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This paper presents an algorithm for determining the precision parameter for aircraft position coordinates based on a combined GPS/EGNOS and GPS/SDCM solution. The proposed algorithm uses a weighted average model that combines a single GPS/EGNOS and GPS/SDCM position navigation solution to determine the resulting aircraft coordinates. The weighted mean model include the linear coefficients as a function of: the inverse of the number of tracked GPS satellites for which EGNOS and SDCM corrections have been generated, and the inverse of the geometric coefficient of the PDOP (Position Dilution of Precision). The corrections between the single GPS/EGNOS and GPS/SDCM solution to the aircraft's resultant coordinates are then calculated on this basis. Finally, the standard deviation for the aircraft resultant BLh (B-Latitude, L-Longitude, h-ellipsoidal height) coordinates is calculated as a measure of precision. The research experiment used recorded on-board GPS+SBAS data from two GNSS receivers mounted on a Diamond DA 20-C1 aircraft. The test flight was carried out on the Olsztyn-Suwałki-Olsztyn route. The calculations of aircraft position based on GPS/EGNOS and GPS/SDCM solution were performed in the RTKLIB v.2.4.3 program in the RTKPOST module. Next, aircraft resultant coordinates and standard deviations were computed in Scilab v.6.0.0 software package. Based on the tests performed, it was found that for the Trimble Alloy receiver, the standard deviation values for the ellipsoidal coordinates BLh of the aircraft do not exceed 1.77 m. However, for the Septentrio AsterRx2i receiver, the values of standard deviations for the aircraft's ellipsoidal BLh coordinates do not exceed 5.04 m. The use of linear coefficients as the inverse of the number of tracked GPS satellites with SBAS corrections in the GPS/EGNOS+GPS/SDCM positioning model resulted in a reduction in standard deviations of approximately 50-51% relative to the solution with linear coefficients calculated as the inverse of the PDOP parameter. In paper, the standard deviation was also obtained using arithmetic mean model. However the values of standard deviation from weighted mean model are lower than arithmetic mean model.
Czasopismo
Rocznik
Tom
Strony
105--117
Opis fizyczny
Bibliogr. 44 poz., wykr., wzory
Twórcy
autor
- Institute of Navigation, Polish Air Force University, Dęblin, Poland
autor
- Institute of Navigation, Polish Air Force University, Dęblin, Poland
autor
- Faculty of Aviation, Polish Air Force University, Dęblin, Poland
autor
- Faculty of Geoengineering, University of Warmia and Mazury in Olsztyn, Poland
autor
- Faculty of Geoengineering, University of Warmia and Mazury in Olsztyn, Poland
autor
- Silesian University of Technology, Faculty of Transport and Aviation Engineering, Gliwice, Poland
autor
- Silesian University of Technology, Faculty of Transport and Aviation Engineering, Gliwice, Poland
Bibliografia
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- [3] Breeuwer, E., Farnworth, R., Humphreys, P., Mcgregor, A., Michel, P., Secretan, H., Leighton, S. J., Ashton, K. J. (2000). Flying EGNOS: The GNSS-1 Testbed, Paper Galileo’s World, January 2000, 10-21. Available at: http://www.egnospro.esa.int/Publications/navigation.html, [Accessed: 10 May 2023].
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- [6] Fellner, A., Trómiński, P., Banaszek, K. (2009). EGNOS APV-I and HEDGE projects implementation in Poland. Geophys. Res. Abstr., 11, 4932.
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- [11] Fellner, R. (2014). Analysis of the EGNOS/GNSS parameters in selected aspects of Polish transport. Transport Problems, 9, 27-37.
- [12] Felski, A., Banaszek, K., Woźniak, T., Zakrzewski, P. (2011). Accuracy of EGNOS service in airport operations. Zeszyty Naukowe Marynarki Wojennej, 52, 1(184): 31-44. (In Polish). [13] Felski, A., Nowak, A. (2011). Accuracy and availability of EGNOS-Results of observations. Artif. Satell., 46, 111-118, DOI: 10.2478/v10018-012-0003-0.
