nach oben

Erschienen in:

2017 | OriginalPaper | Buchkapitel

31. Ground Based Augmentation Systems

verfasst von : Sam Pullen

Erschienen in: Springer Handbook of Global Navigation Satellite Systems

Verlag: Springer International Publishing

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Zusammenfassung

This chapter explains the fundamentals of ground-based augmentation systems (GBASs). GBASs are fielded at airports to support civil aviation operations down to and including precision approach and landing. This chapter describes how GBAS generates differential corrections for Global Positioning System (GPS) pseudorange (L1 C/A-code) signals based on measurements taken at known (reference) locations, how reference measurements are monitored to protect against GPS and GBAS faults or anomalies, and what information is broadcast to users to support enhanced accuracy and integrity (or safety). The application of GBAS to civil aviation precision approach and landing is explained along with the key considerations in fielding GBAS reference equipment at airports. Augmentation systems that transmit additional global navigation satellite system (GNSS)-like ranging signals to users are also briefly introduced.

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Wirtschaft"

Online-Abonnement

Mit Springer Professional "Wirtschaft" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 340 Zeitschriften

aus folgenden Fachgebieten:

Bauwesen + Immobilien
Business IT + Informatik
Finance + Banking
Management + Führung
Marketing + Vertrieb
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Vorheriges Kapitel Aviation Applications

Nächstes Kapitel Space Applications

31.1

B.W. Parkinson: Introduction and heritage of NAVSTAR, the global positioning system. In: Global Positioning System: Theory and Applications, Vol. 1, ed. by B.W. Parkinson, J.J. Spilker (AIAA, Washington DC 1996), pp. 3–28, Chap. 1CrossRef

31.2

K.R. Zimmerman, H.S. Cobb, F.N. Bauregger, S. Alban, P.Y. Montgomery, D.G. Lawrence: New GPS augmentation solution: Terralite XPS system for mining applications and initial experience, Proc. ION GNSS, Long Beach (2005) pp. 2775–2788

31.3

C.E. Cohen, B.S. Pervan, H.S. Cobb, D.G. Lawrence, J.D. Powell, B.W. Parkinson: Precision landing of aircraft using integrity beacons. In: Global Positioning System: Theory and Applications, Vol. 2, ed. by B.W. Parkinson, J.J. Spilker (AIAA, Washington DC 1996), pp. 427–459, Chap. 15

31.4

F. van Graas, M.S. Braasch: Selective availability. In: Global Positioning System: Theory and Applications, Vol. 1, ed. by B.W. Parkinson, J.J. Spilker (AIAA, Washington DC 1996), pp. 601–621, Chap. 17

31.5

B.W. Parkinson, P. Enge: Differential GPS. In: Global Positioning System: Theory and Applications, Vol. 2, ed. by B.W. Parkinson, J.J. Spilker (AIAA, Washington DC 1996), pp. 3–50, Chap. 1CrossRef

31.6

W.J. Clinton: Statement by the President Regarding the United States’ Decision to Stop Degrading Global Positioning System Accuracy (White House, Office of the Press Secretary, Washington DC 1 May 2000)

31.7

R. Braff: Description of the FAA’s local area augmentation system (LAAS), Navigation 44(4), 411–423 (1997)CrossRef

31.8

GNSS-Based Precision Approach Local Area Augmentation System (LAAS) Signal-in-Space Interface Control Document, DO-246D, 16 Dec. 2008 (RTCA, Washington DC 2008)

31.9

Minimum Operational Performance Standards for GPS Local Area Augmentation System Airborne Equipment, DO-253C, 16 Dec.2008 (RTCA, Washington DC 2008)

31.10

B. Pervan, D. Lawrence, K. Gromov, G. Opshaug, J. Christie, P.-Y. Ko, A. Mitelman, S. Pullen, P. Enge, B. Parkinson: Flight test evaluation of an alternative local area augmentation system architecture, Navigation 45(1), 31–38 (1998)CrossRef

31.11

B. Pervan, F.-C. Chan, D. Gebre-Egziabher, S. Pullen, P. Enge, G. Colby: Performance analysis of carrier-phase DGPS navigation for shipboard landing of aircraft, Navigation 50(3), 181–192 (2003)CrossRef

