BEGIN:VCALENDAR
VERSION:2.0
PRODID:-//International GNSS Service - ECPv6.15.20//NONSGML v1.0//EN
CALSCALE:GREGORIAN
METHOD:PUBLISH
X-ORIGINAL-URL:https://igs.org
X-WR-CALDESC:Events for International GNSS Service
REFRESH-INTERVAL;VALUE=DURATION:PT1H
X-Robots-Tag:noindex
X-PUBLISHED-TTL:PT1H
BEGIN:VTIMEZONE
TZID:UTC
BEGIN:STANDARD
TZOFFSETFROM:+0000
TZOFFSETTO:+0000
TZNAME:UTC
DTSTART:20170101T000000
END:STANDARD
END:VTIMEZONE
BEGIN:VEVENT
DTSTART;VALUE=DATE:20181029
DTEND;VALUE=DATE:20181103
DTSTAMP:20260502T044132
CREATED:20181029T000000Z
LAST-MODIFIED:20210907T185007Z
UID:25871-1540771200-1541203199@igs.org
SUMMARY:IGS Workshop 2018
DESCRIPTION:[vc_row][vc_column][vc_column_text] \nIGS Workshop 2018\nDates and Location \n29 October to 2 November\, 2018 in Wuhan\, China \n  \nVenue \nThe Local Organizing Committee (LOC) has announced that the Workshop will take place at: \nEast Lake (Donghu) International Conference Center\nWuchang District\nWuhan 430000\nChina[/vc_column_text][vc_tta_tabs][vc_tta_section title=”Plenaries” tab_id=”plenaries”]Plenaries\n  \nPY01 – Analysis Centers and Reference Frames – Thomas Herring\, Paul Rebischung\, Michael Moore\n\n\n\n \n\n\n\nOverview of workshop\, performance of IGS products\, upcoming reprocessing effort\, potential models\n\nM. Moore\n\n\n\nNew ambiguity-fixed IGS clock analysis products at CODE\n\nS. Shaer\n\n\n\nGalileo un-differenced “integer” products\n\nF. Perosanz\n\n\n\nAperiodic surface mass transport observed in GRACE and GNSS time series\n\nP. Rebischung\n\n\n\nInvestigation of draconitic errors in IGS second reprocessed products at WHU\n\nC. Shi\n\n\n\nImpact of data break on the uncertainty of GNSS site velocity estimate\n\nL. Wang\n\n\n\n  \n\n  \n\nPY02 – Orbit Modeling – Rolf Dach\, Tim Springer\n\n\n\n \n\n\n\nOrbit determination and solar radiation pressure analysis of BDS satellite\n\nQ. Chen\n\n\n\nOptimized Strategies for Precise Orbit Determination of Low Earth Orbiters Based on BDS\n\nQ. Zhang\n\n\n\nInitial Orbit Determination of Third-Generation BeiDou MEO Spacecraft\n\nF. Dilssner\n\n\n\nPrecise orbit determination of QZSS satellites with high-fidelity non-gravitational disturbance model\n\nS. Ikari\n\n\n\nValidation of boxwing models for GNSS satellites\n\nS. McNair\n\n\n\nImproved Precise Orbit Determination by modelling of highly accurate clocks\n\nI. Selmke\n\n\n\n  \n\n  \n\nPY03 – Troposphere – Rosa Pacione\, Sharyl Byram\n\n\n\n \n\n\n\nMulti-GNSS Activities for Atmosphere Sounding at GFZ\n\nG. Dick\n\n\n\nImpact of second-order ionospheric delays on troposphere ZWD estimation with GPS and BeiDou measurements\n\nS. Zhang\n\n\n\nGCOS Reference Upper Air Network (GRUAN) GNSS Precipitable Water Product\n\nJ. Wang\n\n\n\nOn the estimation and use of GNSS tropospheric gradients for meteorological applications\n\nM. Kačmařík\n\n\n\nTropospheric path delays derived from very high-resolution GNSS-based troposphere models and spaceborne SAR interferometry\n\nK. Wilgan\n\n\n\nGPS Water Vapor Data to Improve Water Vapor Retrieval from