The EU GNSS Programmes: EGNOS, GALILEO Status & International Cooperation Ugo Celestino European Commission Damascus, 8 April 2010
Content EU GNSS Programmes - Galileo -EGNOS International Cooperation 2
Introduction Galileo An autonomous infrastructure Global coverage Global Space and Ground elements Services similar to GPS, plus innovative ones EGNOS Simply improves GPS performances Coverage: European landmasses Limited Space and Ground elements Mainly for aviation users («Safety-of-Life») 3
EU GNSS Governance Political oversight European Parliament Council Programme oversight and Programme Management Independant advisors Execution European Space Agency IOV contracts FOC contracts European Commission delegation assistance and delegation Assistance tasks to EC Tasks delegated by EC European GNSS Programme Committee Egnos Service Provider GNSS Supervisory Authority Market preparation Research Accreditation Others 4
GALILEO Navigation solutions powered by Europe 5
Galileo System Architecture 9 Mission Uplink Stations 5 TT&C Stations Constellation of 30 MEO Satellites Users & Service Providers European Control Centres 30-40 Galileo Sensor Stations 6
Galileo vs GPS & Glonass Ground segment GPS Glonass Galileo # Control center 2 2 3 # Monitoring stations Baseline Plans 6 17 4 10 30 to 40 -- # Uplink Stations 3 3 9 # Telemetry, Tracking and Control 4 5 5 More extended to provide more (civilian) services 7
Galileo vs GPS & Glonass Space Segment GPS Glonass Galileo # Orbital planes 6 3 3 # Spacecraft Baseline 24 24 30 Status 31 20 0 Altitude (km) 20 160 19 100 23 200 Inclination 55 65 56 Period 12 h 11 h 14 h 8
Galileo Services Open Service Commercial Service Safety of Life Service Public Regulated Service Free to air; Mass market; Simple positioning Encrypted; High accuracy; Guaranteed service Open Service + Integrity of signal Encrypted; Continuous availability Search and Rescue Service Near real-time; Precise; Return link 9
Galileo Implementation Plan Initial Open Service, Search & Rescue Service, Public Regulated Service minimum 18 satellites In-Orbit Validation 4 IOV satellites plus ground segment 2010/11 2014 All services 30 satellites 2016/17 Galileo System Testbed v1 Validation of critical algorithms Galileo System Testbed v2 2 initial test satellites 2003 2005/07 10
Galileo IOV Ground Segment Sites Svalbard ULS/GSS Alaska GSS Kiruna TTC Redu GSS Washington GSS Fucino GSS Riyadh GSS S. Korea GSS Hawaii GSS Kourou TTC/ULS/GSS New Caledonia ULS/GSS Reunion ULS/GSS Papeete ULS/GSS Easter Island GSS Cordoba GSS South Africa GSS Perth GSS Troll GSS Sensor Stations Up-Link stations TT&C stations Control Centres 11
Galileo IOV vs FOC IOV (In Orbit Validation), FOC (Full Operational Capability) Component Satellites IOV Phase 4 FOC Phase 27(+3) Control Centres 1 3 Mission Uplink Stations 5 9 TT&C Stations 2 5 Sensor Stations 20 30-40 2011 2016/17 12
Galileo IOV Control Centres Oberpfaffenhofen (DE) Fucino (IT) Credits: ESA 13
Galileo IOV Ground Segment Sites Kiruna Galileo TTC Site Completed (Nov 2007) Svalbard Galileo ULS/GSS Site Completed (May 2008) Credits: ESA 14
Galileo FOC Procurement Infrastructure procurement divided in 6 work packages Tender launched on July 1, 2008 Candidates have been shortlisted (see table) WP1, WP4 and WP5 : contracts were signed on January 26, 2010 WP2, WP3 and WP6 : competitive dialogue is under way; award decisions in 2010 15
Galileo Procurement candidate suppliers Work Package 1. System Support 2. Ground Mission Segment 3. Ground Control Segment 4. Space Segment 5. Launch Services 6. Operations Retained Candidates (winners in green) ThalesAleniaSpace (IT) Logica (NL) ThalesAleniaSpace (FR) Logica (UK) Astrium (UK) G-Nav: Lockheed Martin IS&S (UK) Astrium (DE) OHB System (DE ): 14 satellites Arianespace (FR) Opal: DLR (DE) and Telespazio (IT) Nav-Up: Inmarsat, VEGA, BT 16
Galileo Programme Status 2009 IOV : ground infrastructure deployments FOC : first procurement contracts awarded (system support services, first 14 satellites, launchers) 2010 IOV : first two operational satellites to be launched in Dec 2010 FOC : remaining procurements contracts to be awarded in 2010 2011 IOV : third and fourth satellites to be launched in 2011 FOC : ground infrastructure deployments 2012 onwards Progressive FOC deployment with step-wise service introduction as of 2014 (Open Service, Search And Rescue Service, Public Regulated Service) 17
Galileo Challenges Finalise contracts for 3 workpackages Mission Control Operations Decide on launcher options Ensure security accreditation of ground stations Complete budget for FOC Decision PRS access rules Launch 2 «IOV» satellites around 2010 year end 18
EGNOS It s there, use it 19
