Geodetic Survey Division EARTH SCIENCES SECTOR Slide 1 Real-Time and Near Real-Time GPS Products and Services from Canada Y. Mireault, P. Tétreault, F.

Slides:

Advertisements

Similar presentations

The Geoscience Australia’s Online GPS Processing Service (AUSPOS)

Advertisements

GPS Theory and applications

Experimental Results from “BigAnt”, a Large Format Antenna for High Quality Geodetic Ground Stations Gerald Mader National Geodetic Survey (NGS) Silver.

2013 Western Australia Surveying Conference

Reference Frames for GPS Applications and Research

Moscow Aviation Institute (State University of Aerospace Technologies) Ambiguity Resolution of Phase Measurements in Precise Point Positioning working.

Earth Science Sector Characterization of high latitude GPS sensed ionospheric irregularities: Case studies Reza Ghoddousi-Fard¹, Paul Prikryl², Kjellmar.

June 12-14, 2013, Ottawa, Canada From dual- to triple-frequency PPP: method, problems and application in California Jianghui Geng, Yehuda Bock Scripps.

FIX_8 (High Accuracy Positioning using EGNOS and Galileo Products) Galileo SME Workshop 5 th & 6 th April 2006.

A quick GPS Primer (assumed knowledge on the course!) Observables Error sources Analysis approaches Ambiguities If only it were this easy…

Global Navigation Satellite Systems

Jan Kouba Geodetic Survey Div. NRCan Canada IGS Products and Applications.

Limits of static processing in a dynamic environment Matt King, Newcastle University, UK.

The 15th Workshop on JAXA Astrodynamics and Flight Mechanics, 2005

Space Weather influence on satellite based navigation and precise positioning R. Warnant, S. Lejeune, M. Bavier Royal Observatory of Belgium Avenue Circulaire,

GTECH 201 Session 08 GPS.

Real-Time Orbit And Clock Estimation Using PANDA Software Shi C, Lou YD, Zhao QL, Liu JN GNSS Research Center, Wuhan University, China IGS Analysis Center.

13/06/13 H. Rho Slide 1 Geodetic Research Laboratory Department of Geodesy and Geomatics Engineering University of New Brunswick Evaluation of Precise.

AUSPOS Online GPS Processing Service John Manning, John Dawson.Ramesh Govind Geoscience Australia.

AN INDUSTRY APPROACH TO PRECISE POINT POSITIONING GNSS PPP WORKSHOP D. Calle A. Mozo P. Navarro R. Píriz D. Rodríguez G. Tobías JUNE 13 TH, GNSS.

Part VI Precise Point Positioning Supported by Local Ionospheric Modeling GS894G.

Mr.Samniang Suttara B.Eng. (Civil), M.Eng. (Survey) Topcon Instruments (Thailand) Co.,Ltd. Tel Satellite Surveying.

NGS GPS ORBIT DETERMINATION Positioning America for the Future NATIONAL OCEANIC AND ATMOSPHERIC ADMINISTRATION National Ocean Service National Geodetic.

October 8, session 2REFAG2010 Paris1 Distributed processing systems for large geodetic solutions IAG WG “Comparison and combination of precise.

Titelmaster Geometrical and Kinematical Precise Orbit Determination of GOCE Akbar Shabanloui Institute of Geodesy and Geoinformation, University of Bonn.

Part Va Centimeter-Level Instantaneous Long-Range RTK: Methodology, Algorithms and Application GS894G.

Compatibility of Receiver Types for GLONASS Widelane Ambiguity Resolution Simon Banville, Paul Collins and François Lahaye Geodetic Survey Division, Natural.

Real-time IGS Network Management and Data Exchange Interfaces Georg Weber, BKG, Germany IGS Analysis Center Workshop, Miami Beach, Florida, 2-6 June 2008.

SVY 207: Lecture 13 Ambiguity Resolution

Case study for the IGS ultra-rapid orbit requirements Jan Douša Miami Beach, June 2-6, 2008.

GNSS PRECISE POINT POSITIONING WORKSHOP: REACHING FULL POTENTIAL WHAT ARE THE PUBLIC AND INDUSTRY ROLES IN CANADA? Ottawa, Canada – 14 June, 2013 Denis.

Geodetic Research Laboratory Department of Geodesy and Geomatics Engineering University of New Brunswick 01/06/27 S.Bisnath A NEW TECHNIQUE FOR GPS-BASED.