MERSI/FY-3B Remote Sensing Satellite\n\nZ. Liu\n\n\n\n  \n\n  \n\nPY04 – Infrastructure Committee\, RINEX\, Data Centers – Nacho Romero\, Ken Macleod\, Carey Noll\n\n\n\n \n\n\n\nIGS Infrastructure Status and Challenges\n\nI. Romero\n\n\n\nChallenges and Opportunities of GNSS Reference Station Network\n\n. Jiang\n\n\n\nGNSS Science Service Centre (GSSC)\n\nL. Garcia\n\n\n\nImproving the efficiency of GNSS data streaming within the IGS\n\nR. Ruddick\n\n\n\nUpdates to the CSRS-PPP online service\n\nS. Banville\n\n\n\n  \n\n  \n\nPY05 – Timing and Biases – Stefan Schaer\, Michael Coleman\n\n\n\n \n\n\n\nPhase Biases of GPS L1/L2/L5 for the Purpose of Zero-difference Ambiguity Resolution and Initial Results on Galileo E1/E5a\n\nB. Duan\n\n\n\nPhase bias product in the bias-SINEX format and open-source software for undifferenced ambiguity resolution at Wuhan University\n\nJ. Geng\n\n\n\nEstimating a set of IFCBs to make IGS ionospheric-free clock product compatible with various triple-frequency PPP models\n\nL. Pan\n\n\n\nWhat to do about Flex Power\n\nY. Bar-Sever\n\n\n\nQuantifying the pilot-data bias on all current GNSS signals and satellites\n\nJ. Sleewaegen\n\n\n\n  \n\n  \n\nPY06 – MGEX and IGMA – Oliver Montenbruck\, Urs Hugentobler\n\n\n\n \n\n\n\nIntroduction by session chairs\n\nO. Montenbruck\n\n\n\nToward a Multi-Constellation combination : Improving the IGS orbits & clocks combination software for MGEX products\n\nP. Sakic\n\n\n\nTowards instantaneous PPP initialization in case of triple-frequency multi-GNSS data\n\nJ. Guo\n\n\n\nMulti-frequency and multi-GNSS processing with the raw observation approach\n\nS. Strasser\n\n\n\nSignal-in-space Accuracy Analysis for BDS in 2016-2017\n\nB. Wang\n\n\n\nProgress on the ICG IGMA Task Force activities and joint Trial Project with IGS\n\nS. Song\n\n\n\n  \n\n  \n\nPY07 – Antennas – Arturo Villiger\, Florian Dilssner\n\n\n\n \n\n\n\nIntroduction by session chairs\n\nA. Villiger\n\n\n\nField Absolute Calibration of the BDS Receiver Antenna at Wuhan\n\nZ. Hu\n\n\n\nMulti-GNSS Absolute Antenna Field Calibration with a Robot at ETH Zurich\n\nD. Willi\n\n\n\nEstimation of antenna phase center offset for BDS IGSO and MEO satellites\n\nX. Yan\n\n\n\nConsistency antenna products in the MGEX environment\n\nA. Villiger\n\n\n\n  \n\n  \n\nPY08 – Ionosphere – Andrzej Krankowski\n\n\n\n \n\n\n\nHigh-precision and high-resolution VTEC maps based on B-spline expansions and GNSS data\n\nM. Schmidt\n\n\n\nCAS Ionosphere Associate Analysis Center: Status report\n\nZ. Li\n\n\n\nImpact of strong space weather conditions on GNSS-based navigation\n\nG. Olivares\n\n\n\nIonospheric research and service based on near real time GNSS data\n\nJ. Berdermann\n\n\n\nClimate VTEC maps in cooperation of IGS’ GNSS and GIRO sensor networks as a step towards VTEC assimilation into IRI\n\nA. Froń\n\n\n\nRegional Ionospheric Irregularities Mapping at Different Temporal Scales Using GNSS Networks and Its Applications\n\nS. Song\n\n\n\n  \n\n  \n\nPY09 – Real-Time – Axel Ruelke\, Qile Zhao\n\n\n\n \n\n\n\nRecent Developments of DLR’s Real-Time Clock Estimation (RETICLE) Engine\n\nA. Hauschild\n\n\n\nPrecise point positioning of surveying vessel in the Baltic Sea\n\nW. Söhne\n\n\n\nBenefits of IGS RTS for real time ionospheric space weather monitoring\n\nN. Wang\n\n\n\nThe impact of higher order ionospheric corrections on ultra-rapid orbit determination\n\nX. Chen\n\n\n\nFUSING: a distributed software platform for real-time high precision multi-GNSS service\n\nS. Gu\n\n\n\nReal-time orbit and clock products at Wuhan University to support Multi-GNSS application\n\nJ. Guo\n\n\n\n  \n\n  \n\nPY10 – Science Applications – Jianghui Geng\, Fred Blume\n\n\n\n \n\n\n\nCrustal deformation in the Kunlun Fault region from long-term GPS measurements\n\nG. Zheng\n\n\n\nReal-time coseismic fault model estimation based on RTK-GNSS analysis in Japan\n\nS. Kawamoto\n\n\n\nThe Effect of Colored Noise on Automatic Offset Detection in GNSS Time Series\n\nR. Fernandes\n\n\n\nGNSS-Reflectometry for Earth Observation: History\, Results and Prospects\n\nJ. Wickert\n\n\n\nObserving geocenter motion from LEO POD using onboard GPS tracking data\n\nD. Kuang\n\n\n\nRetrieving and Validating Precipitable Water Vapor from Shipborne GNSS Observation using Ground-based and Space-borne Data\n\nM. Ge\n\n\n\n\n\n\n\n\n\n\n\n\n[/vc_tta_section][vc_tta_section title=”Posters” tab_id=”posters”]Posters\n  \nPS01 – Analysis Centers\n\n\n\n \n\n\n\nNew developments at GOP Analysis Center\n\nJ. Dousa\n\n\n\nBetween-satellite single-difference integer ambiguity resolution in the SPODS software\n\nR. Ruan\n\n\n\nCNES/CLS IGS Analysis center: recent activities\n\nS. Loyer\n\n\n\nPrecise satellite clock estimation for GPS\, GLONASS\, BeiDou and Galileo using the Australian Analysis Centre Software\n\nT. Li\n\n\n\nThe ESA/ESOC Analysis Centre progress and improvements\n\nT. Springer\n\n\n\nActivities at the CODE Analysis Center\n\nR. Dach\n\n\n\n  \n\n  \n\nPS02 – Reference Frame\n\n\n\n \n\n\n\nStatus of IGS14 reprocessing at the JPL IGS Analysis Center\n\nP. Ries\n\n\n\nLeast Squares Cubic Splines for the Polar Motion Estimations\n\nP. Li\n\n\n\nConverted Total Least Squares method and Gauss-Helmert model with applications to 3-D coordinate transformations of ITRF series\n\nJ. Cai\n\n\n\n  \n\n  \n\nPS03 – Orbit Modeling\n\n\n\n \n\n\n\nImpact of solar radiation pressure mis-modelling on GNSS satellite orbit determination\n\nT. Tseng\n\n\n\nImpact of empirical parameters on GNSS orbit prediction through numerical integration\n\nT. Papanikolaou\n\n\n\nThe Adjusted Optical Properties of GNSS Satellites and Applications in Precise Orbit Determination and Prediction\n\nB. Duan\n\n\n\nImproving precise orbit and clock determination for BeiDou-3\, Galileo and QZSS with satellite metadata\n\nY. Yuan\n\n\n\nPrecise orbit and clock determination using zero-differenced ambiguity resolution for GPS\, Galileo\, BDS and GLONASS\n\nJ. Wu\n\n\n\nThe impact of atmospheric and hydrological surface loading corrections on GNSS orbits\n\nB. Männel\n\n\n\nA