GPS and Time Metrology GPS is base for the most common used long-haul time and frequency measurement methods within the time community, it is: –precise.

Slides:

Advertisements

Similar presentations

Advertisements

GALILEO and EGNOS Fotis Karamitsos, European Commission

49 th CGSIC Meeting in Savannah, Georgia, September GPS Time and Frequency Transfer Activities at NIST Victor Zhang National Institute of Standards.

Introduction to GNSS opportunities in different Market Segments

Trimble Positioning Services High-Precision GNSS – Wherever you need it Whenever you need it Tomas Dyjas Sales Manager Central Europe 07 th December, 2011,

GPS Theory and applications

2013 Western Australia Surveying Conference

Full Name: Post /Designation: Qualification (Highest) : CNIC # Organisation Name: Postal Address: Field of Interest: City: Postal Code: Cell: Fax: .

M. Kreider, T. Fleck WhiteRabbit 1 WhiteRabbit Timing System.

Pseudolite Network for Space Users A GPS Augmentation Study for NASA Headquarters Code M-3 Thomas R. Bartholomew Kevin L. Brown Al Gifford.

GALILEO INTERIM SUPPORT STRUCTURE EUROPEAN COMMISSION International Civil Aviation Organization GALILEO CAR/SAM ATN/GNSS Seminar Varadero, Cuba, 6 to 9.

GPS and other GNSS signals GPS signals and receiver technology MM10 Darius Plausinaitis

Absolute Receiver Autonomous Integrity Monitoring (ARAIM)

Ground-Based Altimetry Using a Single- Receiver Single-Frequency GNSS Phase Ambiguity Resolution Technique G. Stienne* S. Reboul J.-B. Choquel M. Benjelloun.

EE 570: Location and Navigation: Theory & Practice The Global Positioning System (GPS) Thursday 11 April 2013 NMT EE 570: Location and Navigation: Theory.

Augstas stabilitātes GPS pieskaņojamās atbalsta frekvences ģeneratora moduļa izstrāde un izpēte Projekta zinātniskais vadītājs Dr.hab.sc.comp. Jurijs Artjuhs.

Satellite-Based Augmentation Systems (SBAS) Combined Performance

Introduction to Global Navigation Satellite Systems Ondrej Kútik.

Aviation Considerations for Multi-Constellation GNSS Leo Eldredge, GNSS Group Federal Aviation Administration (FAA) December 2008 Federal Aviation Administration.

CGSIC 2008, Sept 16 USNO GPS OPS Wendy Kelley U.S. Naval Observatory.

The development of Precise GPS Positioning.  What is Precise GPS Positioning?  Carrier-phase measurement  Relative positioning.

Integrating GPS and GIS: The Basics 6/19/12 Presented By: Doug Kotnik, GISP Precision Laser and Instrument.

GLONASS Government Policy, Status and Modernization

GLONASS Government Policy, Status and Modernization

GNSS Receiver - Software Radio Concept František Vejražka Czech Technical University in Prague Faculty of Electrical Engineering.

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

Monitoring the ionospheric activity using GNSS

Class 19 – NAVSTAR GPS, GLONASS and Galileo

Tripp Corbin, CFM, GISP CEO eGIS Associates, Inc. Relationships Matter.

10/7/ Innovative Solutions International Satellite Navigation Division ION NTM 01 Capabilities of the WAAS and EGNOS For Time Transfer SBAS, an Alternate.

GPS How it Works For a full tutorial on GPS and its applications visit the Trimble WebsiteTrimble Website.

GPS: Global Positioning System  The Geographer’s best friend!  You can say with confidence… “I’m not lost!, I’m never lost!”* *Of course, where everybody.

How Does GPS Work ?. Objectives To Describe: The 3 components of the Global Positioning System How position is obtaining from a radio timing signal Obtaining.

GALILEO The European Programme for Global Satellite Navigation Services GALILEO 03/2004 EUROPEAN COMMISSION.

Global Positioning System

Claudinei Rodrigues de Aguiar Federal University of Technology - Parana Paulo de Oliveira Camargo São Paulo State University.

