Galileo Single Frequency Ionospheric Correction: Performances in Terms of Position

Bidaine, Benoît; Lonchay, Matthieu; Warnant, René

doi:10.1007/s10291-012-0261-0

Download

Article (Scientific journals)

Galileo Single Frequency Ionospheric Correction: Performances in Terms of Position

Bidaine, Benoît; Lonchay, Matthieu; Warnant, René

2013 • In GPS Solutions, 17 (1), p. 63-73

Peer Reviewed verified by ORBi

Permalink
https://hdl.handle.net/2268/117284

DOI
10.1007/s10291-012-0261-0

Files (1)Send to Details Statistics Bibliography Similar publications

Files

Full Text

Bidaine_2011_GalileoSFICPerfPos_GPSSol.pdf

Author postprint (309.53 kB)

Download

The final publication is available at www.springerlink.com.

All documents in ORBi are protected by a user license.

Send to

RIS BibTex APA Chicago Permalink X Linkedin

Details

Keywords :

Galileo; positioning; ionospheric correction; single frequency; NeQuick model; data ingestion; Géodésie et GNSS

Abstract :

[en] For GPS single frequency users, the ionospheric contribution to the error budget is estimated by the well-known Klobuchar algorithm. For Galileo, it will be mitigated by a global algorithm based on the NeQuick model. This algorithm relies on the adaptation of the model to slant Total Electron Content (sTEC) measurements. Although the performance specifications of these algorithms are expressed in terms of delay and TEC, the users might be more interested in their impact on positioning. Therefore, we assessed the ability of the algorithms to improve the positioning accuracy using globally distributed permanent stations for the year 2002 marked by a high level of solar activity. We present uncorrected and corrected performances, interpret these and identify potential causes for Galileo correction discrepancies. We show vertical errors dropping by 56–64 % due to the analyzed ionospheric corrections, but horizontal errors decreasing by 27 % at most. By means of a fictitious symmetric satellite distribution, we highlight the role of TEC gradients in residual errors. We describe mechanisms permitted by the Galileo correction, which combine sTEC adaptation and topside mismodeling, and limit the horizontal accuracy. Hence, we support further investigation of potential alternative ionospheric corrections. We also provide an interesting insight into the ionospheric effects possibly experienced during the next solar maximum coinciding with Galileo Initial Operation Capability.

Disciplines :

Earth sciences & physical geography
Electrical & electronics engineering

Author, co-author :

Bidaine, Benoît ; Université de Liège - ULiège / FNRS > Département de géographie - Department of Geography > Unité de Géomatique - Geomatics Unit

Lonchay, Matthieu ; Université de Liège - ULiège / FNRS > Département de géographie - Department of Geography > Unité de Géomatique - Geomatics Unit

Warnant, René ; Université de Liège - ULiège > Département de géographie > Unité de Géomatique - Géodésie et GNSS

Language :

English

Title :

Galileo Single Frequency Ionospheric Correction: Performances in Terms of Position

Publication date :

01 January 2013

Journal title :

GPS Solutions

ISSN :

1080-5370

eISSN :

1521-1886

Publisher :

Springer, Heidelberg, Germany

Volume :

Issue :

Pages :

63-73

Peer reviewed :

Peer Reviewed verified by ORBi

Available on ORBi :

since 21 April 2012

Statistics

Number of views

396 (27 by ULiège)

Number of downloads

827 (10 by ULiège)