multi-year reanalysis of GPS Block II/IIA and IIF satellite yaw maneuvers by means of reverse kinematic point positioning tech\n\nA. Sibois\n\n\n\nSolar Radiation Pressure Model Performance Test Using GNSS Precise Ephemeris\n\nS. Yoon\n\n\n\nAccuracy analysis of the observed GNSS ultra-rapid orbit and its correction\n\nC. Hu\n\n\n\nImproved orbit modelling of Galileo satellites during eclipse seasons\n\nD. Sidorov\n\n\n\nOrbit/Clock decorrelation approach for precise dynamic orbit determination\n\nJ. Chen\n\n\n\nOrbit improvement based on combined processing of GPS and LEO\n\nW. Huang\n\n\n\nContinuous Precise Ephemerides for Beidou GEO/IGSO Maneuvered Satellites\n\nJ. Qiao\n\n\n\n  \n\n  \n\nPS04 – Troposphere\n\n\n\n \n\n\n\nAtmospheric sounding with ground-based\, satellite-based and balloon-based GNSS for climate and meteorology study\n\nX. Wang\n\n\n\nComparison of zenith troposphere delay from different techniques\n\nV. Suvorkin\n\n\n\nIntegrating high-\, medium- and low-earth orbit navigation satellite constellations to retrieve atmospheric water vapor\n\nH. Tan\n\n\n\nAssimilation of GNSS zenith total delay in the weather research and forecasting model: a case study\n\nY. Zheng\n\n\n\nImpact of high-order ionospheric effects on estimated tropospheric parameters with GPS data\n\nZ. Zheng\n\n\n\nAnalysis and comparison of tropospheric scintillation prediction models at Ogun University\n\nP. Enuka\n\n\n\nTrends in the atmospheric water vapour estimated using different elevation-angle-dependent parameters in the GPS\n\nT. Ning\n\n\n\nGNSS-based precise troposphere zenith path delay determination with high temporal resolution\n\nZ. Kang\n\n\n\nGNSS+ Tropospheric Sounding for Weather and Climate – An Australian Perspective\n\nK. Zhang\n\n\n\n  \n\n  \n\nPS05 – Infrastructure Committee\, RINEX\, Data Centers\n\n\n\n \n\n\n\nNew way of GNSS data dissemination within the European Plate Observing System\n\nJ. Dousa\n\n\n\nREGINA a CNES/IGN worldwide GNSS receivers network for IGS and navigation\n\nL. Jolivet\n\n\n\nDiscovering the Geoscience Australia GNSS Data Repository\n\nR. Ruddick\n\n\n\nGFZ GNSS Infrastructure and the Global reference Station Network\n\nM. Ramatschi\n\n\n\nNASA CDDIS: Important Changes to User Access\n\nC. Noll\n\n\n\nEGON: The ESA/ESOC GNSS Observation station Network\n\nI. Romero\n\n\n\nStatus Quo of the new GFZ Operational Data Center\n\nM. Bradke\n\n\n\nFoundation CORS – The backbone of the U.S. National Spatial Reference System\n\nK. Choi\n\n\n\nSIRGAS: 25 years providing the geodetic infrastructure in Latin America\n\nL. Sanchez\n\n\n\n  \n\n  \n\nPS06 – Biases\n\n\n\n \n\n\n\nFY-3D and FY-3C Onboard Observations for DCB Estimation: BDS and GPS DCBs\n\nT. Ma\n\n\n\nFast estimation of real-time high-frequency precise satellite clock offset using multi-frequency and multi-constellation GNSS ob\n\nY. Xiong\n\n\n\nDifferential code bias estimation with ionosphere constrained by DESIGN\n\nY. Wang\n\n\n\nGLONASS phase bias products in the bias-SINEX format at Wuhan University: Differential code-phase bias\n\nY. Pan\n\n\n\nLong-term characteristics analysis and modeling of GPS/BDS inter-frequency clock bias\n\nX. Gong\n\n\n\nMulti-GNSS code bias handling: an observation-specific perspective\n\nN. Wang\n\n\n\nPrecise Common View Time and Frequency Transfer based on BDS GEO satellites\n\nX. Yang\n\n\n\n  \n\n  \n\nPS07 – Timing\n\n\n\n \n\n\n\nGalileo In-Orbit Satellite Clocks Performance and System Time Offset Assessment\n\nL. Zhu\n\n\n\nAnalysis on Prediction Characteristics of time offsets in GNSS\n\nC. Mengfei\n\n\n\nTiming performance evaluation of BDS-3 early constellation using receivers located in time laboratories\n\nB. Sun\n\n\n\nPerformance evaluation of GLONASS on-board atomic clock in long-term\n\nW. Xie\n\n\n\n  \n\n  \n\nPS08 – MGEX\n\n\n\n \n\n\n\nImproving Galileo orbit determination using zero-difference ambiguity fixing in a Multi-GNSS processing\n\nG. Katsigianni\n\n\n\nMulti-GNSS triple-frequency Differential Code Bias (DCB) determination with Precise Point Positioning (PPP)\n\nT. Liu\n\n\n\nHourly orbit and clock solutions for GPS\, GLONASS\, BeiDou\, and Galileo with analysis of added value\n\nA. Sibthorpe\n\n\n\nIntegrated precise orbit determination of FY-3C\, FY-3D\, BDS and GPS\n\nK. Zhang\n\n\n\nLEO constellation augmented multi-GNSS precise positioning: heterogeneous constellation design and frequency selection\n\nF. Ma\n\n\n\nFrequency Stability Analysis of BDS Satellite Clocks Under the Condition of Multi-satellite Orbit Determination\n\nY. Wang\n\n\n\nStatus of the TUM MGEX orbit and clock products\n\nI. Selmke\n\n\n\nGalileo real-time satellite clocks generation based on connection of short-arc observation files\n\nM. Wu\n\n\n\nThe Analysis of BDS2/BDS3 Combined Precise Orbit Determination Strategy\n\nY. Wang\n\n\n\nQZSS signal in space range error\, differential inter-system bias and inter-frequency clock bias analysis\n\nY. Zhang\n\n\n\nAn Assessment of the Accuracy of Broadcast Ephemerides for Multi-GNSS Positioning\n\nB. Stressler\n\n\n\nThe improvement of multi-GNSS orbit and clock at GFZ\n\nZ. Deng\n\n\n\nPPP rapid ambiguity resolution with LEO constellation augmented GNSS\n\nX. Li\n\n\n\nAn empirical SRP model for the orbit normal attitude mode\n\nL. Prange\n\n\n\n  \n\n  \n\nPS09 – IGMA\n\n\n\n \n\n\n\nA Preliminary Assessment on Continuity and Availability of Signal-In-Space for Multi-GNSS: From 2015 to 2016\n\nQ. Zhang\n\n\n\nGalileo SISRE analysis with Where\n\nM. Dähnn\n\n\n\nGMV’s Preliminary Results of its contribution to IGMA-IGS Joint Trial Project\n\nI. Rodriguez\n\n\n\nSão Paulo State University contribution to the IGMA Trial Project – PDOP and broadcast ephemeris accuracy assessment\n\nJ. Galera Monico\n\n\n\n  \n\n  \n\nPS10 – Antennas\n\n\n\n \n\n\n\nGroup Delay Variations of Galileo Satellite Antennas\n\nS. Beer\n\n\n\nestimating-satellite-antenna-calibration-in-a-multi-gnss-environment\n\nR. Dach\n\n\n\n6-axis robot for absolute antenna calibration at the US National Geodetic Survey\n\nA. Bilich\n\n\n\n  \n\n  \n\nPS11 – Ionosphere\n\n\n\n \n\n\n\nPOLarGIMs: Time evolution of vertical electron content distribution in polar ionosphere from UPC-GIM TOMION runs\n\nM. Hernández-Pajares\n\n\n\nModeling real-time global ionospheric TEC map based on the spare and uneven distributed multi-GNSS stations\n\nZ. Li\n\n\n\nRROT: a new ionosphere activity index for ionospheric irregularity monitoring\n\nN. Wang\n\n\n\nIonospheric observable: benefit from PPP and PPP-AR\n\nW. Nie\n\n\n\nA long-term ionospheric dynamics and fluctuations study in a local frame\n\nK. Kotulak\n\n\n\nThe IGS ROTI Map product: scientific applications and development\n\nL. Cherniak\n\n\n\nIonospheric scintillation monitoring with Bałdy LOFAR station\n\nL. Blaszkiewicz\n\n\n\nThe effect of solar storm to ionosphere and user’s position of BDS\n\nJ. Yi\n\n\n\nSurvey of solar flare signatures in the upper ionosphere with GNSS and GOES observations: a case study\n\nS. Blevins\n\n\n\nRegional Mean Electron Content: A new conception to track regional ionosphere activity\n\nC. Liu\n\n\n\nA hybrid of Abel inversion and Vary-Chap model to reconstruct RO electron density profile\n\nH. Lyu\n\n\n\nGNSS NavAer network for supporting Ionospheric Studies in Brazil\n\nJ. Galera Monico\n\n\n\nDevelopment and improvement of BDS single frequency ionospheric model\n\nL. Xu\n\n\n\nApplication of GNSS-based Ionosphere TEC Model in CE-4\n\nW. Zhou\n\n\n\nInfluence of Solar Activities on GNSS Broadcast Ionospheric Models in the Asia-Pacific region\n\nN. Cheng\n\n\n\nStudying Ionosphere Responses to a Geomagnetic Storm in June 2015 with Multi-Constellation Observations\n\nY. Liu\n\n\n\nIonosphere continuous monitoring based on BDS GEO satellites measurements\n\nK. Zhao\n\n\n\n\nPS12 – Real-Time\n\n\n\n \n\n\n\nPerformance Assessment of BDS Real-Time Precise Point Positioning Based on SSR Corrections\n\nY. Shi\n\n\n\nreal-time-gnss-data-quality-control\n\nP. Vaclavovic\n\n\n\nAssessing the ambiguity time convergence as function of constraints in the station coordinates and vice versa\n\nJ. Galera Monico\n\n\n\nResearch progress of multi-GNSS PPP-RTK technology\n\nJ. Huang\n\n\n\nLEO constellation augmented GPS RTK positioning for medium-to-long baselines\n\nH. Lv\n\n\n\nReal-time un-differenced precise positioning for Android smartphones\n\nL. Wang\n\n\n\nPrediction of IGS RTS Correction Data using Machine Learning Algorithms\n\nM. Kim\n\n\n\nProgress and improvements in real-time services at NASA GSFC CDDIS\n\nS. Blevins\n\n\n\nreal-time-implementation-of-instantaneous-ppp-convergence-using-the-e6-gali\n\nD. Laurichesse\n\n\n\nA real-time integrated GNSS/Accelerometer network and processing engine for earthquake early warning in Yunan\, China\n\nX. Shaoming\n\n\n\nTechnology of BDS Real-time Precise Orbit Determination Enhanced by LEOs\n\nW. Le\n\n\n\nA new method of integrating GPS and strong-motion data for real-time seismology\n\nR. Fang\n\n\n\nDevelopment of real time multi-GNSS precise positioning system at IGG\n\nY. Yuan\n\n\n\nInitial accuracy analysis of real-time products of