Logic-probabilistic modeling of hazardous situations in the investigation of aviation events

The article presents an original formalizable logical-probabilistic model for the development of hazardous situations in flight, the use of which contributes to the deepening of the analysis of flight safety as a state of the air transport system, covering all its components and interfaces directly or indirectly involved, the current state of which determines the risk of an accident in each specific flight.

It is shown that the effectiveness of measures to reduce the risk of aviation accidents (prevention of aviation events) within the framework of the civil aircraft flight safety management system is largely determined by the level of organization, depth and quality of the investigation of aviation events.

The developed model is essential for organizing the collection of data and recording the results of aviation events investigation, as well as hazard and risk factors that pose a threat to the safety of civil aircraft flights. It allows you to implement a systematic approach to the investigation of aviation accidents, aviation incidents and their prerequisites, providing coverage of all directly or indirectly involved components of the air transport system and interfaces, the current state of which determines the risk of an accident in each particular flight.

The collection and registration of the results of the investigation of aviation events, data on hazard and risk factors for flight safety within the framework of the state system for managing the safety of civil aircraft flights on the basis of the developed model contributes to the fulfillment of the requirements of international and national legislation by all participants in the flight safety management process

1. Bezopasnost' poletov letatel'nykh apparatov [Aircraft flight safety]. Moscow: VVIA im. prof. N.Ye. Zhukovskogo, 2003. 365 p. (In Russian)

2. Bogomolov A. V., Klimov R. S. (2017). Automation of information processing during collective network expertise .Avtomatizatsiya. Sovremennyye tekhnologii. Vol. 71. 11:509-512. (In Russian)

3. Bolkhovitinov O. V., Volynov I. I., Mikhalev G. Ye., Podolyak M. P. (1991). Teoriya veroyatnosti i matematicheskaya statistika [Probability theory and mathematical statistics]. Moscow: VVIA im. N. Ye. Zhukovskogo, 195 p. (In Russian)

4. Bolshakov A. A., Kulik А. А. (2021). Algorithm of a device designed to support decision making to counter the threat of an aviation accident. Herald of the Bauman Moscow State Technical University. Series Instrument Engineering. 3 (136): 46-59.

5. Filimonyuk L. Yu. (2021). Models and methods for a safe aviation transport systems' functioning subject to the human factor. IFAC-PapersOnLine. 20th. 627-630.

6. Fokin A. V., Guziy A. G. (2017). Methodological support of risk management procedures for commercial aviation flight safety. Vestnik Irkutskogo gosudarstvennogo tekh-nicheskogo universiteta. 10 (129): 77. (In Russian)

7. Frolkin A. I. (2004). Systematic analysis of the causes-factors contained in the "Rules for the investigation of aviation accidents and aviation incidents with state aircraft in the Russian Federation". Trudy obshchestva nezavisimykh rassledova-teley aviatsionnykh proisshestviy. Vypusk 16. Moscow: Poligraf. Pp. 87-107. (In Russian)

8. Guziy A. G. (2007). Methodology of logical-probabilistic quantitative assessment and active management of the risk of aviation accidents in upcoming flights. Problemy bezopasnosti poletov. 11: 24-34. (In Russian)

9. Guziy A. G., Lushkin A. M., Markov N. A., Mayorova Yu. A. (2020a). Methods of risk metering of emergencies with civil aviation aircraft. Problemy bezopasnosti poletov. 7: 31-41. (In Russian)

10. Guziy A. G., Lushkin A. M., Mishin A. V., Shiryayev D. A. (2021). Sistema upravleniya bezopasnost'yu poletov ekspluatanta vozdushnykh sudov [Flight safety management system for an aircraft operator]. Moscow: ID Akademiya Zhukovskogo, 182 p. (In Russian)

11. Guziy A. G., Mayorova YU. A., Mishin A. V., Shiryayev D. A. (2020b). Organizational and psychological analysis of the effectiveness of the investigation of aviation events in commercial aviation in Russia. Organizatsionnaya psikhologiya. Vol. 10. 1: 121-140. (In Russian)

12. Kozlov V. V. (2015). Theory and practice of investigating aviation events related to the actions of a pilot (specialist). Problemy bezopasnosti poletov. 3: 26-48. (In Russian)

13. Kozlov V. V., Kosolapov O. A., Fedoruk A. G. (2017). Development of methodology for determining the causes of flight accidents. Chelovecheskiy faktor: problemy psikhologii i ergonomiki. 3-1 (84): 68-72. (In Russian)

14. Convention on International Civil Aviation (2020). Annex 13. Aircraft Accident and Incident Investigation Ed. 12. Montreal: ICAO, 72 p.

