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The Wide Area Augmentation System (WAAS)

The Wide Area Augmentation System (WAAS). Todd Walter Stanford University http://waas.stanford.edu. Conclusions. WAAS is used to provide aircraft navigation from enroute through vertically guided approach Integrity was and is the key challenge

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The Wide Area Augmentation System (WAAS)

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  1. The Wide Area Augmentation System (WAAS) Todd Walter Stanford University http://waas.stanford.edu

  2. Conclusions WAAS is used to provide aircraft navigation from enroute through vertically guided approach Integrity was and is the key challenge Important to understand what can go wrong and how to protect users Careful analysis of feasible threats New civil frequencies and additional constellations will further improve performance

  3. The Wide-Area Augmentation System Integrity Analyses Comparison with Terrestrial Navigational Aids Future Directions Outline

  4. WAAS

  5. WAAS Architecture 38 Reference Stations 3 Master Stations 4 Ground Earth Stations 2 Geostationary Satellite Links 2 Operational Control Centers Courtesy:

  6. Geostationary Satellites (GEO) • Provides Dual Coverage Over United States PanAmSat 133°W Telesat 107°W Courtesy:

  7. Satellite errors Ephemeris Clock Signal Propagation errors Ionosphere Troposphere Local Errors Multipath Receiver Noise Error Sources

  8. Master Station Schematic

  9. Complicated Schematic

  10. GPS Performance (Usually) On a good day, the red circle encloses 95% of the GPS position fixes.

  11. Major GPS Faults About Twice a YearExample: Ephemeris Failure on April 10, 2007 On a bad day, the GPS errors can be much worse. WAAS & GBAS eliminate these large errors.

  12. Aviation integrity operates on a guilty until proven innocent principle Error bound is the maximum possible value given the measurements This is unlike conventional systems that describe the most likely errors Protection level is a 99.99999% bound on worst reasonable conditions Very different from 95% achieved accuracy Integrity Approach

  13. Failure of Thin Shell Model Quiet Day Disturbed Day

  14. Undersampled Condition Courtesy: Seebany Datta-Barua

  15. 11/20/200321:00:00 GMT

  16. Localizer Performance Vertical (LPV) Coverage Courtesy:

  17. WAAS RNP 0.3 Current Coverage Courtesy:

  18. WAAS LPV and LPV-200 Vertical Position Error Distributions July 2003 to June 2006 Courtesy: FAA Technical Center 3 years 20 WRSs 1 Hz data

  19. Instrument Landing System (ILS) Glideslope antenna for vertical Localizer for horizontal Navigational Aids

  20. ILS Installations: Each Runway EndRequires At Least Two Transmitters 1318 ILS’s nationwide

  21. Airports with WAAS LPVNo GPS Equipment Required at Airport50 Pieces of WAAS Equipment Serve the Continent • As of November, 2009 • 1820 WAAS-based LPV’s • ~1000 for non ILS runways

  22. Localizer Approaches at Moffett Field Courtesy: Sharon Houck

  23. Utility of Protected Accuracy from WAAS • Localizer performance with • vertical guidance (LPV) • Safer than lateral nav. • (non-precision approach) • Same decision ht. as Cat I • GBAS for Cat. II & III • WAAS (& GBAS) tunnels: • Do not flare like ILS • Do not have beam bends • Are programmable • Are adaptable

  24. Current WAAS Performance

  25. Future L1/L5 Performance

  26. L1-only Threats • Reference station multipath, noise, cycle slips, and other receiver errors – WRE bias, CNMP • Satellite clock/ephemeris – UDRE/MT28 • Erroneous ionospheric delay estimates - GIVE • Erroneous WRE clock estimates, interfrequency bias estimates – RDM • L1 code/carrier incoherence – CCC • L1 signal deformation – SQM • Multiple convolved threats – UPM, convolution analysis • Antenna biases, GEO biases – specific analyses

  27. L1/L5 Threats • Reference station multipath, noise, cycle slips, and other receiver errors – WRE bias, CNMP – unchanged • Satellite clock/ephemeris – UDRE/MT28 – need to remove L1/L2 bias from Fast Correction, could remove uncertainty from UDRE • Erroneous ionospheric delay estimates - GIVE – uneeded • Erroneous WRE clock estimates, interfrequency bias estimates – RDM – IFBs uneeded,WRE clocks may be handled by UDRE/UPM

  28. L1/L5 Threats cont. • L1/L5 code/carrier incoherence – CCC – new/updated monitor, MERR reduced without GIVE while threat is potentially increased • L1/L5 signal deformation – SQM – new/updated monitor, MERR reduced while threat is increased. User space will need to be greatly restricted • Multiple convolved threats – UPM, convolution analysis – new/updated monitor specific to L1/L5 user • Antenna biases, GEO biases – specific analyses – new/updated analysis, effects are greater

  29. CCC Threats • Iono-free ccc metric expected to have 2.6 times as much noise as L1-only version • Trip thresholds may need to be increased • Could lead to UDRE bumps or trips • MERR substantially reduced without GIVE • Need much reduced thresholds and test • L1 only monitor has margin thanks to GIVE • Need to collect data to see real test • Need L5 data, but L2C might be OK • High risk factor for not being able to match L1 UDREs

  30. Frequency Dependencies

  31. SDM Threats • Bias threats on L1 have 2.26 times greater influence on iono-free users • L5 biases also must be added • MERR substantially reduced without GIVE • Nominal and threat biases potentially 3.5 times those on L1 only • Bias terms in VPL potentially very beneficial to iono-free user • Need to further restrict user space • L1 and L5 may need to be a very tight box around monitor choice • Difficult to get international buy-in

  32. Conclusions WAAS is used to provide aircraft navigation from enroute through vertically guided approach Integrity was and is the key challenge Important to understand what can go wrong and how to protect users Careful analysis of feasible threats New civil frequencies and additional constellations will further improve performance

  33. Potential of L1/L5 GPS/Galileo Performance

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