A LATERAL DIRECTOR AUTOPILOT DESIGN FOR CONFLICT RESOLUTION ALGORITHMS

Mustafa Suphi Erden, Kemal Leblebicioğlu

Abstract

Conflict resolution, namely avoidance of aircraft crushes, is one of the main problems to be solved in a free flight based air traffic system. The researches on conflict resolution are mainly performed in simulative environments. In the work presented here, a simple lateral director autopilot is designed for conflict resolution studies. Using such a simple autopilot, real aircraft dynamics can be incorporated to conflict resolution techniques and the simulation results can be made closer to real situations.

References

  1. Alliot, JM., H. Gruber, G. Jolly, M. Schoenauer, 1992. Genetic algorithms for solving air traffic control conflicts. In Proceedings 9th IEEE Conference of Artificial Intelligence Application.
  2. Bicchi, A., L. Pallottino, 2000. On optimal cooperative conflict resolution for air traffic management systems. In Proceedings IEEE Transactions on Intelligent Transportation Systems.
  3. Clements, J.C., 1999. The optimal control of collision avoidance trajectories in air traffic management. In Transportation Research Part B 33 (1999) 265-280.
  4. Erden, M.S., K. Leblebicioglu, U. Halici, 2001. Çok ajanli system yaklasimiyla hava trafigi kontrolü, In 9.Sinyal Isleme ve Uygulamalari Kurultayi, Gazimagosa - KKTC.
  5. Erden, M.S., K. Leblebicioglu, U. Halici, 2002. Conflict resolution by negotiation. Abstract In IFAC 15th World Congress Book of Abstracts, 230, Barcelona, Spain; full paper in the related CD.
  6. McLean, D., 1990. Automatic Flight Control Systems, Prentice Hall International (UK) Ltd.
  7. Nelson, R.C., 1998. Flight Stability and Automatic Control, McGraw-Hill Companies Inc.
  8. Pappas, G.J., C.J. Tomlin, J. Lygeros, D.N. Godbole and S.S. Sastry, 1997. A next generation architecture for air traffic management systems. In IEEE Conference on Decision and Control, pp 2405-2440, San Diego, California, USA.
  9. Petrick, H., M. C. Felix, 1998. A soft dynamic programming approach for on-line aircraft 4-D trajectory optimization. In European Journal of Operational Research 107, 87-95.
  10. Rauw, M.O., 1998. FDC 1.2-A SIMULINK Toolbox for Flight Dynamics and Control Analysis, Chapter 11, February 8.
  11. Sachs, G., 1999. Flight path predictor for minimum pilot compensation, Aerospace Science and Technology, 4, 247-257.
  12. Stevens B.L. and F.L. Lewis, 1992. Aircraft Control and Simulation, John Willey & Sons Inc.
  13. Tomlin, C., R. Ghosh, 2000. Maneuver design for multiple aircraft conflict resolution. In Proceedings of the American Control Conference, Chicago, Illinos.
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Paper Citation


in Harvard Style

Suphi Erden M. and Leblebicioğlu K. (2004). A LATERAL DIRECTOR AUTOPILOT DESIGN FOR CONFLICT RESOLUTION ALGORITHMS . In Proceedings of the First International Conference on Informatics in Control, Automation and Robotics - Volume 2: ICINCO, ISBN 972-8865-12-0, pages 330-334. DOI: 10.5220/0001133903300334


in Bibtex Style

@conference{icinco04,
author={Mustafa Suphi Erden and Kemal Leblebicioğlu},
title={A LATERAL DIRECTOR AUTOPILOT DESIGN FOR CONFLICT RESOLUTION ALGORITHMS},
booktitle={Proceedings of the First International Conference on Informatics in Control, Automation and Robotics - Volume 2: ICINCO,},
year={2004},
pages={330-334},
publisher={SciTePress},
organization={INSTICC},
doi={10.5220/0001133903300334},
isbn={972-8865-12-0},
}


in EndNote Style

TY - CONF
JO - Proceedings of the First International Conference on Informatics in Control, Automation and Robotics - Volume 2: ICINCO,
TI - A LATERAL DIRECTOR AUTOPILOT DESIGN FOR CONFLICT RESOLUTION ALGORITHMS
SN - 972-8865-12-0
AU - Suphi Erden M.
AU - Leblebicioğlu K.
PY - 2004
SP - 330
EP - 334
DO - 10.5220/0001133903300334