Share:


Investigation of the residual tropospheric error influence on the coordinate determination accuracy in a satellite landing system

    Oleksandr Kutsenko   Affiliation
    ; Svitlana Ilnytska   Affiliation
    ; Valeriy Konin   Affiliation

Abstract

This paper presents the results of the investigation of the residual tropospheric error influence on coordinate determination in a GNSS landing system. The ICAO recommended methodology for residual tropospheric error calculation is taken as a basis for the present research. Special attention is paid to the troposphere refractivity index and troposphere scale height, which are derived from the well-known troposphere refraction MOPS model. A computer simulation is performed for them for the whole year and the northern hemisphere latitudes. Hardware in the loop simulation has been performed to complement the computer simulation study and investigate the situation with the residual tropospheric error calculation for the experimental GNSS satellites configuration. The experimental measurement session with a duration of about 9 hours is recorded to obtain the configuration of real navigation satellites The residual tropospheric error in meters is calculated for each navigation satellite visible during the experiment. The authors investigate the residual tropospheric error influence on the accuracy of the coordinates determined in the GNSS landing system.

Keyword : global navigation satellite system (GNSS), landing system, ground based augmentation system (GBAS), residual tropospheric error, refraction index, scale height, computer simulation

How to Cite
Kutsenko, O., Ilnytska, S., & Konin, V. (2018). Investigation of the residual tropospheric error influence on the coordinate determination accuracy in a satellite landing system. Aviation, 22(4), 156-165. https://doi.org/10.3846/aviation.2018.7082
Published in Issue
Dec 14, 2018
Abstract Views
1007
PDF Downloads
638
Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

References

Cabinet of Ministers of Ukraine. (2013). Pro vіdnesennya naukovikh ob’єktіv do takikh, shcho stanovlyat’ natsіonal’ne nadbannya [Decree from 28.08.2013 # 650-p. About referring of scientific objects as a national heritage. “Experimental Complex of Monitoring of Global Navigation Satellite Systems of National Aviation University”]. Retrieved 16 May 2018 from http://zakon2.rada.gov.ua/laws/show/650-2013-%D1%80

Global Positioning Systems Directorate. (2016). Global Positioning Systems Directorate, System engineering and integration, Interface specification IS-GPS-200. NAVSTAR GPS Space Segment / Navigation User Segment Interfaces. Retrieved 16 March 2018 from https://www.gps.gov/technical/icwg/IRNIS-200H-001+002+003_rollup.pdf

Grewal, M. S., Andrews, A. P., & Bartone, C. G. (2013). Global navigation satellite systems, Inertial Navigation, and Integration (3rd ed.). New Jersey, Hoboken: John Wiley & Sons, Inc. (603 p.)

EUROCONTROL. (n.d.). Ground-Based Augmentation System (GBAS). Retrieved 16 May 2018 from http://www.eurocontrol.int/gbas

Hofmann-Wellenhof, B., Lichtenegger, H., & Wasle, E. (2008). GNSS – Global Navigation Satellite Systems. GPS, Glonass, Galileo and more. Wien: Springer-Verlag press. https://doi.org/10.1007/978-3-211-73017-1

Hopfield, H. S. (1969). Two-Quartic tropospheric refractivity profile for correcting satellite data. Journal of Geophysical Research, 74(18), 4487-4499. https://doi.org/10.1029/JC074i018p04487

International Civil Aviation Organization. (2016). Global Air Navigation Plan 2016–2030 (ICAO Doc 9750-AN/963). (5 ed.). Retrieved 16 May 2018 from https://www.icao.int/airnavigation/Documents/GANP-2016-interactive.pdf

International Civil Aviation Organization. (2012a). GNSS manual for technical introduction of mandatory GNSS operations (ICAO Doc 9849) (2d ed.). Retrieved 16 May 2018 from https://www.icao.int/Meetings/anconf12/Documents/Doc.%209849.pdf

International Civil Aviation Organization (2012b). Aeronautical Telecommunications. Annex 10 to the Convention on International Civil Aviation (Vol. 1, 6 ed.). Retrieved 16 May 2018 from https://www.theairlinepilots.com/forumarchive/quickref/icao/annex10.1.pdf

Kutsenko, O. V., Ilnytska, S. I., & Konin, V. V. (2017, May 17). Troposphere parameters calculation and residual error modeling for GNSS landing system. In 20th Conference for Junior Researchers “Science – Future of Lithuania” Transport Engineering and Management, Vilnius, Lithuania (pp. 63-68). Retrieved 26 March 2018 from http://jmk.transportas.vgtu.lt/index.php/tran2017/tran2017/paper/viewFile/122/145

Kutsenko, O. V., Ilnytska, S. I, Kondratuik, V. M., & Konin, V. V. (2017, October 17-19). Unmanned aerial vehicle position determination in GNSS landing system. In 2017 IEEE 4th International Conference Actual Problems of Unmanned Aerial Vehicles Developments (APUAVD), Kyiv, Ukraine (pp. 79-84). IEEE. https://doi.org/10.1109/APUAVD.2017.830878

NovAtel Inc. (n.d.). High Precision GNSS Receivers. Retrieved 16 May 2018 from https://www.novatel.com/products/gnss-receivers/

NovAtel Inc. (2018). Waypoint products group: A NovAtel precice postioning product GrafNav / GrafNet GarfNav Static. Software Version 8.70 User Manual, REV 4. (Publication No. OM-20000165). Retrieved 19 March 2018 from https://www.novatel.com/assets/Documents/Waypoint/Downloads/GrafNav-GrafNet-User-Manual-870.pdf

Pershin, D. Yu. (2009). Comparative analysis of tropospheric delay models in precise point positioning in satellite navigation systems GLONAS/GPS”. NGU Proceedings. Information Technologies Series, 7(1), 84-91. Retrieved 19 May 2018 from https://cyberleninka.ru/article/v/sravnitelnyy-analiz-modeley-troposfernoy-zaderzhki-v-zadache-opredeleniya-mestopolozheniya-vysokoy-tochnosti-v-sputnikovyh (in Russian).

RTCA. (2004). Minimum Aviation System Performance Standards for the Local Area Augmentation System (LAAS) (RTCA DO-245A). Retrieved 16 March 2018 from https://standards.globalspec.com/std/11988/rtca-do-245

RTCA. (2016). Minimum Operational Performance Standards for Global Positioning System/Satellite-Based Augmentation System Airborne Equipment (RTCA DO-229E). Retrieved 26 March 2018 from https://standards.globalspec.com/std/10072442/rtca-do-229

Saastamoinen, J. (1972). Atmospheric correction for the troposphere and stratosphere in radio ranging of satellites. In S. W. Henriksen, A. Mancini, & B. H. Chovitz (Eds.), The use of Artificial Satellites for Geodesy. Geophysical Monograph Series, 115, 247-251. Washington, DC: AGU. https://doi.org/10.1029/GM015p0247

Schüler, T. (2001). On ground-based GPS Tropospheric Delay Estimation (PhD dissertation). Universität der Bundeswehr, Munich. Retrieved 16 May 2018 from https://www.unibw.de/IfG/Org/schriftenreihe/pdf-ordner/heft-73/heft-73.pdf

Warburton, J. (2010, October 21). Tropospheric error bounding: nominal and anomalous nominal tropospheric conditions. parameter calculation and consistency. Paper presented at CAAC Team Discussions. Retrieved 16 May 2018 from http://laas.tc.faa.gov/documents/CAAC/CAAC%2011%20Tropospheric%20Threat.pdf