AIRCRAFT NAVIGATION EFFICIENCY IMPROVING DURING LANDING USING SATELLITE NAVIGATION SYSTEM
DOI:
https://doi.org/10.18372/2306-1472.73.12165Keywords:
aircraft landing, global navigation satellite system, instrument landing, integrity, navigation efficiency, precise landingAbstract
Purpose: Two algorithms have been considered in this article. Both of them make possible to improve aircraft navigation efficiency during landing by satellite navigation system signals. The first algorithm describes creation of two reference planes in space using measured coordinates of four points on the runway and the subsequent calculation of the aircraft horizontal and vertical angular deviation from these planes. The second algorithm describes an autonomous integrity control in the aerodrome area when four satellites are visible. Methods: methods of experiment planning, analytic geometry and linear algebra have been used. Results: obtained a new experimental data. Discussion: The results of experimental research of the first algorithm showed the principal possibility of deviation calculation in this way. It is shown that implementation of this technology will make it possible to increase the efficiency of small aircrafts navigation during landing at aerodromes and landing areas that are currently not equipped with radio equipment for instrument landing. The results of research of the second algorithm showed that it allows reducing the number of satellite navigation system failures and also enhances navigation efficiency. These results can be used in the aerospace sector for reducing the number of small aircraft non-flying periods.References
European GNSS Agency (2017), GNSS Market Report, Issue 5, available at https://www.gsa.europa.eu/system/files/reports/gnss_market_report_2017_-_surveying.pdf (Accessed 28 November 2017).
Konin V.V., Zagoruyko V.V. (2000) Sputnikovye navigatsionnie sistemy [Satellite navigation systems]. Money and technologies, no. 4, pp.60–63. (In Russian).
Konin V.V., Zagoruyko V.V. (2001) Obespechenie tochnyh zahodov na posadku metodami sputnikovoj navigacii vsisteme CNSATM Ukrainy [Precise landing using satellite navigation in CNSATM system of Ukraine]. Space science and technology, vol.7, no. 4, pp. 25–30. (In Russian).
Konin V., Shyshkov F. (2015). Extending the Reach of SBAS Some Aspects of EGNOS Performance in Ukraine. InsideGNSS, Januaru– February 2015, pp.50–54.
Konin V.V. (2016) Perspektivy razvitiya GNSS v Ukraine [GNSS development prospects in Ukraine]. Proceedings of Engineering Academy of Ukraine, no.2, pp.13-18. (In Russian)
International Civil Aviation Organization (2017), Global Navigation Satellite System (GNSS) Manual Doc 9849, available at https://www.icao.int/ Meetings/PBN-Symposium/Documents/9849_cons _en%5B1%5D.pdf (Accessed 28 November 2017).
State Aviation Administration of Ukraine (2013), Implementation of Performance Based Navigation (PBN) Ukraine strategy and roadmap 2013–2025, available at https://www.icao.int/safety/ pbn/PBNStatePlans/Ukraine%20PBN%20implementation%20plan.pdf (Accessed 29 November 2017).
Olevinska T.I. (2017). Ispol'zovanie virtual'noj glissady dlya vychisleniya otklonenij letatel'nogo apparata na konechnom uchastke posadki [Application of virtual glide slope for aircraft deviation calculation during landing]. Proceedings of Petersburg Transport University, no. 2, pp. 381-391. (In Russian)
Stratton D.A. Satellite landing system having instrument landing system look alike guidance. Patent US 6239745, available at https://www.google.com/patents/US6239745 (Accessed 29 November 2017).
Fleiger-Holmes S.L, Murphy T.A., Crane J.M. (2012). Airplane position assurance monitor, Patent US 20120265376 A1. Available at http://www.google.it/patents/EP2511733A2?cl=en (Accessed 29 November 2017).
Vygodskiy M.Y. (1977) Spravochnik po vysshej matematike [Reference book on higher mathematics]. Moscow, Science Publ., 852 p. (In Russian)
International Civil Aviation Organization (2006), Aeronautical communication. Annex 10 to ICAO convention, issue 6, available at https://www.icao.int/Meetings/anconf12/Document%20Archive/AN10_V2_cons[1].pdf (Accessed 29 November 2017).
Parkinson B.W., Spilker Jr J.J. (2013) Global Positioning System: Theory and Applications. Washington DC, American Institute of Aeronautics and Astronautics Publ., 793 p.
Konin V.V., Olevinska T.I. (2016) [A method of autonomous integrity control of UAV]. Tezisy nauchno-tekhnicheskoj konferencii "Problemy razvitiya global'noj sistemy svyazi, navigacii i nablyudeniya CNSATM" [Collection of theses of the scientific and technical conference «Problems of the development of the global system of communication, navigation, surveillance and air traffic management CNSATM»]. (In Russian).
Antonovich K.M. (2006) Ispol'zovanie sputnikovyh radionavigacionnyh sistem v geodezii [Satellite radio navigation systems in geodesy]. Moscow, Cartgeocentre Publ., 360 p. (In Russian).
Stepanova N.I. (2014) Ekonomika grazhdanskoj aviacii: uchebnoe posobie [Civil aviation economics: students book]. Moscow. MGTU GA Publ., 130 p. (In Russian).