EGNOS System Architecture 6 Navigation Land Earth Stations 3 GEO Satellites Users & Service Providers 2 Support Facilities 4 Mission Control Centres 34 Ranging & Integrity Monitoring Stations (RIMS) GPS signals 20
EGNOS improves GPS over EuropeNavigation solutions powered by Europe EGNOS Geo-stationary Satellite relays error corrections to users GPS and GLONASS Satellite Constellation EGNOS position accuracy Navigation Land Earth Station (NLES): uplinks error corrections to EGNOS satellites GPS position accuracy Ranging and Integrity Monitoring Stations (RIMS) : receive GPS data & send to MCC Mission Control Centre (MCC) processes GPS data to determine errors 21
EGNOS RIMS Location EGNOS Satellite Footprints RIMS Ranging & Integrity Monitoring Stations (some additional RIMS are not in view) 22
EGNOS improvement on precision True position = Positions potentially given by receiver North South West East GPS D-GPS SBAS (EGNOS) 23
EGNOS Services Current Status Service Accuracy Guarantee of Service Service Status Transmission Means Open Service Typical vertical and horizontal positioning accuracy in the centre of Europe around 1m None Service available since October 2009 L1 frequency (spec: 3m horizontal, 4m vertical) Safety of Life Service Same accuracy as Open Service. SoL service levels compliant to ICAO SARPS definition for APV1 Compliance with ICAO standards (certification) Service to be made available in November 2010 L1 frequency Commercial Service (EDAS) Corrections provided by terrestrial network allow for sub-meter accuracy locally or regionally through additional processing Compliance with SLA when commercialisation will start Experimental service available; Official service to be made available in 2011 Ground network Guarantee of service is key 24
EGNOS Performance - availability Navigation solutions powered by Europe Nearly 100% availability for an extended period 25
EGNOS Performance - coverage Deployment of additional RIMS in North- East-South Europe, Northern Africa, Middle East will increase availability area of APV-1 26
EGNOS Performance - integrity Source: http://www.egnos-pro.esa.int/imagetech/perfect/real_time/view_all/toulouse.html HPE Horizontal Precision Error, HPL Horizontal Protection Level With around 1 m (blue line), the measured Horizontal Precision Error in Europe is consistently better than the requirements 27
EGNOS coverage goes beyond EU EGNOS Service Area EGNOS Satellite Footprints 3 Geostationary satellites INMARSAT 3F2 AOR-E (15.5 W), ARTEMIS (21.3 E), INMARSAT 3F5 IOR-W (25 E) Soon replaced by: - INMARSAT 4F2 - SIRIUS 5 - ASTRA 5B 28
EGNOS Programme status 2009: Assets were transferred to the European Union on April 1, 2009 Open Service declaration took place on Oct 1, 2009 Long-term operator contract was signed on Oct 1, 2009 Procurement to replace the transponder on Artemis is finalized (Astra Sirius 5 to be launched in Nov 2011) Procurement to replace the transponder on Inmarsat 4F2 is ongoing (Astra 5B to be launched in June 2013) Free testing of Commercial Service by Industry & Academia Geographical extension to Africa under study 2010: Safety-of-Life Service declaration planned for November 1, after certification Commercial Service declaration planned for 2011 29
EGNOS Certification Before EGNOS can be used for safety critical operations, it should be demonstrated that it is designed and operated in a safe manner Certification requirements baseline: Single European Sky Regulatory package: Interoperability Regulation (EC No 552/2004) Service Provision Regulation (EC No 550/2004) Provision of air navigation services in the Single European Sky Commission Regulation (EC No 2096/2005) ANSP certification process Safety Oversight Regulation (EC No1315/2007) 30
EGNOS benefits in aviation General operational benefits Reduction in angle of approach (direct and curved) Better lateral guidance EGNOS enables a reduction in the decision height EGNOS competitive space Allows for IFR-like operation in non ILS-equipped airports Increase in airports capacity Increase in safety Increase in flight capability (e.g. helicopters) Expensive land based navaids can be avoided Enables their long term decommissioning => lower terminal charges 31
EGNOS Challenges Ensure certification of operator for SoL Complete ECAC coverage Remove obsolescences Manage the assets Frequency Evolution Evolution of Standards Augmentation of new GNSS LPV200 service level Maintain EGNOS over the long term Capture economic opportunities downstream, in aviation and beyond 32
EU GNSS Budget 2007-2013: 3.5Bn GNSS budget allocations 2007-2013 (in M ) 426 18,5 307 20 Galileo ESA Delegation Agreement Other operational expenses 57,5 Galileo IOV Delegation Agreement Administrative expenditure EGNOS 2.645 Public regulated service pilot project 33
