Е-Публикации
Технически университет - София

Abstract: Cet article décrit le développement d’un modèle mathématique à 4 degrés de liberté de la trajectoire de vol en configuration d’approche de l’avion de ligne le plus utilisée, pour court et moyen-courrier, Airbus A320. Cette modélisation a été effectuée à l’aide de logiciel Matlab. Les données pour le modèle et sa validation ont été collectés par la page web d’Airbus et la page web d’aéroport de Munich. Le bruit de jet est considéré comme la source prinicpale des nuisances sonores. On présente les résultats obtenus suite à une discussion de contenue de la minimisation de bruit réalisée près de l’aéroport.

References

1. EC, 2002, Directive 2002/49/EC of the European Parliament and of the Council of 25 June 2002 relating to the assessmentand management of environmental noise (OJ L 129, 18.7.2002, p. 12–25).
2. Е.R. Boeker, E. Dinges, B. He, G, Fleming, C.J. Roof, P.J. Gerbi, A.S. Rapoza, J. Hermann, “Integrated noise model (INM) version 7.0 technical manual”, FAA-AEE-08-01, 2008.
3. W. Krebs, “Sound source data for aircraft noise simulation”, Acta Acoustica united with Acustica Vol, 90p, 91-100, 2004.
4. S. Khardi, L. Abdallah, “Optimization approaches of aircraft flight path reducing noise: Comparison of aircraft modelling methods”, Applied Acoustics 73, p.291-301, 2012.
5. X.P. Menedez, “Contributions to the optimisation of aircraft noise abatement procedures” Doctoral Thesis, Càtedra abertis de Gestión de Infraestructuras del Transporte Universitat Politècnica de Catalunya, 2011.
6. F. Nahayo at al. “Optimal Control of Two-Commercial Aircraft Dynamic System During Approach”, The Noise Levels Minimization. Gen. Math. Notes, Vol. 3, No. 2, April 2011, pp.27-49 ISSN 2219-7184; Publication, 2011.
7. R. Koenig, E. Schubert, “On the Influences of an Increased ILS Glide Slope on Noise Impact, Fuel Consumption and Landing Approach Operation”, AIAC14 Fourteenth Australian International Aerospace Congress, 28 February – 3 March, Melburn, 2014.
8. R. Koenig, E. Schubert, “On the Influences of an Increased ILS Glide Slope on Noise Impact, Fuel Consumption and Landing Approach Operation”, AIAC14 Fourteenth Australian International Aerospace Congress, 28 February – 3 March, Melburn, 2014.
9. J.R. Stone, D.E. Groesbeck, C.L. Zola, “Conventional profile coaxial jet noise prediction”, AIAA Journal, 21(1), pp. 336-342, 1983.
10. J.E. Bridges, A. Khavaran, C.A. Hunter, “Assessment of Current Jet Noise Prediction Capabilities”, 14th Aeroacoustics Conference, Vancouver, British Columbia, Canada, May 5–7, 2008.
11. Airbus-AC-A320, Aircraft Characteristics - Airport And Maintenance Planning. AIRBUS S.A.S. Customer Services, Technical Data Support and Services, 31707 Blagnac Cedex, FRANCE, 2016.
12. Aircraft performance summary tables for the base of aircraft data (BADA) revision 3.0.
13. The Aircraft Noise and Performance (ANP) Database: An international data resource for aircraft noise modellers.
14. http://ww1.jeppesen.com/personal-solutions/aviation/vfr-charts.jsp.
15. https://travis-web01.munich-airport.de/data/travis.php?lang=en&_ga=2.41081378.185368683.1524577872-2134088401.1513440516.
16. A318/A319/A320/A321, Performance Training Manual.

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