Measuring the true Integrity of Navigation in Real-Time Antti A. I. Lange PhD

Galileo EU/ESA GPS USA GLONASS Russia Global Navigation Satellite Systems GNSS Accuracy 10m or better Compass China Planned India, Japan, Korea.

Calibration of geodetic (dual frequency) GPS receivers Implications for TAI and for the IGS G. Petit.

Global Navigation Satellite Systems

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

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

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

EGNOS Workshop Kraków, Poland 24 Sep 2004 Institute for the Protection and Security of the Citizen GNSS for field checks of agriculture parcel in IACS.

M. Gende, C. Brunini Universidad Nacional de La Plata, Argentina. Improving Single Frequency Positioning Using SIRGAS Ionospheric Products.

What Makes a GNSS Signal the IGS Analysis Center Workshop 2-6 June 2008, Miami Beach Larry Young (not an expert, just a user) Jet Propulsion Lab.

Global Positioning System Overview

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

EE 495 Modern Navigation Systems

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

International Association of Geodesy 2-Feb-16 1 The Role of the GPS/GNSS in Geodesy and Geodynamics G. Beutler Astronomical Institute, University of Bern.

Kenneth Johnston US Naval Observatory Presented by Jules McNeff International Committee on GNSS Provider’s Forum Bangalore, India 4 September 2007 GPS.

Lecture 22 – NAVSTAR GPS, GLONASS and Galileo 7 April 2009 GISC3325.

49th CGSIC - Timing Subcommittee Outline of presentation  Change in the definition of international time scales (ITU, CCTF)  UTC  TAI  Leap.

GALOCAD GAlileo LOcal Component for nowcasting and forecasting Atmospheric Disturbances R. Warnant, G. Wautelet, S. Lejeune, H. Brenot, J. Spits, S. Stankov.

48th CGSIC - Timing Subcommittee Outline of presentation  International time comparisons  Uncertainties  Upcoming techniques  Glonass and Galileo.

CGSIC Meeting – March 11, 2004 EUROPEAN COMMISSION GPS / Galileo Time Offset ICD Development presented by Jörg Hahn (ESA), E. Powers (USNO)

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

Relative positioning with Galileo E5 AltBOC code measurements DEPREZ Cécile Dissertation submitted to the University of Liège in partial requirements for.

Vladimír Smotlacha, CESNET Alexander Kuna, IPE Time and Frequency Transfer in All-optical Network TNC 2011 Prague 17 May 2011.

2011 All rights reserved National Metrology Centre Status Report about National Metrology Centre A*STAR By LIU Yanying Agency for Science,

Control Methods Workshop 2010 campaign, Ispra April / 37 GNSS: how should we measure parcels in 2010 ? Cozmin LUCAU, Krasimira GANISHEVA,

Report from TCTF WG on TWSTFT Coordinator: Miho Fujieda, NICT Sub Coordinator: Yi-Jiun Huang, TL Sub Coordinator: Hideo Maeno, NICT APMP TCTF meeting Nov.

GPS - Global Positioning System

The Global Positioning System and Embedded Receiver Applications

EE 495 Modern Navigation Systems

Results of the questionnaire for remote calibration in T&F field

GNSS opportunities in Road Transportation

CNES Real-time Analysis center Status

Agenda Background and Motivation

Presentation transcript:

GPS and Time Metrology GPS is base for the most common used long-haul time and frequency measurement methods within the time community, it is: –precise (3ns code, ca 100ps phase for frequency), –truly global, –low cost, use is free of charge, –reliable, robust (during peacetime) and very well monitored, –well understood (code). In combination with other GNSS, for example GLONASS and the future GALILEO, it offers even better robustness and performance.

GPS and Time Metrology Due to its excellent performance (code) it is primarily used to form TAI and UTC. The use of carrier phase (CP) allows to exploit an unmatched accuracy for frequency measurements, but some aspects of CP are still ongoing research! SP GPS time metrology research involves for example: –real-time frequency estimation, –post processing (CP and Code), –comparison with other accurate techniques (TWSTFT), –the use of CP methods on the application niveau (GPS aided clock transport, cable length measurements,...).

Comparison: Real-Time CP versus TWSTFT

Comparison: Real-Time CP versus Post Processed CP

GPS CP Aided Clock Transport