31.12

G. Lachapelle, P. Alves: DGPS RTK positioning using a reference network, Proc. ION GPS, Salt Lake City (2000) pp. 1165–1171

31.13

G. Crosby, D. Kraus: A ground-based regional augmentation system (GRAS) – The Australian proposal, Proc. ION GPS, Salt Lake City (2000) pp. 713–721

31.14

Minimum Operational Performance Standards for GPS Ground-Based Regional Augmentation System Airborne Equipment, DO-310, 13 Mar. 2008 (RTCA, Washington DC 2008)

31.15

G. Johnson, C. Oates: USCG NDGPS accuracy and spatial decorrelation assessment, Proc. ION GNSS, Nashville (2012) pp. 3665–3674

31.16

S. Pullen, J. Lee: Guidance, navigation, and separation assurance for local-area UAV networks: Putting the pieces together, Proc. ION Pacific PNT, Honolulu (2013) pp. 902–914

31.17

IP-921 Product Page (Microhard Systems Inc., Calgary 2014) http://www.microhardcorp.com/IP921B.php

31.18

Engineering Development Services Group LAAS, US Federal Aviation Administration, William J. Hughes Technical Center, Atlantic City, http://laas.tc.faa.gov/

31.19

Minimum Aviation System Performance Standards for the Local Area Augmentation System (LAAS), DO-245A, Dec. 9, 2004 (RTCA, Washington DC 2004)

31.20

Global Positioning System Wide Area Augmentation System (WAAS) Performance Standard, 1st ed., 31 Oct. 2008 (US Federal Aviation Administration, Washington DC 2008)

31.21

T. Murphy, M. Harris, C. Shively, L. Azoulai, M. Brenner: Fault modeling for GBAS airworthiness assessments, Navigation 59(2), 145–161 (2012)CrossRef

31.22

T. Dautermann, M.L. Felux, A. Grosch: Approach service type D evaluation of the DLR GBAS testbed, GPS Solutions 16(3), 375–387 (2012)CrossRef

31.23

J. Rife, S. Pullen: Aviation applications. In: GNSS Applications and Methods, ed. by S. Gleason, D. Gebre-Egziabher (Artech House, Norwood 2009) pp. 245–267

31.24

Specification: Performance Type One Local Area Augmentation System Ground Facility, FAA-E-2937A, 17 Apr. 2002 (US Federal Aviation Administration, Washington DC 2002)

31.25

G. Xie, S. Pullen: Integrity design and updated test results for the stanford LAAS integrity monitor testbed, Proc. ION AM, Albuquerque (2001) pp. 681–693

31.26

A. Mitelman: Signal Quality Monitoring for GPS Augmentation Systems, Ph. D. Thesis (Stanford Univ., Dept. Aeronautics and Astronautics, Stanford 2004)

31.27

G. Wong, R.E. Phelts, T. Walter, P. Enge: Bounding errors caused by nominal GNSS signal deformations, Proc. ION GNSS, Portland (2011) pp. 2657–2664

31.28

R.E. Phelts: Multicorrelator Techniques for Robust Mitigation of Threats to GPS Signal Quality, Ph. D. Thesis (Stanford Univ., Dept. Aeronautics and Astronautics, Stanford 2001)

31.29

R.E. Phelts, T. Walter, P. Enge: Toward real-tme SQM for WAAS: Improved detection techniques, Proc. ION GPS/GNSS, Portland (2003) pp. 2739–2749

31.30

F. Liu, M. Brenner, C.Y. Tang: Signal deformation monitoring scheme implemented in a prototype local area augmentation system ground installation, Proc. ION GNSS, Fort Worth (2006) pp. 367–380

31.31

FAA LAAS Ground Facility Functions (LAAS KTA Group, Washington DC 1998)

31.32

A.J. van Dierendonck: GPS receivers. In: Global Positioning System: Theory and Applications, Vol. 1, ed. by B.W. Parkinson, J.J. Spilker (AIAA, Washington DC 1996), pp. 329–407, Chap. 8

31.33

B. Pervan, D.V. Simili: Code-carrier divergence monitoring for the GPS local area augmentation system, Proc. IEEE/ION PLANS, San Diego (2006) pp. 483–493

