journal, 2001, no. 2, p. 11-20.

STRUTT, J.E. and HALL, P.L. Global Vehicle Reliability Prediction and Optimi-zation Techniques. Bury St. Edmunds and London: Professional Engineering Pub-lishing, 2003, 140 p.

LEONTYEV, A.N., SOLOVYOV, A.A., RASSCHUPKIN, V.P. and KORYTOV, M.S. Fundamentals of Reliability and Repair of Vehicles of Special Purpose (in Rus-sian). Omsk: SibADI, 2010, 135 p.