Development of a Method for Computation of Aircraft Safety Control Signal

The optimal flight safety management of an aircraft is considered, on the basis of which the signal for parrying the threat of an aviation accident is calculated. In the process of analyzing the factors affecting the flight safety of the aircraft, the psychophysical state of the crew, the serviceability of the aircraft’s onboard equipment and the flight weather conditions are separated into separate groups. Based on the performed analysis, a target function of aircraft flight safety management is proposed in the form of a maximum, which is provided by the output signal of the aircraft flight safety management system. The calculation of the control signal is based on a count state of the flight conditions of the aircraft, which allows us to estimate the causal relationship of the factors of threat of the accident, and to determine the control signal with the safety of the vessel. In the course of this work, an algorithm for calculating the aircraft safety control signal has been developed. The results obtained during the work can be used for software and hardware implementation of aircraft flight safety management systems, as well as for the design of systems and complexes of its onboard equipment.

safety control systems of flight, optimal control, aviation accident, control signal, state graph

1. Sapagov V. A., Anisimov K. S., Novozhilov A. V. Fail-safe Computing System for Integrated Flight Control Systems, Trudy MAI, vol. 45, available at: http://www.mai.ru/science/trudy/ (Accessed: 01.03.2017) (in Russian).

2. Obolensky Ju. G. et al. Remote control systems and stee ring gears: structures and developments, Vestnik MAI, 2016, vol. 20 (2), pp. 161—171 (in Russian).

3. Black G. Th., Moorhouse D. J. Flying Qualities Design Requirements for Sidestick Controllers, 1979, 186 p., available at: http://contrails.iit.edu/reports/9304.

4. Popov Ju. V. Safety indicators of aviation flights, Available at: http://agps-2006.narod.ru/ttb/2014-6/10-06-14.ttb.pdf (Accessed: 04.02.2017) (in Russian).

5. Zheltov S. Yu., Fedunov B. E. Operational Goal-Setting in Anthropocentric objects from the Viewpoint of the Conceptual Model called Etap: I. St ructures of Algorithms for the Support of Crew Decision-Making, J. Comput.Syst.Sci., 2015, vol. 54, no. 3, pp. 384—398.

6. Levin D. N., Grif M. G. Formalization of Ergonomic Indicators During Research Data-Control Field of the Aircraft Cockpi, 2019 Modern Safety Technologies in Transportation (MOSATT), Kosice, Slovakia, 2019, pp. 94—97.

7. Fedunov B. E., Prokhorov M. D. Conclusion on precedent in knowledge bases of onboard intellectual systems, Iskusstvennyj intellekt i prinjatie reshenij, 2010, no.3, pp. 63—72 (in Russian).

8. Bolshakov A. A., Kulik A. A., Sergushov I. V. (2016). Development the control system algorithms functioning of flight safety for the aircraft of helicopter type, Izvestija Samarskogo nauchnogo centra RAN, 2016, vol. 18, no. 1, pp. 358—362 (in Russian).

9. Kuklev E. A. Safety management of aircrafts based on fuzzy assessments of risks of abnormal flight conditions, Nauchnyj vestnik MGTU GA, 2016, no. 226, pp. 199—205 (in Russian).

10. Rezchikov A. F. et al. Diagnostics of operators’ dangerous states in case of critical events’ combinations in man-machine systems, Vestnik komp’juternyh i informacionnyh tehnologij, 2017, no. 8(158), pp. 48—56 (in Russian).