31.34

B. Pervan, L. Gratton: Orbit ephemeris monitors for local area differential GPS, IEEE Trans. Aerosp. Electron. Syst. 41(2), 449–460 (2005)CrossRef

31.35

GPS SPS PAN Report #58 (FAA William J. Hughes Technical Ctr., Atlantic City 2007) http://www.nstb.tc.faa.gov/reports/pan58_0707.pdf

31.36

H. Tang, S. Pullen, P. Enge, L. Gratton, B. Pervan, M. Brenner, J. Scheitlin, P. Kline: Ephemeris type A fault analysis and mitigation for LAAS, Proc. IEEE/ION PLANS, Indian Wells (2010) pp. 654–666

31.37

G. Xie: Optimal On-Airport Monitoring of the Integrity of GPS-Based Landing Systems, Ph. D. Thesis (Stanford Univ., Dept. Aeronautics and Astronautics, Stanford 2004)

31.38

Global Positioning System Standard Positioning Service Performance Standard (GPS SPS PS), 4th edn. (US Department of Defense, Washington DC 2008)

31.39

S. Pullen, J. Rife, P. Enge: Prior probability model development to support system safety verification in the presence of anomalies, Proc. IEEE/ION PLANS, San Diego (2006) pp. 1127–1136

31.40

J. Lee, S. Pullen, P. Enge: Sigma-mean monitoring for the local area augmentation of GPS, IEEE Trans. Aerosp. Electron. Syst. 42(2), 625–635 (2006)CrossRef

31.41

J. Rife, S. Pullen, B. Pervan: Core overbounding and its implications for LAAS integrity, Proc. ION GNSS, Long Beach (2004) pp. 2810–2821

31.42

J. Rife, B. Pervan: Overbounding revisited: Toward a more practical approach for error modeling in safety-critical applications, Proc. ION GNSS, Savannah (2009) pp. 1225–1235

31.43

T. Dautermann, C. Mayer, F. Antreich, A. Konovaltsev, B. Belabbas, U. Kalberer: Non-Gaussian error modeling for GBAS integrity assessment, IEEE Trans. Aerosp. Electron. Syst. 48(1), 693–706 (2012)CrossRef

31.44

J. Rife, R.E. Phelts: Formulation of a time-varying maximum allowable error for ground-based augmentation systems, IEEE Trans. Aerosp. Electron. Syst. 44(2), 548–560 (2008)CrossRef

31.45

J.R. Clynch, A.A. Parker, R.W. Adler, W.R. Vincent, P. McGill, G. Badger: The hunt for RFI: Unjamming a coast harbor, GPS World 14(1), 16–23 (2003)

31.46

J. Grabowski: Field observations of personal privacy devices, Proc. ION ITM, Newport Beach (2012) pp. 689–741

31.47

S. Pullen, G.X. Gao: GNSS jamming in the name of privacy-potential threat to GPS aviation, Inside GNSS 7(2), 34–43 (2012)

31.48

E. Steindl, W. Dunkel: The impact of interference caused by GPS repeaters on GNSS receivers and services, Proc. ENC 2013, Vienna (Austrian Inst. Navigation, Vienna 2013)

31.49

J. Lee, S. Pullen, S. Datta-Barua, P. Enge: Assessment of ionosphere spatial decorrelation for global positioning system-based aircraft landing systems, AIAA J. Aircraft 44(5), 1662–1669 (2007)CrossRef

31.50

S. Pullen: The use of threat models in aviation safety assurance: Advantages and pitfalls, Proc. CERGAL 2014, Dresden (German Inst. Navigation, Bonn 2014)

31.51

S. Pullen, Y.S. Park, P. Enge: Impact and mitigation of ionospheric anomalies on ground-based augmentation of GNSS, Radio Sci. 44(1), RS0A21 (2009)CrossRef

31.52

S. Datta-Barua, J. Lee, S. Pullen, M. Luo, A. Ene, D. Qiu, G. Zhang, P. Enge: Ionospheric threat parameterization for local area global-positioning-system-based aircraft landing systems, AIAA J. Aircraft 47(4), 1141–1151 (2010)CrossRef

31.53

M. Kim, Y. Choi, H.-S. Jun, J. Lee: GBAS ionospheric threat model assessment for category I operation in the Korean region, GPS Solutions 19(3), 443–456 (2015)CrossRef

