Development of system for selecting suitable landing location inside the local hazard area

Authors

DOI:

https://doi.org/10.15587/1729-4061.2021.243298

Keywords:

emergency situation, suitable geolocation, assistance system, flight area, efficiency criteria

Abstract

In the area of successful landing and guidance of the aircraft on the route, flight safety is perceived as the highest rate of observation of all operational-control functions of the aircraft. The given functions of the aircraft are observable and identifiable by the systems and cognitive perceptions of the pilot. Situational control of the aircraft on the route with the identification of the danger, into which the pilot can get is perceived as an exact element of failure. If the pilot enters such a situation, apriori solutions are offered to him/her by the aircraft information system. The character and emergency solution in the highest criticism of the failure of aircraft systems is the controlled landing in the local safety corridor when guiding the aircraft on the selected route. The aim of the article is the theory of the solution for the introduction of an assistance element in small aircraft with a description of the solution of autonomous choice of geolocation in a defined local environment. By a heuristic experiment in the article, let’s prove the methods of selection of geographical areas for landing an aircraft with the possibility of introduction into the aircraft information system. The article presents the methodology of creation autonomous assistance system, based on the measurement of detection areas for landing with the collection of data from the GIS system. This system can assist in pilot training and real flights for small aircraft without difficulty. The effectiveness of such system and the parameterization of its data were shown and proved. The developed models may be further used for creation an autonomous selection system in the event of accidental aircraft failures

Author Biographies

Pavol Kurdel, Technical University of Košice

PhD, Associate Professor

Department of Avionics

David Pastir, Technical University of Košice

Postgraduate Student

Department of Air Traffic Management

Jaroslav Zaremba, University of Security Management in Košice

Postgraduate Student

Institute of Security Science

Lukas Korba, Technical University of Košice

Postgraduate Student

Department of Avionics

Anna Yakovlieva, National Aviation University

PhD, Leading Researcher

References

  1. Kvasnic, P., Kvasnica, I. (2007). Informačné technológie a matematické modely v leteckých trenažéroch. Trenčianska Univerzita A.D.
  2. Madarász, L. (2004). Inteligentné technológie a ich aplikácie v zložitých systémoch. University Press Elfa.
  3. Pavlik, M., Gladyr, A., Zbojovsky, J. (2020). Comparison of Measured and Simulated Data of Shielding Effectiveness, Reflection and Absorption of Electromagnetic Field. 2020 IEEE Problems of Automated Electrodrive. Theory and Practice (PAEP). doi: https://doi.org/10.1109/paep49887.2020.9240895
  4. Madarász, L., Sarnovský, J., Bizík, J. (1992). Control of Complex systems. Bratislava.
  5. Douglas, A. (2002). Symbiotic Interactions. Oxford University Press.
  6. Zajac, G. (2016). The Role of Air Transport in the Development of International Tourism. Journal of international trade, logistics and law, 2 (1), 1–8. Available at: http://www.jital.org/index.php/jital/article/view/37/pdf_10
  7. Tomová, A., Dudáš, A. (2018). An Aviation Strategy for Europe: A critical assessment of delivered results. MAD - Magazine of Aviation Development, 6 (3), 17–22. doi: https://doi.org/10.14311/mad.2018.03.03
  8. Muehlethaler, C. M., Knecht, C. P. (2016). Situation Awareness Training for General Aviation Pilots using Eye Tracking. IFAC-PapersOnLine, 49 (19), 66–71. doi: https://doi.org/10.1016/j.ifacol.2016.10.463
  9. Sant’Anna, D. A. L. M. de, Hilal, A. V. G. de. (2021). The impact of human factors on pilots’ safety behavior in offshore aviation companies: A brazilian case. Safety Science, 140, 105272. doi: https://doi.org/10.1016/j.ssci.2021.105272
  10. Thomsen, B. T., Annaswamy, A. M., Lavretsky, E. (2019). Shared Control Between Adaptive Autopilots and Human Operators for Anomaly Mitigation. IFAC-PapersOnLine, 51 (34), 353–358. doi: https://doi.org/10.1016/j.ifacol.2019.01.018
  11. Gabriela, S., Irina-Carmen, A., Tiberiu Adrian, S. (2017). Design of Air Traffic Control Operation System. INCAS BULLETIN, 9 (3), 105–119. doi: https://doi.org/10.13111/2066-8201.2017.9.3.9
  12. Garcia, G., Keshmiri, S. (2013). Adaptive and Resilient Flight Control System for a Small Unmanned Aerial System. International Journal of Aerospace Engineering, 2013, 1–25. doi: https://doi.org/10.1155/2013/289357
  13. Bigazzi, L., Gherardini, S., Innocenti, G., Basso, M. (2021). Development of Non Expensive Technologies for Precise Maneuvering of Completely Autonomous Unmanned Aerial Vehicles. Sensors, 21 (2), 391. doi: https://doi.org/10.3390/s21020391
  14. Andoga, R., Fozo, L., Madarasz, L. (2008). Digital Electronic Control of a Small Turbojet Engine - MPM 20. 2008 International Conference on Intelligent Engineering Systems. doi: https://doi.org/10.1109/ines.2008.4481266
  15. Schmidt, D. (1986). Cooperative synthesis of control and display augmentation. Astrodynamics Conference. doi: https://doi.org/10.2514/6.1986-2204

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Published

2021-10-31

How to Cite

Kurdel, P., Pastir, D., Zaremba, J., Korba, L., & Yakovlieva, A. (2021). Development of system for selecting suitable landing location inside the local hazard area. Eastern-European Journal of Enterprise Technologies, 5(3 (113), 84–91. https://doi.org/10.15587/1729-4061.2021.243298

Issue

Section

Control processes