Fugro Chance Inc. Comparison of Network and State Space DGPS Services Real Time Tidal Monitoring for Seismic Data Collection Applications Richard Barker.

National Geodetic Survey – Continuously Operating Reference Stations & Online Positioning User Service (CORS & OPUS) William Stone Southwest Region (UT,

P. Alves and G. Lachapelle University of Calgary USM GPS Workshop Carrier Phase GPS Navigation for Hydrographic Surveys, and Seamless Vertical Datums March.

IGS Analysis Center Workshop, 4 June 2008 Recommendations from “RT/NRT user requirements” 1.E-GVAP recommends IGS to support PPP strategy with high quality.

A Geodesist’s View of the Ionosphere Gerald L. Mader National Geodetic Survey Silver Spring, MD.

Earth Sciences Sector SLIDE 1 NAREF & CBN Velocity Solutions for a New Version of SNARF Mike Craymer Joe Henton Mike Piraszewski 8th SNARF Workshop AGU.

Airborne GPS Positioning with cm-Level Precisions at Hundreds of km Ranges Gerald L. Mader National Geodetic Survey Silver Spring, MD National Geodetic.

RECENT ENHANCEMENTS TO THE CDDIS IGS Network Systems Workshop November 2-5, 1998 Annapolis, MD Carey E. Noll Manager, CDDIS NASA GSFC Greenbelt, MD.

Introduction to GPS/GNSS Introduction to Tidal and Geodetic Vertical Datums Corbin Training Center January 7, 2009 Jeff Little Guest Speaker ,

GPS: Everything you wanted to know, but were afraid to ask Andria Bilich National Geodetic Survey.

VTEC prediction using a recursive artificial neural networks approach in Brazil: initial results Engineer School - University of São Paulo Wagner Carrupt.

SP Swedish National Testing and Research Institute Real-Time GPS Processing with Carrier Phase FILTER PARAMETER INFLUENCE ON GPS CARRIER PHASE REAL-TIME.

PPP Workshop: Reaching Full Potential

Meeting the Needs of the IGS Real-Time PPP User Community

Global Positioning System Overview

Presented by: Technical contributions from: THE INTERNATIONAL ASSOCIATION OF GEODESY AND PRECISE POINT POSITIONING.

PENDING & PROPOSED MODEL CHANGES: SESSION RECOMMENDATIONS IGS core products AC modeling documentation Troposphere modeling Higher-order ionospheric corrections.

1 SVY 207: Lecture 12 Modes of GPS Positioning Aim of this lecture: –To review and compare methods of static positioning, and introduce methods for kinematic.

Earth Sciences Sector SLIDE 1 Some current GNSS activities at GSD GEOIDE Project #31 Workshop October 2006 P. Collins F. Lahaye K. MacLeod Y. Mireault.

View on GPS and Galileo ‘From across the Atlantic…’ Ruth E. Neilan International GNSS Service (IGS) Central Bureau Jet Propulsion Laboratory/California.

SHA: the GNSS Analysis Center at SHAO Junping Chen, Bin Wu, Xiaogong Hu Haojun Li, Xiao Pei, Yize Zhang Shanghai Astronomical Observatory (SHAO)

Real Time Stream Editor for PPP  Conventional approaches to Real Time Precise Point Position use ionosphere- free combination of code and phase observables.

Geodetic Applications of GNSS within the United States Dr. Gerald L. Mader National Geodetic Survey NOS/NOAA Silver Spring, Maryland USA Munich Satellite.

Real Time Stream Editor for PPP  Conventional approaches to Real Time Precise Point Position use ionosphere-free combination of code and phase observables.

On the Way to Full PPP Potential Pierre Héroux Geodetic Survey Division, Natural Resources Canada.

ESOC Navigation Support Office IGS Workshop 2008 Miami IGS Real Time Pilot Project: Analysis Centre Activities Loukis Agrotis 4 June 2008.

Redundancy in Dynamic Positioning (DP) Applications based on Satellite Navigation. High Precision Navigation and Positioning Conference,

IGS Workshop 2008, Miami Beach IGN activities as IGS data center The IGN Global Data Centre (GDC) has been designed and implemented in answer to both the.

Astronomisches Institut der Universität Bern Global Navigation Satellite Systems for Positioning and Time Transfer T. Schildknecht, A. Jäggi R. Dach, G.

The Global Positioning System Rebecca C. Smyth April 17 - May 2, 2001.

Limits of static processing in a dynamic environment Matt King, Newcastle University, UK.