More statistics

Scopus citations^®

Scopus citations^®
without self-citations

OpenCitations

Bibliography

Allain D, Mitchell C (2009) Ionospheric delay corrections for single-frequency GPS receivers over Europe using tomographic mapping. GPS Solut 13(2): 141-151. doi: 10. 1007/s10291-008-0107-y.
Bidaine B, Warnant R (2009) Measuring total electron content with GNSS: investigation of two different techniques. In: 11th International conference on ionospheric radio systems and techniques (IRST 2009), Edinburgh (UK), April 28th to May 1st, 2009. Institution of Engineering and Technology-IET, London, pp 201-206. doi: 10. 1049/cp. 2009. 0063.
Bidaine B, Warnant R (2010) Assessment of the NeQuick model at mid-latitudes using GNSS TEC and ionosonde data. Adv Space Res 45(9): 1122-1128. doi: 10. 1016/j. asr. 2009. 10. 010.
Bidaine B, Warnant R (2011) Ionosphere modelling for Galileo single frequency users: illustration of the combination of the NeQuick model and GNSS data ingestion. Adv Space Res 47(2): 312-322. doi: 10. 1016/j. asr. 2010. 09. 001.
Bruyninx C (2004) The EUREF permanent network: a multi-disciplinary network serving surveyors as well as scientists. GeoInformatics 7: 32-35.
Coisson P, Radicella SM, Leitinger R, Nava B (2006) Topside electron density in IRI and NeQuick: features and limitations. Adv Space Res 37(5): 937-942. doi: 10. 1016/j. asr. 2005. 09. 015.
Conte J, Azpilicueta F, Brunini C (2011) Accuracy assessment of the GPS-TEC calibration constants by means of a simulation technique. J Geodesy 1-8. doi: 10. 1007/s00190-011-0477-8.
Dow JM, Neilan RE, Rizos C (2009) The international GNSS service in a changing landscape of Global Navigation Satellite Systems. J Geodesy 83(3-4): 191-198. doi: 10. 1007/s00190-008-0300-3.
Hernandez-Pajares M, Juan JM, Sanz J, Ramos-Bosch P, Rovira-Garcia A, Salazar D, Ventura-Traveset J, Lopez-Echazarreta C, Hein G (2010) The ESA/UPC GNSS-Lab tool (gLAB): an advanced multipurpose package to process and analyse GNSS data. In: 5th ESA workshop on satellite navigation user, Noordwijk (The Netherlands), December 8th to 10th, 2010.
Hernández-Pajares M, Juan JM, Sanz J, Orus R, Garcia-Rigo A, Feltens J, Komjathy A, Schaer SC, Krankowski A (2009) The IGS VTEC maps: a reliable source of ionospheric information since 1998. J Geodesy 83(3-4): 263-275. doi: 10. 1007/s00190-008-0266-1.
Hofmann-Wellenhof B, Lichtenegger H, Wasle E (2008) GNSS-global navigation satellite systems-GPS, GLONASS, Galileo, and more. Springer, Vienna. doi: 10. 1007/978-3-211-73017-1.
Klobuchar JA (1987) Ionospheric time-delay algorithm for single-frequency GPS users. IEEE Trans Aero Electron Syst AES-23 (3): 325-331. doi: 10. 1109/TAES. 1987. 310829.
Leitinger R, Zhang ML, Radicella SM (2005) An improved bottomside for the ionospheric electron density, model NeQuick. Ann Geophys-Italy 48(3): 525-534.
Mohino E (2008) Understanding the role of the ionospheric delay in single-point single-epoch GPS coordinates. J Geodesy 82(1): 31-45. doi: 10. 1007/s00190-007-0155-z.
Nava B, Radicella SM, Leitinger R, Coisson P (2006) A near-real-time model-assisted ionosphere electron density retrieval method. Radio Sci 41(6): RS6S16. doi: 10. 1029/2005rs003386.
Nava B, Coisson P, Radicella SM (2008) A new version of the NeQuick ionosphere electron density model. J Atmos Sol-Terr Phys 70(15): 1856-1862. doi: 10. 1016/j. jastp. 2008. 01. 015.
Orus R, Arbesser-Rastburg B, Prieto-Cerdeira R, Hernandez-Pajares M, Juan JM, Sanz J (2007a) Performance of different ionospheric models for single frequency navigation receivers. Paper presented at the 2007 Beacon Satellite Symposium, Boston.
Orus R, Cander LR, Hernandez-Pajares M (2007b) Testing regional vertical total electron content maps over Europe during the 17-21 January 2005 sudden space weather event. Radio Sci 42(3): RS3004. doi: 10. 1029/2006rs003515.
Prieto-Cerdeira R, Orus R, Arbesser-Rastburg B (2006) Assessment of the ionospheric correction algorithm for GALILEO single frequency receivers. In: 3rd ESA workshop on satellite navigation user equipment technologies NAVITEC 2006, Noordwijk, The Netherlands, December 11th to 13th, 2006.
Radicella SM, Leitinger R (2001) The evolution of the DGR approach to model electron density profiles. Adv Space Res 27(1): 35-40. doi: 10. 1016/S0273-1177(00)00138-1.
Rawer K (1963) Propagation of decameter waves (HF-Band). In: Landmark B (ed) Meteorological and astronomical influences on radio wave propagation, vol 11. Academic Press, New York, pp 221-250.
Snay RA, Soler T (2008) Continuously operating reference station (CORS): history, applications, and future enhancements. J Surv Eng-ASCE 134(4): 95-104. doi: 10. 1061/(Asce)0733-9453(2008)134: 4(95).
Spits J, Warnant R (2011) Total electron content monitoring using triple frequency GNSS: results with Giove-A/-B data. Adv Space Res 47(2): 296-303. doi: 10. 1016/j. asr. 2010. 08. 027.
Stankov SM, Marinov P, Kutiev I (2007) Comparison of NeQuick, PIM, and TSM model results for the topside ionospheric plasma scale and transition heights. Adv Space Res 39(5): 767-773. doi: 10. 1016/j. asr. 2006. 10. 023.
Warnant R, Pottiaux E (2000) The increase of the ionospheric activity as measured by GPS. Earth Planets Space 52(11): 1055-1060.