GSP – Galileo Signal Priority
… Space for Priority
Galileo Signal Priority A new approach to TSP Közlekedéstudományi Konferencia Győr 2014 27 március 2014 Dr. Tomasz Kulpa – Politechnika Krakowska
Dr. Jörg Pfister – pwp-systems GmbH The research leading to these results has received funding from the European Union Közlekedéstudományi Konferencia Győr 2014 Framework Programme (FP7/2007-2013) under grant agreement n [277688-2].
GSP Project Galileo Signal Priority • 7th Framework Programme • Supervised by GSA – European GNSS Agency • Duration: January 2012 – March 2014
… Space for Priority! Közlekedéstudományi Konferencia Győr 2014
Partners pwp-systems GmbH
Széchenyi István Egyetem
Telematix services a.s.
Politechnika Krakowska Közlekedéstudományi Konferencia Győr 2014
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Functions of public transport • Which functions in public transport need position: – – – –
Disposition Real Time Passenger Information Dynamic Schedule Synchronization Transit Signal Priority
• Transit Signal Priority (TSP) is still dominated by infrastructure based system • If onboard intelligence can satisfy the requirements of TSP, the infrastructure is dispensable, which leads to significant cost savings. • Performance improvement with GNSS can make PT more attractive Közlekedéstudományi Konferencia Győr 2014
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Not only PT
Közlekedéstudományi Konferencia Győr 2014
Project aims
1. Development of RPP (Robust Positionning Prototype) device for PT vehicles posotionning purposes
2. Assessment of RPP and different TSP scenarios with microsimulation tools (VISSIM)
Közlekedéstudományi Konferencia Győr 2014
Project structure
GSP Galileo Signal Priority
WP 1 Project Management
WP 2 System Design and Tech. Development
WP 3 Demonstration
WP 4 Assessment and Dissemination
WP 1.1 Project Management
WP 2.1 Technical Specification and System Analysis
WP 3.1 Demonstration in Halle
WP 4.1 Technical Assessment of RPP
WP 1.2 Tech. Coordination
WP 2.2 Development of Positioning Prototype
WP 3.2 Demonstration in Cracow
WP 4.2 Technical Assessment of TSP
WP 1.3 Controlling and Reporting
WP 2.3 Implementation into Traffic Simulation (VISSIM)
WP 5 Market Trial and Market Development
WP 4.3 Socio-Economic Evaluation
WP 2.4 Development of TrafficLight Algorithm
Közlekedéstudományi Konferencia Győr 2014
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Scope of workpackages • Development of RPP (Robust Positioning Prototype) (PWP) – development – installing in tram – test trials
• Development of microsimulation models of selected junctions (PK) – positioning errors within microsimulation
• Assessement and dissemination (SIU) – COBA – participation in conferences – organisation of conferences and workshops
• Market trial (TMX) Közlekedéstudományi Konferencia Győr 2014
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RPP in tram RPP: GNSS + EGNOS Accelerometer Gyroscope
Interfaces: Ethernet, Serial CAN-Bus, IBIS-Bus R09.16-Telegram
Közlekedéstudományi Konferencia Győr 2014
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Galileo testing field low-cost GPS
Antennas
L1/L2 GPS
ITCS-Equipment
Inertiale NavigationUnit Doppler-Radar
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RPP vs. GNSS – Example 1
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RPP vs. GNSS – Example 2
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RPP assessment • Precission – positionning 6,25 m (95%) and 25 m (99%) – speed 0,25 m/s – availability 99,9%
• 9 test trials
Közlekedéstudományi Konferencia Győr 2014
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RPP assessment results
Parameter
GNSS
RPP
Position
AVE: 4.52 m
AVE: 2.79 m
Position
K95: 10.94 m
K95: 6.04 m
Position
K99: 20.47 m
K99: 7.63 m
Speed
AVE: 0.16 m/s
AVE: 0.04 m/s
Azimuth
AVE: 2.6 °
AVE: 0.9 °
Availability
97.9 %
100 %
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RPP and GNSS errors distribution RPP
GNSS
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Results for junction in Krakow min. 8,4 / max. 55,8
min. 8,2 / max. 37,4
Közlekedéstudományi Konferencia Győr 2014
Results for junction in Halle
Közlekedéstudományi Konferencia Győr 2014
Cost/Benefit Analysis (COBA) • Input from microsimulation – time losts
• Other data – unit cost of passengers – unit operational cost – unit investment and maintanance costs
• Scenarios assessment – passenger costs – operational costs – investment and maintanance costs
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Summary • RPP fulfils precision and reliability requirements • RPP might be used fo passenger information and TSP one unit, multiple use • lower cost of whole system (around 20%) compared to infrastructure based TSP • higher elasticity (comparing to induction loops) as well as precission and reliability (compared to available GNSS)
Közlekedéstudományi Konferencia Győr 2014
Possible aplications • possible to use in new TSP systems • especially useful in buses change of route, bus detection on separated and common lanes • floating pre-emption point constant travel time from pre-emption point to stop line, instead of constant distance • continuously updated vehicle position • continuous positioning data transfer limits
Közlekedéstudományi Konferencia Győr 2014
GSP – Galileo Signal Priority
… Space for Priority
KÖSZÖNÖM!
The research leading to these results has received funding from the European Union Közlekedéstudományi Konferencia Győr 2014 Framework Programme (FP7/2007-2013) under grant agreement n [277688-2].
