Time-frequency analysis of differences between coordinates of three permanent GNSS stations in Krakow

Axelrad, P., Comp, C., and MacDoran, P. (1994). Use of signal-to-noise ratio for multipath error correction in GPS differential phase measurements: methodology and experimental results. In Proceedings of the 7th international technical meeting of the Satellite Division of The Institute of Navigation (ION GPS 1994), Salt Lake City, UT, September 1994, pages 655–666. Search in Google Scholar

Axelrad, P., Comp, C. J., and Macdoran, P. F. (1996). SNR-based multipath error correction for GPS differential phase. IEEE Transactions on Aerospace and Electronic Systems, 32(2):650–660, doi:10.1109/7.489508. Search in Google Scholar

Baker, T. (1984). Tidal deformations of the Earth. Science Progress (1933-), pages 197–233. Search in Google Scholar

Cai, C. and Gao, Y. (2013). Modeling and assessment of combined GPS/GLONASS precise point positioning. GPS solutions, 17:223–236, doi:10.1007/s10291-012-0273-9. Search in Google Scholar

Dach, R., Böhm, J., Lutz, S., Steigenberger, P., and Beutler, G. (2011). Evaluation of the impact of atmospheric pressure loading modeling on GNSS data analysis. Journal of geodesy, 85:75–91, doi:10.1007/s00190-010-0417-z. Search in Google Scholar

Fuhrmann, T., Garthwaite, M. C., and McClusky, S. (2021). Investigating GNSS multipath effects induced by co-located Radar Corner Re˚ectors. Journal of Applied Geodesy, 15(3):207–224, doi:10.1515/jag-2020-0040. Search in Google Scholar

Han, J., Tu, R., Zhang, R., Fan, L., and Zhang, P. (2019). SNR-dependent environmental model: application in real-time GNSS landslide monitoring. Sensors, 19(22):5017, doi:10.3390/s19225017. Search in Google Scholar

Hunegnaw, A. and Teferle, F. N. (2022). Evaluation of the multipath environment using electromagnetic-absorbing materials at continuous GNSS stations. Sensors, 22(9):3384, doi:10.3390/s22093384. Search in Google Scholar

Kazmierski, K., Hadas, T., and Sośnica, K. (2018). Weighting of multi-GNSS observations in real-time precise point positioning. Remote Sensing, 10(1):84, doi:10.3390/rs10010084. Search in Google Scholar

Kim, H.-Y. (2013). Statistical notes for clinical researchers: assessing normal distribution (2) using skewness and kurtosis. Restorative dentistry & endodontics, 38(1):52–54, doi:10.5395/rde.2013.38.1.52. Search in Google Scholar

Kosek, W. (1995). Time variable band pass filter spectra of real and complex-valued polar motion series. Artificial Satellites, 30(1):27–43. Search in Google Scholar

Kouba, J. (2003). Measuring seismic waves induced by large earthquakes with GPS. Studia Geophysica et Geodaetica, 47:741–755, doi:10.1023/A:1026390618355. Search in Google Scholar

Lau, L. and Cross, P. (2005). Use of signal-to-noise ratios for real-time GNSS phase multipath mitigation. In Proc. of National Navigation Conference NAV05, The Royal Institute of Navigation, 1-3 November 2005, London, volume 1. Search in Google Scholar

Leick, A., Rapoport, L., and Tatarnikov, D. (2015). GPS satellite surveying. John Wiley & Sons. Search in Google Scholar

Li, X., Ge, M., Dai, X., Ren, X., Fritsche, M., Wickert, J., and Schuh, H. (2015). Accuracy and reliability of multi-GNSS real-time precise positioning: GPS, GLONASS, BeiDou, and Galileo. Journal of geodesy, 89(6):607–635, doi:10.1007/s00190-015-0802-8. Search in Google Scholar

Mohamed, A. S., Doma, M. I., and Rabah, M. M. (2019). Study the effect of surrounding surface material types on the multipath of GPS signal and its impact on the accuracy of positioning determination. can Journal of Geographic Information System, 8(5):199–205, doi:10.5923/j.ajgis.20190805.01. Search in Google Scholar

Parvazi, K., Farzaneh, S., and Safari, A. (2020). Role of the RLS-VCE-estimated stochastic model for improvement of accuracy and convergence time in multi-GNSS precise point positioning. Measurement, 165:108073, doi:10.1016/j.measurement.2020.108073. Search in Google Scholar

Peppa, I. and Psimoulis, P. (2023). Detection of GNSS antenna oscillatory motion and multipath conditions via exploitation of multipath-induced SNR variations. GPS Solutions, 27(3):117, doi:10.1007/s10291-023-01432-6. Search in Google Scholar

Peppa, I., Psimoulis, P., and Meng, X. (2019). Modelling antenna vibrations using the Signal-to-Noise Ratio (SNR) of GNSS signals. In Proceeding of 4th joint international symposium on deformation monitoring (JISDM) Athe, 15-17 May 2019, Athens, Greece. Search in Google Scholar

Piras, M., Roggero, M., and Fantino, M. (2009). Crustal deformation monitoring by GNSS: network analysis and case studies. In Advances in Geosciences: Volume 13: Solid Earth (SE), pages 87–103. World Scientific, doi:10.1142/9789812836182_0007. Search in Google Scholar

Popiński, W. (2009). On application of the Fourier transform band pass filtering technique. Artificial Satellites, 44(4):149–160, doi:10.2478/v10018-009-0026-3. Search in Google Scholar

Popiński, W. and Kosek, W. (1995). The Fourier transform band pass filter and its application for polar motion analysis. Artificial Satellites, 30(1):9–25. Search in Google Scholar

Prochniewicz, D. and Grzymala, M. (2021). Analysis of the impact of multipath on Galileo system measurements. Remote Sensing, 13(12):2295, doi:10.3390/rs13122295. Search in Google Scholar

Ren, Y., Lian, L., and Wang, J. (2021). Analysis of seismic deformation from global three-decade GNSS displacements: implications for a three-dimensional Earth GNSS velocity field. Remote Sensing, 13(17):3369, doi:10.3390/rs13173369. Search in Google Scholar

Richardson, T., Hill, C., Moore, T., and Toor, P. (2016). Analysis of multi-constellation GNSS signal quality. In Proceedings of the 2016 International Technical Meeting of The Institute of Navigation, Monterey, California, January 2016, pages 631–638. doi:10.33012/2016.13394. Search in Google Scholar

Siejka, Z. (2018). Validation of the accuracy and convergence time of Real Time Kinematic results using a single Galileo navigation system. Sensors, 18(8):2412, doi:10.3390/s18082412. Search in Google Scholar

Singleton, R. (1969). An algorithm for computing the mixed radix fast Fourier transform. IEEE Transactions on audio and electroacoustics, 17(2):93–103, doi:10.1109/TAU.1969.1162042. Search in Google Scholar

Špánik, P. and Hefty, J. (2017). Multipath detection with the combination of SNR measurements – example from urban environment. Geodesy and Cartography, 66(2), doi:10.1515/geocart-2017-0020. Search in Google Scholar

Strode, P. R. and Groves, P. D. (2016). GNSS multipath detection using three-frequency Signal-to-Noise measurements. GPS solutions, 20:399–412, doi:10.1007/s10291-015-0449-1. Search in Google Scholar

West, S. G., Finch, J. F., and Curran, P. J. (1995). Structural equation models with nonnormal variables: Problems and remedies. In Hoyle, R., editor, Structural equation modeling: Concepts, issues and applications, pages 56–75. Newbery Park, CA: Sage. Search in Google Scholar