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dc.contributor.authorWang, Kan
dc.contributor.authorEl-Mowafy, Ahmed
dc.contributor.authorWang, W.
dc.contributor.authorYang, L.
dc.contributor.authorYang, X.
dc.date.accessioned2022-09-05T06:41:46Z
dc.date.available2022-09-05T06:41:46Z
dc.date.issued2022
dc.identifier.citationWang, K. and El-Mowafy, A. and Wang, W. and Yang, L. and Yang, X. 2022. Integrity Monitoring of PPP-RTK Positioning; Part II: LEO Augmentation. Remote Sensing. 14 (7): ARTN 1599.
dc.identifier.urihttp://hdl.handle.net/20.500.11937/89286
dc.identifier.doi10.3390/rs14071599
dc.description.abstract

Low Earth orbit (LEO) satellites benefit future ground-based positioning with their high number, strong signal strength and high speed. The rapid geometry change with the LEO augmentation offers acceleration of the convergence of the precision point positioning (PPP) solution. This contribution discusses the influences of the LEO augmentation on the precise point positioning—real-time kinematic (PPP-RTK) positioning and its integrity monitoring. Using 1 Hz simulated data around Beijing for global positioning system (GPS)/Galileo/Beidou navigation satellite system (BDS)-3 and the tested LEO constellation with 150 satellites on L1/L5, it was found that the convergence of the formal horizontal precision can be significantly shortened in the ambiguity-float case, especially for the single-constellation scenarios with low precision of the interpolated ionospheric delays. The LEO augmentation also improves the efficiency of the user ambiguity resolution and the formal horizontal precision with the ambiguities fixed. Using the integrity monitoring (IM) procedure introduced in the first part of this series of papers, the ambiguity-float horizontal protection levels (HPLs) are sharply reduced in various tested scenarios, with an improvement of more than 60% from 5 to 30 min after the processing start. The ambiguity-fixed HPLs can generally be improved by 10% to 60% with the LEO augmentation, depending on the global navigation satellite system (GNSS) constellations used and the precision of the ionospheric interpolation.

dc.languageEnglish
dc.publisherMDPI
dc.relation.sponsoredbyhttp://purl.org/au-research/grants/arc/DP190102444
dc.rights.urihttp://creativecommons.org/licenses/by/4.0/
dc.subjectScience & Technology
dc.subjectLife Sciences & Biomedicine
dc.subjectPhysical Sciences
dc.subjectTechnology
dc.subjectEnvironmental Sciences
dc.subjectGeosciences, Multidisciplinary
dc.subjectRemote Sensing
dc.subjectImaging Science & Photographic Technology
dc.subjectEnvironmental Sciences & Ecology
dc.subjectGeology
dc.subjectintegrity monitoring
dc.subjectPPP-RTK
dc.subjectLEO
dc.subjectGNSS
dc.subjectL5
dc.subjectSATELLITES
dc.subjectSERVICE
dc.titleIntegrity Monitoring of PPP-RTK Positioning; Part II: LEO Augmentation
dc.typeJournal Article
dcterms.source.volume14
dcterms.source.number7
dcterms.source.titleRemote Sensing
dc.date.updated2022-09-05T06:41:44Z
curtin.departmentSchool of Earth and Planetary Sciences (EPS)
curtin.accessStatusOpen access
curtin.facultyFaculty of Science and Engineering
curtin.contributor.orcidWang, Kan [0000-0001-5688-6937]
curtin.contributor.orcidEl-Mowafy, Ahmed [0000-0001-7060-4123]
curtin.contributor.researcheridWang, Kan [N-1713-2017]
curtin.identifier.article-numberARTN 1599
dcterms.source.eissn2072-4292
curtin.contributor.scopusauthoridWang, Kan [55621722900]
curtin.contributor.scopusauthoridEl-Mowafy, Ahmed [7004059531]


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