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High-accuracy four-dimensional trajectory prediction for civil aircraft

Published online by Cambridge University Press:  27 January 2016

W. Schuster ,
M. Porretta  and
W. Ochieng
W. Schuster*
Affiliation:
Centre for Transport Studies, Imperial College, London, UK
M. Porretta
Affiliation:
Centre for Transport Studies, Imperial College, London, UK
W. Ochieng
Affiliation:
Centre for Transport Studies, Imperial College, London, UK
*
w.schuster@imperial.ac.uk
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Abstract

Current state-of-the-art trajectory prediction tools typically model aircraft as three-dimensional point-masses, and make a number of simplifying assumptions about the actual and anticipated dynamics states of the aircraft. They are typically based on predefined settings obtained from existing databases such as Eurocontrol’s Bada rather than real-time information, including on the environment, available onboard the aircraft. This significantly limits trajectory prediction performance. This paper proposes a high-accuracy four-dimensional trajectory prediction model for use onboard civil aircraft, as well as by ground-based systems, which addresses these limitations. It is designed for strategic traffic capacity optimisation and conflict-detection and resolution over time-horizons covering the entire duration of a flight. The model incorporates a number of features including a novel flight-control-system and an enhanced flight-script that incorporates new taxonomy and content thereby enabling better definition of aircraft intent. The accuracy of the model is characterised using operational data acquired during a real flight trial. Results show that the performance of the proposed model is significantly better than the current models. Its accuracy is better than the required navigation performance for departure, en route and Non-Precision-Approach phases of flight.

Type
Research Article
Information
The Aeronautical Journal , Volume 116 , Issue 1175 , January 2012 , pp. 45 - 66
Copyright
Copyright © Royal Aeronautical Society 2012 

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References

1. Fairley, G.T. and McGovern, S., A Kinematic/Kinetic Hybrid Airplane Simulator Model, ASME International Mechanical Engineering Congress and Exposition, Proceedings 1, pp 1120.Google Scholar
2. ICAO (1964), Manual of the ICAO Standard Atmosphere, ICAO Doc 7488.Google Scholar
3. SESAR Consortium (2006 – 2008), http://www.eurocontrol.int/sesar/public/standard_page/documentation.html, Deliverables D1 – D6.Google Scholar
4. Glover, W. and Lygeros, J. A Stochastic Hybrid model for Air Traffic Control Simulation, Hybrid Systems: Computation and Control, 2004, ser. LNCS, Alur, R. and Pappas, G. Springer Verlag, (2993), pp 372386.Google Scholar
5. Glover, W. and Lygeros, J. (2004), A Multi-Aircraft Model for Conflict Detection and Resolution Algorithm Validation, Technical Report WP1, Deliverable D1.3, HYBRIDGE.Google Scholar
6. Porretta, M., Dupuy, M-D., Schuster, W., Majumdar, A. and Ochieng, W. Performance evaluation of a novel 4D trajectory prediction model for civil aircraft, J Navigation, 2008, 61, (03), pp 393420.Google Scholar
7. RTCA (2009), NextGen Mid-Term Implementation Task Force, RTCA Task Force 5.Google Scholar
8. Schuster, W. et al High Accuracy Navigation Report, 2008, ANASTASIA D3.2.3.2.Google Scholar
9. EUROCONTROL (2009b), Reference Validation Data Base, EUROCONTROL TP team website.Google Scholar
10. ICAO (2008), Performance-based Navigation (PBN) Manual, ICAO Doc 9613 AN/937.Google Scholar
11. EUROCONTROL Experimental Centre (2009), User Manual for the Base of Aircraft Data (BADA), Revision 3.7, EEC Note 10/04.Google Scholar
12. Vilaplana Ruiz, M.A. (2005), COURAGE Domain Analysis Deliverables D2.1 and D3.1, The Boeing Research and Technology Europe, Madrid, Spain.Google Scholar
13. Erzberger, H. and Heere, K. Algorithm and Operational Concept for Resolving Short Range Conflicts, 2008, Proc 26th International Congress of the Aeronautical Sciences, Anchorage, Alaska, USA, 2008.Google Scholar
14. Paielli, R. Tactical conflict resolution using vertical maneuvers in en route airspace, AIAA J Aircr, November-December 2008, 45, (6).Google Scholar