International Cooperation 34
Cooperation: diverse intensity and scope Country or Region specific Agreements with: Norway, Switzerland, USA, South Korea, Ukraine, Morocco, other ad hoc for Galileo GS, other under discussion Regional training centers: Asia, Africa, Latin America Galileo/EGNOS applications development R & D EGNOS modular extension General Multilateral: Founding member of UN International Committee on GNSS & Providers Forum, candidate to host ICG in 2010 Compatibility Interoperability Standardisation Trade matters 35
EU Objectives in Bi/Multi-lateral Coordination Ensure compatibility at a minimum: ability of space-based PNT services to be used separately or together without interfering with each individual service or signal, and without adversely affecting national security Radio frequency compatibility (ITU provides a framework) Spectral separation between PRS and other signals Compatibility is a MUST Once Compatibility has been achieved, interoperability can be addressed 36
EU Objectives in Bi/Multi-lateral Coordination Galileo encourages interoperability between Galileo open signals (OS, SoL and CS) and other space-based PNT signals when desirable for the benefits of users Focus on E1 CBOC (MBOC), AltBOC E5 (which includes E5a & E5b) and E6 CS signals Common maximum power level is a necessary aspect of Interoperability (and compatibility) Highest minimum power level is a desired aspect as well 37
Outstanding Issues on Interoperability Definition of interoperability? Technical: same center frequency, same modulation, commonly agreed maximum power level, geodetic reference frames realization and system time reference Non-technical: transparency and availability of open information on signals (e.g. SIS ICD), availability of open information on performance standards and actual performance ICG (International Committee GNSS) should work on the definition of consolidated boundary conditions to achieve interoperability 38
EU US Agreement 2004 Agreement: plenary session held in October 2008 Radio-frequency compatibility and interoperability: common MBOC civil signal on GPS L1C Galileo E1 open service Trade and civil applications Design and development of the next generation Security and International aspects 39
China EU Agreement 2003 Agreement: regular steering Committee meetings Run by MOST and European Commission Beidou/Compass was not involved until recently Technical Working Group regular meetings to address the compatibility and interoperability between Galileo and Compass Industrial Working Group regular meetings to address industrial cooperation 40
India EU Draft Agreement Regular meetings to address the compatibility and interoperability of IRNSS and GAGAN with Galileo and EGNOS 41
Russian Federation EU Discussions Under the hospices of the EU RF Space Dialogue Regular meetings to address the compatibility and interoperability of GLONASS and SDCM with Galileo and EGNOS Draft Agreement under discussion 42
Japan EU Discussions Regular meetings to address the compatibility and interoperability of QZSS with Galileo Good prospect for an E6 CS / QZSS Lex interoperable signal Draft Agreement under consideration 43
R&D for applications/service development Technical MEDA 1 2M MEDA 2 1,6M General Aviation Mobile LBSRoad navigation GNSS market Aw-T-Demo 2,5M 1,9M Road charging & safety critical Profes sional Mariti me & multi modal Rail Enablers Regulatory 0,8M 0,2M 25M [First Call FP7] 40M [ Second Call FP7] 4,5M [2006-09] 4,5M [36 months] Non-EU partners usually join consortia 44
Potential EGNOS extensions EGNOS Service Area MEDA Extension Northern-East Europe Arabic peninsula Depending on the extension area, technical implementation may vary from: Homogeneous extension with deployment of additional RIMS Regional infrastructure including additional processing capabilities W. Africa S. Africa EGNOS Satellite Footprints To be further evaluated 45
Conclusions EGNOS enters its operational phase EGNOS Open Service since Oct 2009 EGNOS Safety-of Life-Service in 2010 Galileo is progressing, at the crossing between the development (IOV) and deployment (FOC) phases GIOVE-A, GIOVE-B missions on-going FOC procurement on-going First two operational satellites in 2010 OS, S&R Service, PRS as of 2014 International cooperation is important GALILEO: - Secure ground infrastructure - Compatibility as a minimum, interoperability desired - Enable new services provision, free trade and fair access to markets worldwide EGNOS: - Leverage EU investment to service other areas - Applications development on common standards 46
Thank you for your attention Further information: http://www.satellite-navigation.eu/ Input and questions are welcome ugo.celestino@ec.europa.eu