Model of the Surface-to-Air Missile System Reliability during Long-Term Operation

Authors

  • V.V. Lukyanchuk Air Force Research Laboratory, Kharkiv National Air Force University named after Ivan Kozhed-ub, Kharkiv, Ukraine
  • B.M. Lanetskii Air Force Research Laboratory, Kharkiv National Air Force University named after Ivan Kozhed-ub, Kharkiv, Ukraine
  • I.V. Koval Air Force Research Laboratory, Kharkiv National Air Force University named after Ivan Kozhed-ub, Kharkiv, Ukraine
  • Pavlo Open’ko the National Defence University of Ukraine named after Ivan Cherniakhovskyi
  • V.V. Tуurin Institute of Aviation and Air Defense, National Defense University of Ukraine named after Ivan Cherniakhovskyi, Kyiv, Ukraine
  • V.V. Khoma Institute of Aviation and Air Defense, National Defense University of Ukraine named after Ivan Cherniakhovskyi, Kyiv, Ukraine

DOI:

https://doi.org/10.3849/aimt.01506

Keywords:

coefficient of effectiveness sustainment, long-term operation, SAMS reliability model, typical cyclogram of intended use , surface-to-air missile systems

Abstract

During the long-term operation, anti-aircraft missile weapons are characterized by the technical condition and level of reliability change influeincing the efficiency on the intended use. The article presents a model of surface-to-air missile system (SAMS) reliability during long-term operation, which contains a set of models, namely: a model of operation of ground combat assets (GCA) of SAMS according to the typical cyclogram of intended use (TCIU); a reliability dynamics model of SAMS GCA in the established system of maintenance and repair (SMR) and a reliability dynamics model of surface-to-air missiles (SAM) during extended usage. It is expedient to use the developed model at substantiation of requirements to the indicators of SAMS and SAM reliability for their development or modernization; when developing SAMS repair plans in terms of determining the time of SAMS GCA and (or) SAM repairing time and when developing methods for assessing the effectiveness of SAMS taking into account the duration of SAMS GCA and SAMS usage.

 

Author Biography

  • Pavlo Open’ko, the National Defence University of Ukraine named after Ivan Cherniakhovskyi

    Candidate of Technical Sciences, Senior researcher

References

NAPIÓRKOWSKIA, J. and J. GONERA. Analysis of Failures and Reliability Model of Farm Tractors. Agricultural Engineering, 2020, 24(2), pp. 89-101. DOI 10.1515/agriceng-2020-0020.

CUI, L., Y. LI, J. SHENA and L. CONG. Reliability Evaluation Based on a Dependent Two-Stage Failure Process with Competing Failures. Applied Mathematical Modelling, 2018, 64, pp. 699-712. DOI 10.1016/j.apm.2018.07.39.

PRAKS, P., V. KOPUSTINSKAS and M. MASERA. Monte-Carlo-Based Reliability and Vulnerability Assessment of a Natural Gas Transmission System Due to Random Network Component Failures. Sustainable and Resilient Infrastructure, 2017, 2, pp. 97-107. DOI 10.1080/23789689.2017.1294881.

YANG, J., J. CHEN, Y. HUO and Y. LIU А Novel Cluster-Based Wireless Sensor Network Reliability Model Using the Expectation Maximization Algorithm. Journal of Sensors, 2021, 2021, pp. 1-13. DOI 10.1155/2021/8869544.

TORRES, E.S., S. SRIRAMULA, D. CELEITA and G. RAMOS. Reliability Model and Sensitivity Analysis for Electrical/Electronic/Programmable Electronic Safety-Related Systems. IEEE Transactions on Industry Applications, 2020, 56(4), pp. 3422-3430. DOI 10.1109/TIA.2020.2990583.

