about
A two-layer model of the ionosphere using Global Positioning System dataCombining ionosonde with ground GPS data for electron density estimationRevisit the calibration errors on experimental slant total electron content (TEC) determined with GPSA method for scintillation characterization using geodetic receivers operating at 1 HzFast Precise Point Positioning: A System to Provide Corrections for Single and Multi-frequency NavigationIonospheric and plasmaspheric electron contents inferred from radio occultations and global ionospheric mapsA Worldwide Ionospheric Model for Fast Precise Point PositioningAccuracy of ionospheric models used in GNSS and SBAS: methodology and analysisTwo-component model of topside ionosphere electron density profiles retrieved from Global Navigation Satellite Systems radio occultationsImprovement of the Ionospheric Radio Occultation Retrievals by means of Accurate Global Ionospheric MapsThe Impacts of the Ionospheric Observable and Mathematical Model on the Global Ionosphere ModelAATR an ionospheric activity indicator specifically based on GNSS measurementsCorrection Notice to: Feasibility of precise navigation in high and low latitude regions under scintillation conditionsFeasibility of precise navigation in high and low latitude regions under scintillation conditionsGPS differential code biases determination: methodology and analysisFast Precise Point Positioning: A System to Provide Corrections for Single and Multi-Frequency NavigationIonosphere/plasmasphere sounding with ground and space-based GNSS observationsWide-Area, Carrier-Phase Ambiguity Resolution Using a Tomographic Model of the IonosphereWide Area RTK: A satellite navigation system based on precise real-time ionospheric modellingEnhanced Precise Point Positioning for GNSS UsersGNSS measurement of EUV photons flux rate during strong and mid solar flaresIntegrity Monitoring for Carrier Phase AmbiguitiesPlasmaspheric Electron Content contribution inferred from ground and radio occultation derived Total Electron ContentPropagation of medium scale traveling ionospheric disturbances at different latitudes and solar cycle conditionsToward a SIRGAS Service for Mapping the Ionosphere’s Electron Density DistributionImprovement of retrieved FORMOSAT-3/COSMIC electron densities validated by ionospheric sounder measurements at JicamarcaGlobal prediction of the vertical total electron content of the ionosphere based on GPS dataGround- and space-based GPS data ingestion into the NeQuick modelThe ionosphere: effects, GPS modeling and the benefits for space geodetic techniquesGNSS data management and processing with the GPSTkImproving the Abel transform inversion using bending angles from FORMOSAT-3/COSMICNetwork-based high accuracy positioning with the GPSTkObtaining more accurate electron density profiles from bending angle with GPS occultation data: FORMOSAT-3/COSMIC constellationThe IGS VTEC maps: a reliable source of ionospheric information since 1998Comment on “A method for detecting ionospheric disturbances and estimating their propagation speed and direction using a large GPS network” by James L. Garrison et alCorrection to “Second-order ionospheric term in GPS: Implementation and impact on geodetic estimates”Solar flare detection system based on global positioning system data: First resultsSecond-order ionospheric term in GPS: Implementation and impact on geodetic estimatesMedium-scale traveling ionospheric disturbances affecting GPS measurements: Spatial and temporal analysisImprovement of global ionospheric VTEC maps by using kriging interpolation technique
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description
Spaans onderzoeker
@nl
forsker
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researcher, ORCID id # 0000-0001-8880-7084
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name
J. Sanz
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J. Sanz
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J. Sanz
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Jaume Sanz
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Jaume Sanz
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Jaume Sanz
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type
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J. Sanz
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J. Sanz
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J. Sanz
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Jaume Sanz
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Jaume Sanz
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Jaume Sanz
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J. Sanz
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J. Sanz
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J. Sanz
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J. Sanz
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Jaume Sanz
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Jaume Sanz
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Jaume Sanz
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0000-0001-8880-7084
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