31.54

C.A. Shively, R. Niles: Safety concepts for mitigation of ionospheric anomaly errors in GBAS, Proc. ION NTM, San Diego (2008) pp. 367–381

31.55

S. Ramakrishnan, J. Lee, S. Pullen, P. Enge: Targeted ephemeris decorrelation parameter inflation for improved LAAS availability during severe ionosphere anomalies, Proc. ION NTM, San Diego (2008) pp. 354–366

31.56

J. Seo, J. Lee, S. Pullen, P. Enge, S. Close: Targeted parameter inflation within ground-based augmentation systems to minimize anomalous ionospheric impact, AIAA J. Aircraft 49(2), 587–599 (2012)CrossRef

31.57

T. Murphy, M. Harris: More ionosphere anomaly mitigation considerations for category II/III GBAS, Proc. ION GNSS, Fort Worth (2007) pp. 438–452

31.58

S. Khanafseh, S. Pullen, J. Warburton: Carrier phase ionospheric gradient ground monitor for GBAS with experimental validation, Navigation 59(1), 51–60 (2012)CrossRef

31.59

J. Jing, S. Khanafseh, S. Langel, F.-C. Chan, B. Pervan: Multi-dimensional ionospheric gradient detection for GBAS, Proc. ION ITM, San Diego (2013) pp. 121–128

31.60

D. Lamb: Development of local area augmentation system siting criteria, Proc. ION AM, Albuquerque (2001) pp. 669–680

31.61

D.B. Thornberg, D.S. Thornberg, M.F. DiBenedetto, M.S. Braasch, F. Graas, C. Bartone: LAAS integrated multipath-limiting antenna, Navigation 50(2), 117–130 (2003)CrossRef

31.62

A.R. Lopez: Calibration of LAAS reference antennas, Proc. ION GPS, Salt Lake City (2001) pp. 1209–1218

31.63

M. Felux, T. Dautermann, H. Becker: GBAS landing system-precision approach guidance after ILS, Aircraft Eng. Aerosp. Technol. 85(5), 382–388 (2013)CrossRef

31.64

Honeywell: SmartPath Ground-Based Augmentation System (GBAS), https://aerospace.honeywell.com/products/safety-systems/smart-path

31.65

N.P.P.F. Spektr: GBAS activities in Russia, ICAO EUR GBAS Implement. Workshop, Paris (ICAO, Montréal 2010) pp. 1–53

31.66

C.R. Spitzer, U. Ferrell, T. Ferrell: Digital Avionics Handbook, 3rd edn. (CRC, Boca Raton 2014)

31.67

Rockwell Collins: GNLU-9X5M Multi-Mode Receiver, www.rockwellcollins.com/Data/Products/Navigation_and_Guidance/Radio_Navigation_and_Landing/GNLU-9X5M_Multi-Mode_Receivers.aspx

31.68

L. Kruczynski: Joint program office test results. In: Global Positioning System: Theory and Applications, Vol. 1, ed. by B.W. Parkinson, J.J. Spilker (AIAA, Washington DC 1996), pp. 699–715, Chap. 19

31.69

B. Pervan: Navigation Integrity for Aircraft Precision Landing Using the Global Positioning System, Ph. D. Thesis (Stanford Univ., Dept. Aeronautics and Astronautics, Stanford 1996)

31.70

Locata Technology Brief v.8.0 (Locata Corporation, Canberra 2014)www.locata.com/technology/

31.71

C. Rizos: Locata: A positioning system for indoor and outdoor applications where GNSS does not work, Proc. APAS 2013, Canberra (Assoc. Public Authority Surv., Canberra 2013) pp. 73–83

Titel: Ground Based Augmentation Systems
verfasst von: Sam Pullen
Verlag: Springer International Publishing
Buch: Springer Handbook of Global Navigation Satellite Systems
Print ISBN: 978-3-319-42926-7

Electronic ISBN: 978-3-319-42928-1

Copyright-Jahr: 2017
DOI: https://doi.org/10.1007/978-3-319-42928-1_31

Springer Professional

Zusammenfassung

Bitte loggen Sie sich ein, um Zugang zu Ihrer Lizenz zu erhalten.

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Springer Professional "Wirtschaft"