ZUBAREV, V.V., A.P. KOVTUNENKO, A.V. VASILENKO, I.B. CHEPKOV and M.A. SHISHANOV. Foundations of the Theory of Complex Substantiation of Requirements for Technical Indicators of Complex Systems [in Russian]. Kyiv: Knizhkove vidavnitstvo NAU, 2010. ISBN 978-966-2377-11-8.

KOVTUNENKO, A.P., V.V. ZUBAREV, B.N. LANETSKIY and A.A. ZVEREV. Mathematical Modeling in Problems of Research of Reliability of a Technical Systems [in Russian]. Kyiv: Knizhkove vidavnitstvo NAU, 2006. ISBN 978-966-598-306-4.

MUSCOLINO, G., R. SANTORO and A. SOFI. Reliability Analysis of Structures with Interval Uncertainties under Stationary Stochastic Excitations. Computer Methods Applied Mechanics and Engineering, 2016, 300, pp. 47-69. DOI 10.1016/j.cma.2015.10.023.

TOBIAS, P.A. and D.C. TRINDADE. Applied Reliability. 3rd ed. Boca Raton: CRC Press, 2012. ISBN 978-1-58488-466-5.

LANETSKII, B.N., V.V. LUKYANCHUK and A.A. ARTEMENKO. Comprehensive Assessment of Indicators of Reliability and Residual Durability of Complex Technical Systems Operated According to Their Technical Condition. Fundamentals [in Russian]. Information Processing Systems, 2016, 2(139), pp. 40-43. ISSN 1681-7710.

OPEN’KO, P.V., P.A. DRANNYK, V.V. KOBZEV, M.B. BROVKO and G.S. ZALEVSKY. Substantiation of Reliability Requirements for Mobility Means of Surface-to-Air Missile Systems. Advances in Military Technology, 2017, 12(1), pp. 91-99. DOI 10.3849/aimt.01122.

OPEN’KO, P.V., V.V. TYURIN, M.Y. MIRONYUK, P.A. DRANNYK and V.V. KOBZEV. Reliability and Maintainability Requirements for Mobility Means of Surface-to-Air Missile Systems. Advances in Military Technology, 2020, 15(2), pp. 425-434. DOI 10.3849/aimt.01402.

LANETSKII, B.N., І.V. KOVAL, V.V. LUKYANCHUK and V.P. POPOV. Method for Predicting the Influence of Changes in the Technical State of the Main Samples of Anti-Aircraft Missile System on the Efficiency of Their Functioning During Long-Term Operation [in Ukrainian]. Armament and Military Equipment, 2020, 3(27), pp. 50-55. DOI 1034169/2414-0651.

ADMP-01:2014, Guidance for Developing Dependability Requirements – Edition A Version 1.-14.

ADMP-02:2014, Guidance for Dependability In-Servise – Edition A Version 1.-15.

LANETSKII, B., V. LUKYANCHUK, H. KHUDOV, M. FISUN, O. ZVIERIEV and I. TEREBUHA. Developing the Model of Reliability of a Complex Technical System of Repeated Use with a Complex Operating Mode. Eastern-European Journal of Enterprise Technologies, 2020, 4(107), pp. 55-65. DOI 10.15587/ 1729-4061.2020.214995.

DREJPER N.R. and H. SMITH. Applied Regression Analysis. 3rd ed. Hoboken: Wiley, 1998. ISBN 978-0-471-17082-2.

ADUEVSKIJ, V.S. ed. Reliability and Efficiency in Technology [in Russian]. Мoscow: Mashinostroenie, 1990.

BEICHELT, F. and P. FRANKEN. Reliability and Maintenance-Mathematical Methods [in German]. Berlin: Verlag Technik, 1983.

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14-12-2021

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How to Cite

Lukyanchuk , V., Lanetskii, . B., Koval, I., Open’ko, P., Tуurin V., & Khoma, V. (2021). Model of the Surface-to-Air Missile System Reliability during Long-Term Operation. Advances in Military Technology, 16(2), 277-288. https://doi.org/10.3849/aimt.01506

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