Control Systems and Computers, N5, 2017, Article 6

Upr. sist. maš., 2017, Issue 5 (271), pp. 62-74.

UDC 629.7.077

D.O. Voloshenyuk 1, S.V. Pavlova2

1 Research fellow, Department of intelligent control, International Research and Training Center for Information Technologies and Systems of NAS of Ukraine and MES of Ukraine, 40, Glushkova ave., Kyiv, 03187, Ukraine, E-mail:

2 Senior research fellow, Department of intelligent control, International Research and Training Center for Information Technologies and Systems of NAS of Ukraine and MES of Ukraine, 1, Kosmonavta Komarova ave., Kyiv, 03187, Ukraine, E-mail:

The Aircraft Landing Management in Conditions of Increasing the Air Traffic Intensity

 Purpose: The scientific task of the developing methods, models and means of informational support of decision making for the construction of an optimal landing trajectory for further improvement of the airplane flight safety and upgrading of environmental and economic indicators of the aviation equipment use is relevant.

Methods: In order to reduce the number of aviation events, ICAO’s decision is made on the need to install an ILSupgraded

ILS or microwave landing system (MLS) in airports at the airports. However, there are currently four types of landing systems that meet the requirements of ICAO and aviation experts must select one of them. These are the ILS, MLS and two completely different satellite landing systems. All four systems meet the requirements of ICAO for automatic landing systems for the XXI century.

Results: Accordingly, the task is to create a system in the aviation industry that will allow:

– quantitatively and qualitatively increase the level of environmental friendliness and efficiency of flights in aviation in general;

– to substantially improve the safety of flights;

– solve the problem of airport overload with air traffic intensity;

– to increase the efficiency of the aviation equipment use, etc.

Discussion: The perspective direction is the introduction of a satellite communication system, navigation and surveillance. Important parameters that characterize the landing systems (in addition to reliability requirements) are the accuracy of the determining navigational parameters, working area and range of action.

Keywords: Aircraft Landing, Microwave Systems, Flexible Trajectories, Air Traffic, Aviation Security.

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  1. Pavlov V.V., Voloshenyuk D.O., Volkov O.Ye. The concept of network centric control of landing aircraft on free paths with technology for solving conflict situations. Kibernetika i vyčislitelnaâ tehnika, 2014, 178, P. 36–51. (in Ukrainian).
  2. THE ICAO CIRCULARS on ergonomics and human Factors, ICAO: 2000, N 1–12.
  3. Pavlov V.V., Skripec A.V. Ergonomic issues for the creation and operation of aeronautical electrified and piloting and navigation complexes of aircraft: Schoolbook, K: KMUGA, 2000, 460 p. (In Russian).
  4. Rogozhin V.O., Sinєglazov V.M., Fіljashkіn M.K. Aircrafts and naval complexes of aircraft: Schoolbook, K.: NAU, 2005, 502 p. (in Ukrainian).
  5. Pavlova S.V., Volkov A.Ye. System of guaranteed resolution of dynamic conflicts of aircrafts in real time. Proc. of the National Aviation Univ.: Scientific journal: scientific article, 2017, 1, P. 29–35.
  6. Grevcov N.M., Efumov O.E., Mel’c I.O. Optimization of aircraft reduction trajectories in the vertical plane: Scientific notes CAGI. T. XXVI, 1995, N3–4, P. 98–110. (In Russian).
  7. Kelley H. J., Cliff E. M. Optimal symmetric flight with intennediate vehicle model. A col1. of tech. papers of the AIAA Guidance and Control Conf. Gut1inburg, Tennessee. Aug. 15–17, 1983.
  8. Zaporozhets O.I., Babeichuk D.G. Application CNS / ATM for effective methods of reducing aircraft noise when the aircraft before boarding, Proceedings of the National Aviation University, 2008, 4, P. 82–88. (in Ukrainian).
  9. Flight Manual. OPS T. 1: Procedures for flight operations. ICAO, Doc.8168-1, 2004, 258 c. (In Russian).
  10. Guidance material on a balanced approach to managing aviation noise. ICAO, Doc 9829 AN/451, 2004, 112 p. (In Russian).
  11. Babak V.P., Babeichuk D.G. Zaporozhets O.I. Model study evaluating environmental benefits uprova-tion cns/atm air traffic control technology. Proceedings of the National Aviation University, 2007, 1, P. 3−9. (in Ukrainian).
  12. Babeichuk D., Zaporozhets O., Helenko Y. Environmental benefits associated with CNS/ATM initiatives. Int. Symp. On air and water pollution abayement, 21−23 June 2007, Zakopane, Poland, P. 207−208.
  13. Babeichuk D., Veklenko O. CNS/ATM support for aircraft noise impact reduction around the airports. Proc. of Third World Congress “Aviation in XXI Century”, 2013, 2, P. 4.21−4.23.

Received 22.09.2017