Improving positioning accuracy of aircraft using SPP method in GLONASS system

Authors

DOI:

https://doi.org/10.61089/aot2024.v0s1gv25

Keywords:

GLONASS, GPS, accuracy, position errors, SPP code method

Abstract

The paper presents the results of a study showing the accuracy of the determination of aircraft position coordinates based on the SPP (Single Point Positioning) solution in the GLONASS (Globalnaja Navigatsionnaya Sputnikovaya Sistema) system. For this purpose, the paper develops and implements an algorithm for the correction of position errors as parameters describing positioning accuracy. The proposed algorithm uses position error values determined for a single GNSS (Global Navigation Satellite Systems) receiver, which are joined in a linear combination to determine the positioning accuracy of the aircraft. The algorithm uses linear coefficients as an inverse function of the number of GLONASS satellites being tracked by the GNSS receiver. The developed algorithm was tested for GLONASS satellite data recorded by Topcon HiPer Pro and Javad Alpha geodetic receivers, during a flight test carried out with a Cessna 172 aircraft around the military airport in Dęblin. Navigation calculations were carried out using RTKLIB v.2.4.3 and Scilab v.6.0.0 software. On the basis of the tests carried out, it was found that for single Topcon HiPer Pro and Javad Alpha receivers, position errors were up to ±11.4 m. However, by using the position error correction algorithm for both receivers, GLONASS positioning accuracy is up to ±3.6 m. The developed algorithm reduces position errors by 60-80% for all BLh (B- Latitude, L- Longitude, h- ellipsoidal height) coordinates. The paper shows the possibility of testing and implementing the proposed mathematical algorithm for the SPP solution in a GPS (Global Positioning System) navigation system. In this case the position errors from the GPS SPP solution range from -0.9 m to +0.9 m for all BLh coordinates. The obtained results showed that application the GLONASS and GPS system in air transport is important. The algorithm used in this work can also be applied to other global GNSS navigation systems (e.g. Galileo (European Navigation Satellite system) or BeiDou (Chinese Navigation Satellite System))  in air transport and navigation.

References

Baburov, V. I., Ivantsevich, N. V., Sauta, O. I. (2017). GLONASS technologies for controlling the fields of short-range navigation and landing systems, In Proceedings of 2017 24th Saint Petersburg International Conference on Integrated Navigation Systems (ICINS), 1-4. https://doi.org/10.23919/ICINS.2017.7995681.

Baburov, V. I., Vasileva, N. V., Ivantsevich, N. V. (2018). Navigation sharing prospects GLONASS and pseudolites fields for navigation and landing of aircraft in Arctic. Voprosy radioelektroniki, 7, 13-17, https://doi.org/10.21778/2218-5453-2018-7-13-17.

Bang, E., Milner, C., Macabiau, C., Estival, P. (2018). Preliminary Integrity Assessment for GPS/GLONASS RAIM with Multiple Faults, In Proceedings of 2018 IEEE/ION Position, Location and Navigation Symposium (PLANS), Monterey, CA, April 2018, 327-335. https://doi.org/10.1109/PLANS.2018.8373398.

Blanch, J., Walter, T., Enge, P. (2012). Satellite Navigation for Aviation in 2025, In Proceedings of the IEEE, 100, no. Special Centennial Issue, 1821-1830. https://doi.org/10.1109/JPROC.2012.2190154.

Dumas, P.-Y. (2011). GLONASS-K for Airborne Applications, InsideGNSS, July/August, 46-50.

Gorskiy, E., Kopylov, I., Kharin, E., Kopelovich, V., Yasenok, A. (2019). Trajectory Measurements during Monitoring and Testing of Ground-Based Radio Equipment and Airborne Equipment of Instrument Landing Systems, In Proceedings of 2019 26th Saint Petersburg International Conference on Integrated Navigation Systems (ICINS), 1-4. https://doi.org/10.23919/ICINS.2019.8769357.

Grzegorzewski, M. (2005). Navigating an aircraft by means of a position potential in three dimensional space. Annual of Navigation, 9, 1-111.

Hegarty, C. J., Chatre, E. (2008). Evolution of the Global Navigation Satellite System (GNSS), In Proceedings of the IEEE, 96 (12), 1902-1917. https://doi.org/10.1109/JPROC.2008.2006090.

Ilcev, S. D. (2011). Implementation of Local Satellite Augmentation System (LSAS) for airport infrastructures, In Proceedings of 2011 International Siberian Conference on Control and Communications (SIBCON), 207-211. https://doi.org/10.1109/SIBCON.2011.6072633.

Ilyin, V., Kopylov, I., Kharin, E., Kopelovich, V., Yakushev, A., Zhabin, P. (2022). Flight Tests of Onboard SNS Equipment Characteristics During Operation with Different Global Navigation Satellite Systems, In Proceedings of 2022 29th Saint Petersburg International Conference on Integrated Navigation Systems (ICINS), 1-5. https://doi.org/10.23919/ICINS51784.2022.9815371.

