Validating the impact of various ionosphere correction on mid to long baselines and point positioning using GPS dual-frequency receivers
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Alaa A. Elghazouly
,
Mohamed I. Doma
Abstract
Due to the ionosphere delay, which has become the dominant GPS error source, it is crucial to remove the ionospheric effect before estimating point coordinates. Therefore, different agencies started to generate daily Global Ionosphere Maps (GIMs); the Vertical Total Electron Content (VTEC) values represented in GIMs produced by several providers can be used to remove the ionosphere error from observations.
In this research, an analysis will be carried with three sources for VTEC maps produced by the Center for Orbit Determination in Europe (CODE), Regional TEC Mapping (RTM), and the International Reference Ionosphere (IRI). The evaluation is focused on the effects of a specific ionosphere GIM correction on the precise point positioning (PPP) solutions. Two networks were considered. The first network consists of seven Global Navigation Satellite Systems (GNSS) receivers from (IGS) global stations. The selected test days are six days, three of them quiet, and three other days are stormy to check the influence of geomagnetic storms on relative kinematic positioning solutions. The second network is a regional network in Egypt.
The results show that the calculated coordinates using the three VTEC map sources are far from each other on stormy days rather than on quiet days. Also, the standard deviation values are large on stormy days compared to those on quiet days. Using CODE and RTM IONEX file produces the most precise coordinates after that the values of IRI. The elimination of ionospheric biases over the estimated lengths of many baselines up to 1000 km has resulted in positive findings, which show the feasibility of the suggested assessment procedure.
References
[1] Abd Rabbou, M., and, El-Rabbany, A., 2017, “Performance analysis of precise point positioning using multi-constellation GNSS: GPS, GLONASS, Galileo and BeiDou”, Survey Review, 49(352), pp. 39–50. doi: 10.1080/00396265.2015.1108068.Suche in Google Scholar
[2] Banville, S., Collins, P., Zhang, W., and, Langley, R., 2014, “Global and regional ionospheric corrections for faster PPP convergence”, J Navigation, Journal of the Institute of Navigation, 61(2), 115–124.10.1002/navi.57Suche in Google Scholar
[3] Elghazouly, A., Doma, M., Sedeek, A., Rabah, M., and, Hamama, M., 2019a, “Validation of global TEC mapping model based on spherical harmonic expansion towards TEC mapping over Egypt from a regional GPS network”, American Journal of Geographic Information System, 8(2), 89–95. doi: 10.5923/j.ajgis.20190802.04.Suche in Google Scholar
[4] Elghazouly A., Doma M., and, Sedeek, A., 2019b, “Estimating satellite and receiver differential code bias using a relative Global Positioning System network”, Ann Geophys, 37, 1039–1047. doi: 10.5194/angeo-37-1039-2019.Suche in Google Scholar
[5] Elsayed A., Sedeek A., Doma M., and, Rabah M., 2018, “Vertical ionospheric delay estimation for single-receiver operation”, J Appl Geodesy, doi: 10.1515/jag-2018-0041.Suche in Google Scholar
[6] Feltens, J., 2003, “The International GPS Service (IGS) ionosphere working group”, Advances in Space Research 31(3), 635–644.10.1016/S0273-1177(03)00029-2Suche in Google Scholar
[7] Krypiak-Gregorczyk, A., Wielgosz, P., and, Borkowski, A., 2017, “Ionosphere model for European region based on multi-GNSS data and TPS interpolation”, Remote Sens., 9, 1221. doi:10.3390/rs9121221.Suche in Google Scholar
[8] Leick, A., Rapoport, L., and, Tatarnikov, D., 2015, “GPS Satellite Surveying”, 4th ed., Wiley, New York.10.1002/9781119018612Suche in Google Scholar
[9] NOAA (National Oceanic and Atmospheric Administration), website: https://www.swpc.noaa.gov, last visit Jan 2019.Suche in Google Scholar
[10] Saleh, M., and, Becker, M., 2014, “A new velocity field from the analysis of the Egyptian Permanent GPS Network (EPGN)”, Arabian Journal of Geosciences, 7(11), 4665–4682.10.1007/s12517-013-1132-xSuche in Google Scholar
[11] Sanz, J., Juan, J., and, Herna’ndez-Pajares, M., 2013, “GNSS Data processing, vol. I: fundamentals and algorithms”, Noordwijk, the Netherlands. ESA Commun. ESTEC TM-23/1.Suche in Google Scholar
[12] Schaer, S., 1999, “Mapping and Predicting the Earth’s Ionosphere Using the Global Positioning System”, PhD thesis, University of Bern. Bern.Suche in Google Scholar
[13] Sedeek, A., 2020, “Ionosphere delay remote sensing during geomagnetic storms over Egypt using GPS phase observations”, J Arabian Journal of Geosciences, 13(16), 1–15.10.1007/s12517-020-05817-6Suche in Google Scholar
[14] Sedeek, A., 2021, “Low-cost positioning performance using remotely sensed ionosphere”, The Egyptian Journal of Remote Sensing and Space Science. doi: 10.1016/J.EJRS.2021.07.004.Suche in Google Scholar
[15] Shi, C., Gu, S., Lou, Y., and, Ge, M., 2012, “An improved approach to model ionospheric delays for single-frequency Precise Point Positioning”, Advances in Space Research, 49, 1698–1708.10.1016/j.asr.2012.03.016Suche in Google Scholar
[16] Su, K., Jin, S., and, Hoque, M., 2019, “Evaluation of ionospheric delay effects on multi-GNSS positioning performance”, J Remote Sensing, 11(2), 171.10.3390/rs11020171Suche in Google Scholar
[17] Veettil, S., Aquino, M., Marques, H., and, Moraes, A., 2020, “Mitigation of ionospheric scintillation effects on GNSS precise point positioning (PPP) at low latitudes”, J Journal of Geodesy, 94(2), 1–10.10.1007/s00190-020-01345-zSuche in Google Scholar
© 2022 Walter de Gruyter GmbH, Berlin/Boston
Artikel in diesem Heft
- Frontmatter
- Research Articles
- Validating the impact of various ionosphere correction on mid to long baselines and point positioning using GPS dual-frequency receivers
- Target-based terrestrial laser scan registration extended by target orientation
- Linear discontinuous ground deformation detection based on coherence analysis of pre and post event radar image pairs
- GNSS time and frequency transfers through national positioning, navigation and timing infrastructure
- Recent GPS-based long wavelength crustal deformation revealed active postseismic deformation due to the 2006 Yogyakarta earthquake
- Effect of PCV and attitude on the precise orbit determination of Jason-3 satellite
- Geometric quality control for bio-based building elements: Study case segmented experimental shell
Artikel in diesem Heft
- Frontmatter
- Research Articles
- Validating the impact of various ionosphere correction on mid to long baselines and point positioning using GPS dual-frequency receivers
- Target-based terrestrial laser scan registration extended by target orientation
- Linear discontinuous ground deformation detection based on coherence analysis of pre and post event radar image pairs
- GNSS time and frequency transfers through national positioning, navigation and timing infrastructure
- Recent GPS-based long wavelength crustal deformation revealed active postseismic deformation due to the 2006 Yogyakarta earthquake
- Effect of PCV and attitude on the precise orbit determination of Jason-3 satellite
- Geometric quality control for bio-based building elements: Study case segmented experimental shell