Astronomical Institute University of Bern 1 Astronomical Institute, University of Bern, Switzerland * now at PosiTim, Germany 5th International GOCE User.

Limits of static processing in a dynamic environment Matt King, Newcastle University, UK.

Real-Time Working Group

Appliance of IceCORS network 2017 by Dalia Prizginiene

CNES Real-time Analysis center Status

WHY DOES THE IGS CARE ABOUT EOPs?

Agenda Background and Motivation

Presentation transcript:

Geodetic Survey Division EARTH SCIENCES SECTOR Slide 1 Real-Time and Near Real-Time GPS Products and Services from Canada Y. Mireault, P. Tétreault, F. Lahaye, P. Collins, M. Caissy Geodetic Survey Division, Natural Resources Canada (GSD/NRCan) IGS Analysis Center Workshop 2008 June 2-6, 2008 Miami Beach, Florida, USA

Geodetic Survey Division EARTH SCIENCES SECTOR Slide 2 Outline 1.NRCan Ultra Rapid Products (EMU) 2.CSRS Precise Point Positioning Service (CSRS-PPP) 3.Canadian RT GPS Tracking Network 4.Canadian High Precision RT GPS Wide-Area Correction Service (GPS·C) 5.Final Notes

Geodetic Survey Division EARTH SCIENCES SECTOR Slide 3 1. NRCan Ultra Rapid Products (EMU) Orbits and clocks for RT/NRT usage Covers 48h, i.e. 24h estimated and 24h predicted Produced every hour ~1h delay for orbits and ~1.5h delay for clocks Submission to IGS every 6h Predicted orbits used in GPS·C Estimated orbits and 30-sec satellite clocks used in NRT PPP 1.1 Description

Geodetic Survey Division EARTH SCIENCES SECTOR Slide Some Highlights DatesImportant Changes and Highlights 2000-Mar-20 1 st orbit Ultra Rapid 1 st orbit submission to IGS (3h cycle) 2002-Oct-31 1 st clock Ultra Rapid 1 st clock submission to IGS (3h cycle) 2006-Oct-31 5-min Estimating 5-min satellite clocks 2007-Jan-24 1h 1h cycle 2007-Oct sec Estimating 30-sec satellite clocks

Geodetic Survey Division EARTH SCIENCES SECTOR Slide Precision * NRCan Solutions (EMU) Orbits * (cm) Clocks * (ns) Estimated portion (24h) 3-4 a 0.15 a 3h prediction 5b5b 0.5 6h prediction 51 12h prediction 62 24h prediction 134 (*) Orbit and Clock Median RMS when compared to IGS Rapid (IGR) (a) Orbits and clocks are used in NRT PPP (b) Orbits are used in GPS·C

Geodetic Survey Division EARTH SCIENCES SECTOR Slide 6 2. CSRS Precise Point Positioning (PPP) A Web based global positioning service for single GNSS datasets (currently GPS only; GLONASS planned) Initiated in the Fall of 2003 as next-day service (17h delay) Delay reduced to 90min (May 2008) using NRCan Ultra Rapid orbits and 30sec clocks Process static or kinematic (both with single or dual frequency data) Use of IGS IONEX grids for single frequency processing 2.1 Description

Geodetic Survey Division EARTH SCIENCES SECTOR Slide CSRS-PPP Usage

Geodetic Survey Division EARTH SCIENCES SECTOR Slide Latitude Longitude Ellipsoidal height Mean Differences (cm) EMU (30sec) IGR (5min) IGS 5min IGS 30sec 2.3 CSRS-PPP Static Positioning Corrections (wrt IGS05) Statistics based on processing of 30 secs data from 24 hour files for ALGO DRAO RESO SASK STJO for GPS Week 1470

Geodetic Survey Division EARTH SCIENCES SECTOR Slide CSRS-PPP Kinematic Positioning Variations (wrt IGS05) LatitudeLongitudeEllipsoidal height Mean position variations (cm) EMU (30sec) IGR (5min) IGS 5min IGS 30sec Statistics based on processing of 30 secs data from 24 hour files for ALGO DRAO RESO SASK STJO for GPS Week 1470

Geodetic Survey Division EARTH SCIENCES SECTOR Slide Canadian RT GPS Tracking Network