International Civil Aviation Organization, (2006). ICAO Standards and Recommended Practices (SARPS), Annex 10 Volume I (Radio Navigation Aids). Available online: www.ulc.gov.pl/pl/prawo/prawo-mi%C4%99dzynarodowe/206-konwencje, [Accessed on: 10.12.2022].

Ivan, A. N., Pandele, C. A., Ionescu, B., Grigorie, T. L. (2023). Analysis of the impact of GNSS disruptions on aircraft operations at Romanian airports. Journal of Physics: Conference Series, 2526, 1-8. https://doi.org/10.1088/1742-6596/2526/1/012096.

Jin, W., Zhai, C., Wang, L., Zhang, Y., Zhan, X. (2009). Ambiguity Function Method Scheme for Aircraft Attitude Sensor Utilising GPS/GLONASS Carrier Phase Measurement. Defence Science Journal, 59(5), 466-470. https://doi.org/10.14429/dsj.59.1548.

Khadonova, S. V., Ufimtsev, A. V., Dymkova, S. S. (2020). “Digital Smart Airport” System Based on Innovative Navigation and Information Technologies, In Proceedings of 2020 International Conference on Engineering Management of Communication and Technology (EMCTECH), 1-6. https://doi.org/10.1109/EMCTECH49634.2020.9261529.

Kokorin, V., Uguy, V., Vladimirov, V. (2005). Transceiver Module of Airplane GPS/GLONASS Tracking System, In Proceedings of TELSIKS 2005 - 2005 uth International Conference on Telecommunication in Modern Satellite, Cable and Broadcasting Services, 570-571. https://doi.org/10.1109/TELSKS.2005.1572178.

Krasuski, K., Ciećko, A., Bakuła, M., Grunwald, G. (2022). Accuracy Examination of the SDCM Augmentation System in Aerial Navigation. Energies, 15, 7776. https://doi.org/10.3390/en15207776.

Marathe, T., Pai, K. P, Suhas, H. N., Rakesh Nayak, A. (2012). GPS GLONASS SBAS receiver for airborne applications, In Proceedings of Proceedings of NAVCOM 2012 Pearl Jubilee International Conference on Navigation and Communication, Hyderabad, India, 20-21 December 2012, 1-4.

Pereira, V.A.S., Monico, G., Camargo, P. (2021). Estimation and analysis of protection levels for precise approach at Rio de Janeiro international airport using real time σVIG for each GPS and GLONASS satellite. Boletim de Ciências Geodésicas, 27, 1-20. https://doi.org/10.1590/s1982-21702021000s00010.

RTKLIB Website, (2022). [Online]. Available at: http://rtklib.com/, [Accessed on: 10.12.2022].

Sarkar, S., Bose, A., (2017). Lifetime Performances of Modernized GLONASS Satellites: A Review, Artificial Satellites, 52 (4), 85–97. https://doi.org/10.1515/arsa-2017-0008.

Sayim, I. (2018). Performance Analysis of GBAS Vertical Protection Levels for Civil Aircraft Precision Approach and Landing using GPS and GLONASS. Afyon Kocatepe University Journal of Science and Engineering, 18, 397-402, https://doi.org/10.5578/fmbd.66811.

Scilab Website, (2022). [Online]. Available at: https://www.scilab.org/, [Accessed on: 10.12.2022].

Skrypnik, O. N., Arefyev, R. O. (2020). Optimization of the trajectory of a mobile pseudosatellite to improve the accuracy of the integrated navigation-time field GLONASS. Modern High Technologies, 2, 51-58. https://doi.org/10.17513/snt.37914.

Skrypnik, O. N., Arefyeveva, N. G. (2017). Construction of an optimal flight trajectory in the GLONASS accuracy field, In Proceedings of 2017 24th Saint Petersburg International Conference on Integrated Navigation Systems (ICINS), 1-3. https://doi.org/10.23919/ICINS.2017.7995606.

Skrypnik, O. N., Arefyeveva, N. G., Arefyev, N. G. (2018). Optimization of an aircraft flight trajectory in the Glonass dynamic accuracy field. Civil Aviation High Technologies, 21(5), 56-66. https://doi.org/10.26467/2079-0619-2018-21-5-56-66.

Takasu T., (2013). RTKLIB ver. 2.4.2 Manual, RTKLIB: An. Open Source Program. Package for GNSS Positioning. Available online: http://www.rtklib.com/prog/manual_2.4.2.pdf [Accessed on: 10.12.2022].

Walter, T., Blanch, J., Choi, M. J., Reid, T., Enge, P. (2013). Incorporating GLONASS into aviation RAIM receivers, In Proceedings of the 2013 International Technical Meeting of The Institute of Navigation, San Diego, California, January 2013, 239-249.

Downloads

Published

2024-03-13

Issue

Section

Original articles

How to Cite

Krasuski, K., Ciećko, A., Grunwald, G., & Kirschenstein, M. (2024). Improving positioning accuracy of aircraft using SPP method in GLONASS system. Archives of Transport, 69(1), 21-37. https://doi.org/10.61089/aot2024.v0s1gv25

Share

Most read articles by the same author(s)

Similar Articles

31-40 of 216

You may also start an advanced similarity search for this article.