multi-GNSS from Shanghai Astronomical Observatory AC of iGMAS\n\nQ. Chen\n\n\n\nLooking for optimal ways to combine global ionospheric maps in real-time\n\nM. Hernández-Pajares\n\n\n\n  \n\n  \n\nPS13 – Science Applications\n\n\n\n \n\n\n\nGCS (General Commission for Survey\, Riyadh\, KSA) Data & Analysis Centre – the results of processing the data from GNSS CORS netw\n\nL. Golubinka\n\n\n\nGNSS geodetic networks development in Mongolia and Its Application in Geodynamic Study\n\nE. Danzansan\n\n\n\nResearch on Extracting Common Mode Error in GPS Network using Principal Component Analysis\n\nJ. Wang\n\n\n\nOn the spatial correlation of colored noise in GPS position time series\n\nA. Santamaria-Gomez\n\n\n\nRobust fractal analysis and automatic singular points detection of IGS station coordinates time series\n\nQ. Zhang\n\n\n\nUndifferenced ambiguity resolution for GPS-based precise orbit determination of low Earth orbiters using the new CODE clock and\n\nD. Arnold\n\n\n\nA gravitational redshift test using eccentric Galileo satellites\n\nP. Delva\n\n\n\nVertical Displacements Driven by Groundwater Storage Changes in the North China Plain Detected by GPS Observations\n\nR. Liu\n\n\n\nThe Research on Common Mode Errors in GNSS Time Series Using Geographically Weighted Principal Component Analysis\n\nR. Zou\n\n\n\nGNSS Fog stations supporting Internet of Things applications: concepts\, framework and use case studies\n\nY. Feng\n\n\n\nHomogenized Ground-based GPS precipitable water products from 1999 to 2015 over China and evaluations of radiosondes and reanaly\n\nW. Zhang\n\n\n\nOnshore GNSS Used for Monitoring Tidal Variations\n\nQ. Liu\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n[/vc_tta_section][vc_tta_section title=”Recommendations” tab_id=”recommendations”]Recommendations\n\n\n\n \n\n\nAC and Reference Frame\n\n\nSpace Vehicle Orbit Dynamics Working Group\n\n\nTroposphere Working Group\n\n\nInfrastructure Committee\, RINEX\, Data Centers\n\n\nMGEX Working Group\n\n\nIGMA Working Group\n\n\nAntenna Working Group\n\n\nTIGA Working Group Recommendations\n\n\nIONO Working Group Recommendations\n\n\n\n[/vc_tta_section][vc_tta_section title=”Videos” tab_id=”videos”][vc_column_text] \nVideos\n[/vc_column_text][vc_raw_html]JTNDZGl2JTIwY2xhc3MlM0QlMjJ2aWRlb1dyYXBwZXIlMjIlM0UlMEElMjAlMjAlM0NpZnJhbWUlMjB3aWR0aCUzRCUyMjU2MCUyMiUyMGhlaWdodCUzRCUyMjM0OSUyMiUyMHNyYyUzRCUyMmh0dHBzJTNBJTJGJTJGd3d3LnlvdXR1YmUuY29tJTJGZW1iZWQlMkZ2aWRlb3NlcmllcyUzRmxpc3QlM0RQTDdteEZOLXdtLTZiOHdzcy1peGo4ZWozNmxzdkx6SFN0JTIyJTIwZnJhbWVib3JkZXIlM0QlMjIwJTIyJTIwYWxsb3dmdWxsc2NyZWVuJTNFJTNDJTJGaWZyYW1lJTNFJTBBJTNDJTJGZGl2JTNF[/vc_raw_html][/vc_tta_section][/vc_tta_tabs][/vc_column][/vc_row]
URL:https://igs.org/event/igs-workshop-2018/
LOCATION:East Lake (Donghu) International Conference Center\, Wuchang District\, Wuhan\, 430000\, China
CATEGORIES:IGS Workshops
ATTACH;FMTTYPE=image/png:https://igs.org/wp-content/uploads/2020/08/workshop2018-presents.png
ORGANIZER;CN="International GNSS Service":MAILTO:CB@igs.org
END:VEVENT
END:VCALENDAR