15. Larkin E. V., Bogomolov A. V., Gorbachev D. V., Privalov A. N. (2019). Investigation of criteria for matching the flow of events to the Poisson flow. Vestnik komp'yuternykh i informa-tsionnykh tekhnologiy. 1 (175): 3-11. DOI: 10.14489/vkit.2019.01.pp.003-011 (In Russian)

16. Larkin E. V., Bogomolov A. V., Privalov A. N., Dobrovolsky N. N. (2018b). Discrete model of paired relay-race. Bulletin of the South Ural State University. Series: Mathematical Modelling, Programming and Computer Software. Vol. 11. 3:72-84. DOI: 10.14529/mmp180306.

17. Larkin E. V., Bogomolov A. V., Privalov A. N., Dobrovolsky N. N. (2018c). Relay races along a pair of selectable routes. Bulletin of the South Ural State University. Series: Mathematical Modelling, Programming and Computer Software. Vol. 11. 1: 15-26. DOI: 10.14529/mmp180102.

18. Larkin E., Bogomolov A., Gorbachev D., Privalov A. (2017). About approach of the transactions flow to poisson one in robot control systems. Lecture Notes in Computer Science. Vol. 10459 LNAI: 113-122.

19. Larkin E., Kotov V., Bogomolov A., Privalov A. (2018a). Multiple swarm relay-races with alternative routes. Lecture Notes in Computer Science. Vol. 10941 LNCS: 361-373.

20. Makarenko V. G., Bogomolov A. V., Rudakov S. V., Podorozhnyak A. A. (2007). Technology for building an inertial satellite navigation system for vehicle control with neural network optimization of the composition of the measurement vector. Mekhatronika, avtomatizatsiya, upravleniye. 1: 39-44. (In Russian)

21. Markov N., Bogomolov A., Shishov A., Dvornikov M. (2021). Information technology concept of integration of computing resources and physical processes in cyber-physical systems for personalized information about the potential danger of an emergency situation in high-altitude flight. Studies in Systems, Decision and Control. Vol. 338: 205-214.

22. Nikiforov D. A., Vorona A. A., Bogomolov A. V., Kukushkin Yu. A. (2015). Methods for assessing the potential unreliability of a pilot’s actions. Bezopasnost' zhiznedeyatel'nosti. 7 (175): 7-16. (In Russian)

23. Ponomarenko V. A., Gander D. V., Alekseyenko M. S., Somov M. V. (2020). Methodology and practice of introducing an innovative approach to joint training of pilots and air traffic controllers. Problemy bezopasnosti poletov. 10: 11-21. (In Russian)

24. Ponomarenko V., Tretyakov V., Zakharov A. (2019). Generative games in aviation. Advances in Intelligent Systems and Computing. Vol. 823: 576-581.

25. Postanovlenie Pravitel'stva Rossijskoj Federacii ot 18 noyabrya 2014 g. N 1215, g. O poryadke razrabotki i primeneniya sistem upravleniya bezopasnost'yu poletov vozdushnyh sudov, a takzhe sbora i analiza dannyh o faktorah opasnosti i riska, sozdayushchih ugrozu bezopasnosti poletov grazhdanskih vozdushnyh sudov, hraneniya etih dannyh i obmena imi. Moskva, 2014. (In Russian).

26. Safety Management Manual, Fourth Edition. Doc 9859. Montreal: ICAO, 2018.

27. Soldatov S. K., Bogomolov A. V., Zasyadko K. I., Vonarshenko A. P., Yazlyuk M. N. (2020). Professionally important psychophysiological qualities of flight instructors and their development. Human Physiology. Vol. 46. 7: 806-810.

28. Soldatov S. K., Guziy A. G., Bogomolov A. V. (2007). A priori assessment of the professional reliability of a pilot at the stage of preparation for flights. Problemy bezopasnosti poletov. 8: 33. (In Russian)

29. Tobin D. S., Golosovskiy M. S., Bogomolov A. V. (2020). Technology for ensuring the reliability of information during network expertise. Sovremennyye informatsionnyye tekhnologii i IT-obrazovaniye. Vol. 16. 3: 623-632. (In Russian)

30. Tobin D., Bogomolov A., Golosovskiy M. (2022). Model of organization of software testing for cyber-physical systems. Studies in Systems, Decision and Control. Vol. 418: 51-60.

31. Volkova V. N., Denisov A. A. (2014). Teoriya sistem i sistemnyy analiz [Theory of systems and system analysis]. Moscow: Yurayt, 616 p. (In Russian)

32. Zasyad'ko K. I., Soldatov S. K., Bogomolov A. V., Vonarshenko A. P., Yazlyuk M. N. (2020). Psychophysiological features of the professional activity of a pilot in visual search and detection of small-sized ground objects in adverse weather conditions. Psikhologiya. Psikhofiziologiya. Vol. 13. 4: 87-99. DOI: 10.14529/jpps200410 (In Russian)

33. Zubkov B. V., Prozorov S. Ye. (2011). Bezopasnost' poletov. Moscow: MGTU GA, 2011. 246 p. (In Russian)