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- [16] Gołda, P. (2018). Selected decision problems in the implementation of airport operations. Scientific Journal of Silesian University of Technology. Series Transport, 101, 79-88. DOI: 10.20858/sjsutst.2018.101.8.
- [17] Gołda, P., Zawisza, T., Izdebski, M. (2021). Evaluation of efficiency and reliability of airport processes using simulation tools. Eksploatacja i Niezawodnosc – Maintenance and Reliability, 23 (4): 659–669, DOI: 10.17531/ein.2021.4.8.
- [18] Grunwald, G., Bakuła, M., Ciećko, A. (2016). Study of EGNOS accuracy and integrity in eastern Poland. Aeronaut. Journal, 1230, 1275-1290, DOI: 10.1017/aer.2016.66.
- [19] Grzegorzewski, M. (2005). Navigating an aircraft by means of a position potential in three dimensional space. Annual of Navigation, 9, 1-111.
- [20] Hvezda, M. (2021). Simulation of EGNOS satellite navigation signal usage for aircraft LPV precision instrument approach. Aviation, 25, 171-181, DOI: 10.3846/aviation.2021.14554.
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- [22] Jafernik, H. (2016). Assessment of the Usefulness of EGNOS Differential Corrections in Conducting GPS Static Measurements. Int. J. Eng. Res. Appl., 6, 25-30.
- [23] Januszewski, J. (2010). Satellite Navigation Systems in the Transport, Today and in the Future. Archives of Transport, 22, 175-187.
- [24] Januszewski, J. (2011). A Look at the Development of GNSS Capabilities Over the Next 10 Years. TransNav Int. J. Mar. Navig. Saf. Sea Transp., 5, 73-78.
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- [27] Kaleta, W. (2014). EGNOS Based APV Procedures Development Possibilities In The South-Eastern Part of Poland. Annual of Navigation, 21, 85-94, DOI: 10.1515/aon2015-0007.
- [28] Kaleta, W. (2015). Future EGNOS APV procedures implementation in Poland as a chance for small and medium airports development. Trans. Inst. Aviat., 240, 18-26.
- [29] Krasuski, K., Wierzbicki, D., Bakuła, M. (2021). Improvement of UAV Positioning Performance Based on EGNOS+SDCM Solution. Remote Sens., 13, 2597, DOI: 10.3390/rs13132597.
- [30] Krasuski, K., Mrozik, M., Wierzbicki, D., Ćwiklak, J., Kozuba, J., Ciećko, A. (2022). Designation of the Quality of EGNOS+SDCM Satellite Positioning in the Approach to Landing Procedure. Applied Sciences, 12, 1335, DOI: 10.3390/app12031335.
- [31] Krzykowska-Piotrowska, K., Dudek, E., Wielgosz, P., Milanowska, B., Batalla, J. M. (2021). On the Correlation of Solar Activity and Troposphere on the GNSS/EGNOS Integrity. Fuzzy Logic Approach. Energies, 14, 4534, DOI: 10.3390/en14154534.
- [32] Muls, A., Boon, F. (2001). Evaluating EGNOS augmentation on a military helicopter. In Proceedings of the 14th International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GPS 2001), Salt Lake City, UT, USA, 11-14 September 2001; 2458-2462.
- [33] Oleniacz, G. (2015). GNSS technology and its applications in implementation and control measurements. Wyższa Szkoła Inżynieryjno Ekonomiczna z siedzibą w Rzeszowie, 2015, ISBN: 978-83-60507-24-7. (In Polish).
- [34] Oleniacz, G., Świętoń, T. (2018). Accuracy of RTN-GNSS measurement in various measuring conditions, Przegląd Geodezyjny, 90(1), 20-22, DOI: 10.15199/50.2018.1.3. (In Polish).
- [35] Oliveira, J., Tiberius, C. (2008). Landing: Added Assistance to Pilots on Small Aircraft Provided by EGNOS. In Proceedings of the Conference 2008 IEEE/ION Position, Location and Navigation Symposium, Monterey, CA, USA, 5-8 May 2008; 321-333.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2024)
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-dcfc64cd-b03c-45c2-aa35-e1278d1e6222