MATHEMATICAL MODELS OF THE FAILURE FLOW OF THE AIRCRAFT ELECTRONIC SYSTEM COMPONENTS

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DOI: https://doi.org/10.20998/2522-9052.2020.2.07
Keywords:
residual resource, airplane, mathematical model, failure flow, aircraft electronic system, technical condition, circuit position

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Serhii Haievskyi
Aircraft Academy of the National Aviation University, Kropyvnytskyi
https://orcid.org/0000-0003-3434-7494
Serhii Khmelevskiy
Ivan Kozhedub Kharkiv National Air Force University, Kharkiv
https://orcid.org/0000-0001-6216-3006
Artur Boiko
Military unit А3544, Kropyvnytskyi
Tatiana Mishchenko
Military unit А2171, Odesa
https://orcid.org/0000-0001-5131-485X
Oleksander Timochko
Kreditech Holding, Hamburg
https://orcid.org/0000-0003-0424-0426

Abstract

The subject of the article is the process of functioning of the modern aircraft electronic system, its components and functional units as an object of mathematical model. The purpose is to analyze an existing mathematical apparatus, which is used to calculate the failure flow of the plane radio-electronic system and opportunities for its improvement. Tasks: to build mathematical models of the failure flow of components, functional units and the plane radio-electronic system as a whole with an unlimited number of recoveries with different depth of resource recovery. The analyzed methods are: parametric methods and probabilistic methods for assessment failureless. The results obtained: mathematical models of the failure flow of the circuit positions of the aircraft electronic system were developed. Conclusions. A generalization of the well-known mathematical models of the failure flow with an unlimited number of minimum restorations of finite duration is obtained as a result of consideration of mathematical models of the failure flow of the circuit positions of the plane radio-electronic system.

Article Details

How to Cite
Haievskyi, S., Khmelevskiy, S., Boiko, A., Mishchenko, T., & Timochko, O. (2020). MATHEMATICAL MODELS OF THE FAILURE FLOW OF THE AIRCRAFT ELECTRONIC SYSTEM COMPONENTS. Advanced Information Systems, 4(2), 34–41. https://doi.org/10.20998/2522-9052.2020.2.07
Issue
Vol. 4 No. 2 (2020): Advanced Information Systems
Section
Information systems modeling
Author Biographies

Serhii Haievskyi, Aircraft Academy of the National Aviation University, Kropyvnytskyi

graduate student of the Department of Flight Operations, Aerodynamics and Flight Dynamics

Serhii Khmelevskiy, Ivan Kozhedub Kharkiv National Air Force University, Kharkiv

Candidate of technical sciences, Associate Professor, Chair Deputy of mathematical and software ACS department

Artur Boiko, Military unit А3544, Kropyvnytskyi

deputy commander of the Military unit

Tatiana Mishchenko, Military unit А2171, Odesa

deputy head of the center

Oleksander Timochko, Kreditech Holding, Hamburg

Expert Quality Assurance Engeneer

References

(1995), Reliability of equipment. Methods for assessing reliability indicators according to experimental data: DSTU 3004-95, Effective from 1995-01-25, Derzhsprozhyvstandart Ukrainy, Kyiv, 51 p.

Bobalo, Yu.Ya., Nedostup, L.A. and Lazko, О.V. (2007), “Analysis of methods for assessing the reliability of systems of compatible components of electronic devices”, Radio electronic and computer systems, No 7(26), pp. 212-214.

Yurkov, N.K., Kochegarov, I.I. and Petryanin, D.L. (2015), “To the problem of modeling the risk of failure of electronic equipment with long-term functioning”, Caspian Journal: Management and High Technologies, No 4(32), pp. 220-231.

Chernyavsky V.M. (2012), “Application of nonparametric methods for assessing the level of reliability of aircraft with low operating intensity”, Collection of scientific works of Kharkiv National University of the Air Force, No 3 (32), pp. 59-63.

Kuchuk, G., Kovalenko, A., Komari, I.E., Svyrydov, A. and Kharchenko, V. (2019), “Improving big data centers energy efficiency: Traffic based model and method”, Studies in Systems, Decision and Control”, vol 171, Kharchenko, V., Kondratenko, Y., Kacprzyk, J. (Eds.), Springer Nature Switzerland AG, pp. 161-183, DOI: http://doi.org/10.1007/978-3-030-00253-4_8

Kuchuk, G., Nechausov, S. and Kharchenko, V. (2015), “Two-stage optimization of resource allocation for hybrid cloud data store”, International Conference on Information and Digital Technologies, Zilina, pp. 266-271, DOI: http://dx.doi.org/10.1109/DT.2015.7222982

Hudkov M.V. (2010), “Methods of forecasting the reliability of electronic equipment in the operation of aircraft by condition with control parameters”, Weapons systems and military equipment, No 4(24), pp. 32-35.

Dobrydenko, O.M., Bologin, A.S., Khilchenko, M.F. and Belinska, R.B. (2011), “Modern methods of forecasting the technical condition of aviation equipment”, Collection of scientific works of the State Research Institute of Aviation, No 7(14), pp. 163-167.

Sviridov, A., Kovalenko, A. and Kuchuk, H. (2018), “The pass-through capacity redevelopment method of net critical section based on improvement ON/OFF models of traffic”, Advanced Information Systems, Vol. 2, No. 2, pp. 139–144, DOI: https://doi.org/10.20998/2522-9052.2018.2.24

Kovalenko, А. and Kuchuk H. (2018), “Methods for synthesis of informational and technical structures of critical application object’s control system”, Advanced Information Systems, Vol. 2, No. 1, pp. 22–27, DOI: https://doi.org/10.20998/2522-9052.2018.1.04

Ruban, I., Kuchuk, H. and Kovalenko A. (2017), “Redistribution of base stations load in mobile communication networks”, Innovative technologies and scientific solutions for industries, No 1 (1), P. 75–81, doi : https://doi.org/10.30837/2522-9818.2017.1.075

Donets V., Kuchuk N., Shmatkov S. Development of software of e-learning information system synthesis modeling process. Advanced Information Systems, Vol. 2, No. 2, Р. 117–121. DOI: https://doi.org/10.20998/2522-9052.2018.2.20

Kashtanov, V.A. and Medvedev, A.I. (2010), “Reliability Theory of Complex Systems”, FIZMATLIT, Moscow, 608 p.

Bobalo, L.A., Nedostup, Yu.Ya. and Kiselychnyk, M.D. (2013), Quality, reliability of electronic equipment, Lviv Polytechnic Publishing House, Lviv, 196 p.

Kozlov, V.A. and Ushakov, I.A. (1985), Handbook for calculating the reliability of radio electronics and automation equipment, Soviet Radio, Moscow, 462 p.

Barlow R. and Proshan F. (1985), “Statistical theory of reliability and failure test”, Nauka, Moscow, 388 p.

Gaevsky, S.V., Balakireva, S.M., Komarov, D.V. and Yavtushenko, V.O. (2020), “Analysis of the electronic system of the aircraft as an object of extension of service life”, Control, navigation and communication systems, No 1 (59), pp. 15–20.