Geodetic Survey Division EARTH SCIENCES SECTOR Slide GPS·C: Canadian High Precision RT GPS Wide-Area Correction Service Pseudorange & Phase Processing from IGS-RT + RT-CACS Stations · dtstadtsatdtrop –P3 =  (Xsta,Xsat) + c · ( dtsta – dtsat ) + dtrop +  · dtstadtsatdtropN –L3 =  (Xsta,Xsat) + c · ( dtsta – dtsat ) + dtrop + N +   Xsat provided by EMU (1h cycle) || IGU (6hr cycle) predictions  dtsta, dtsat,dtrop,N estimated in real-time Enhancement of the current code-based system 4.1 Description (1/2)

Geodetic Survey Division EARTH SCIENCES SECTOR Slide Description (2/2) Modeled Effects –Earth & ocean tides –Station & satellite absolute PCV –Relativity –ITRF station velocity –Phase wind-up Parameters Estimated –Station and satellite clocks (white noise parameters wrt VRC) –Station troposphere ZPD (random-walk) –Constant (float) ambiguities RT High Precision Correction Stream 120sec (linear over 240sec) 2sec

Geodetic Survey Division EARTH SCIENCES SECTOR Slide GPS·C Results

Geodetic Survey Division EARTH SCIENCES SECTOR Slide GPS·C Development Status –Access to 50+ real-time stations globally –Finalizing stress-tests & application robustness improvements –IOC targeted for Fall 2008  Pilot Project / ESS activities Further Refinements to the Phase-based Algorithm & Models –YAW model (Kouba, GPS Solutions (online)) –Un-differenced integer ambiguity resolution with decoupled clocks –Define BRD-independent orbit messages –Define messages for troposphere-mapping grid, satellite DCB’s –Define messages required for PPP ambiguity resolution

Geodetic Survey Division EARTH SCIENCES SECTOR Slide Day-Boundary Clock Jumps / Decoupled Clocks

Geodetic Survey Division EARTH SCIENCES SECTOR Slide Final Notes IGS Ultra Rapid Combination –Push it to a 3h cycle? Ultimate goal of 1h cycle? –Reduce delay from 3h to 2h? –Need more AC clock solutions to improve precision and accuracy! Global RT GPS Tracking Network –Would provide faster data for Ultra Rapid orbits/clocks turnaround Need for 30sec satellite clocks for Rapid and Ultra Rapid products (NRT users such as PPP)

Geodetic Survey Division EARTH SCIENCES SECTOR Slide 17 Information on decoupled clocks –“Isolating and Estimating Undifferenced GPS Integer Ambiguities”, Paul Collins, GSD, NRCan Presented at the Institute of Navigation, NTM 2008, San Diego, January , session D3. Look also for the corresponding paper in the ION TNM proceeding.

Geodetic Survey Division EARTH SCIENCES SECTOR Slide 18 Statistics based on processing of 5 min data from 24 hour files for ALGO for GPS Week 1470

Geodetic Survey Division EARTH SCIENCES SECTOR Slide 19 Statistics based on processing of 5 min data from 24 hour files for ALGO for GPS Week 1470

Geodetic Survey Division EARTH SCIENCES SECTOR Slide CSRS-PPP Static Positioning Corrections (wrt IGS05) Hours Statistics based on processing of 30 secs data from 24 hour files for ALGO DRAO RESO SASK STJO for GPS Week 1470

Geodetic Survey Division EARTH SCIENCES SECTOR Slide 21 Y. Mireault, P. Tétreault, F. Lahaye, P. Collins, M. Caissy Geodetic Survey Division, Natural Resources Canada (NRCan Natural Resources Canada (NRCan) has been involved in producing and promoting GPS Real-Time (RT) and Near Real-Time (NRT) products and services for more than 10 years. Key products and services, like 1Hz GPS station data, Ultra Rapid GPS orbits/clocks, GPS Precise Point Positioning (PPP) and GPS corrections (GPS·C), have been developed and refined over the past several years. This presentation will focus on current RT and NRT products and services developed by NRCan and made available to users in Canada and world wide. First, a description of the RT GPS tracking network covering Canadian territory and used within GPS·C will be given. Next, NRCan’s hourly Ultra Rapid GPS satellite orbit and 30- sec satellite clock estimation strategy will be presented. Then, we will discuss NRCan’s PPP, a free online post-processing service using IGS and NRCan’s orbits/clocks and IGS IONEX products to allow GPS users world wide to compute better-accuracy positions from their single/dual frequency datasets observed in static/kinematic mode. Finally, an overview of the RT GPS wide-area correction service (GPS·C) distributed nationally through the Canada-wide DGPS will be given. Real-Time and Near Real-Time GPS Products and Services from Canada