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Determination of flying objects position

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Języki publikacji
EN
Abstrakty
EN
This paper describes various methods of flying object positioning with the emphasis on their accuracy. Based on the accomplished analysis, we will select the most appropriate method to determine the position of a flying object for relative navigation purposes. The primary criterion for choosing a positioning method is the accuracy of distance measurement within users working in the aviation communications network. The results presented in the paper have been based on mathematical modelling and computer simulation performed in the Matlab programming environment. The results obtained can be used to navigate flying or non-flying objects that work in the air communications network.
Twórcy
autor
  • Technical University of Kosice, Kosice, Slovakia 
autor
  • Technical University of Kosice, Kosice, Slovakia 
  • Technical University of Kosice, Kosice, Slovakia
Bibliografia
  • 1. Awnage, J.L. & Grafarend, E.W. 2004. Solving Algebraic Computational Problems in Geodesy and Geoinformatics. Germany: Springer, 2004. Kap. 9.2, Ranging by Global Positioning System, p. 107-116. ISBN 3-540-23425-X.
  • 2. Bloudicek, R., Rydlo, S.: Example of scientific manuscript improvement of the teaching process at the subject air traffic management systems by means of simulators and simulation programs 2012. Transport Means - Proceedings of the International Conference, pp. 333-335.
  • 3. Dzunda, M. & Kotianova, N. 2016. The Accuracy of Relative Navigation System. International Conference on Engineering Science and Production Management (Espm) Location: Slovakia Date: Apr. 16-17, Pages: 369-375 Published: 2016. - doi:10.1201/b19259-68
  • 4. Džunda,M. & Kotianová, N. 2015. Selected aspects of applying communication technology to air transportation. International Conference on Communication Technology and Application, June 28-29, 2015 in Bangkok, Thailand. Pages: 1-7.
  • 5. Dzunda, M. & Kotianova N. & Holota, K. & Et Al. 2015. Use of Passive Surveillance Systems in Aviation. [in:] A. Weintrit (ed.), Activities in Navigation: Marine Navigation and Safety of Sea Transportation. Pages: 249-253. Published: 2015. - doi:10.1201/b18513-40
  • 6. Dzunda, M. & Hrban, A. 1998. Accuracy of The Passive Tracking Systems. 12th International Conference On Microwaves And Radar (Mikon98), Krakow, Poland. Date: May 20-22, 1998. Pages: 216-220 Published: 1998.
  • 7. Kotianova,N. 2017. Relative Navigation in The Air Communications Network. Dissertation, LF TUKE in Košice 2017. 138p.
  • 8. Pavolová, H. & Tobisová, A. 2013. The Model of Supplier Quality Management in a Transport Company. Nase More. Vol. 60, No. 5-6, pp. 123-126. ISSN 0469-6255.
  • 9. Rozenberg, R. & Szabo, S. & Šebeščáková, I. 2014. Comparison of Fsc and Lcc and Their Market Share in Aviation. In: International Review of Aerospace Engineering (Irease). Vol. 7, No. 5 (2014), p. 149-154. ISSN 1973-7459. - doi:10.15866/irease.v7i5.4439
  • 10, Sabo, J. & Korba, P. & Antoško, M. & Sekelová, M. & Rozenberg, R. 2017. Gnss Approach on Small Regional non Public Airports. In: Sgem 2017. Sofia 2017, p. 559-564. ISBN 978-619-7408-03-4.
  • 11. Šebeščáková, I. & Melníková, L. & Socha, Ľ. 2013. The Assessment of The Contribution of Aviation to the National Economy. In: Exclusive E-Journal. Roč. 1, Č. 2, 2013, S. 1-10. Issn 1339-4509.
  • 12. Vagner, J. Pappová, E. 2014. Comparison of Radar Simulator for Air Traffic Control. In: Nase More. Vol. 61, no. 1-2 (2013), p. 31-35. - ISSN 0469-6255.
Uwagi
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).
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Bibliografia
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