Transport and Aerospace Engineering

The Theoretical Aspects of Erroneous Actions During the Process of Decision Making by Air Traffic Control evaluates the factors affecting the operational decision-making of a human air traffic controller, interacting in a dynamic environment with the flight crew, surrounding aircraft traffic and environmental conditions of the airspace. This article reviews the challenges of air traffic control in different conditions, ranging from normal and complex to emergency and catastrophic. Workload factors and operating conditions make an impact on air traffic controllers’ decision-making. The proposed model compares various operating conditions within an assumed air traffic control environment subsequently comparing them against a theoretically “perfect” air traffic control system. A mathematical model of flight safety assessment has been proposed for the quantitative assessment of various hazards arising during the process of Air Traffic Control. The model assumes events of various severity and probability ranging from high frequency and low severity up to less likely and catastrophic ones. Certain limitations of the model have been recognised and further improvements for effective hazard evaluation have been suggested.

Atlantic Flight Training. Human Performance and limitation: JAA ATPL training. Neu-Isenburg: Jeppesen, 2004.

C. E. Dole, Flight theory for pilots. 4th ed., Englewood: Jeppesen, 1989.

B. Etkin and L. Duff Reid, Dynamics of flight: stability and control. 3rd ed., Hoboken (N.J.): Wiley, 1996.

ICAO Circular 270-AT/111, Outlook For Air Transport To The Year 2005. Canada, Montreal, Quebec: ICAO, 1997.

A. Urbahs and I. Jonaite, “Features of the use of unmanned aerial vehicles for agriculture applications,” Aviation, 2013, vol. 17, issue 4, pp. 170-175, 2013. https://doi.org/10.3846/16487788.2013.861224

A. Urbahs, V. Petrovs, M. Urbaha, and K. Carjova, “Evaluation of functional landing and taking off characteristics of the hybrid aircraft in comparison with competing hybrid air vehicles,” in Transport Means – Proceedings of the International Conference, Kaunas, 24-25 October, 2013, pp. 246–249.

L. Miķelsons and S. Andersone, “Statistical analysis of the effects of fatigue on pilot aircraft control,” in Proc. The 4th International Scientific and Practical Conference. Transport systems, logistics and engineering – 2016, Riga, 2016, pp. 40–48.

L. Miķelsons, S. Andersone, and V. Šestakovs, “Some theoretical aspects of the error in the decision making process by the ATC,” in Proc. The 4th International Scientific and Practical Conference Transport systems, logistics and engineering – 2016, Riga, 2016, pp. 94–104.

W. Durham, Aircraft flight dynamics and control. Chichester, West Sussex: Wiley, 2013.

P. J. Swatton, The principles of flight for pilots. Chichester, U.K.: John Wiley, 2011. https://doi.org/10.1002/9780470710944

A. Jastrebinskis and V. Šestakovs, “The method for assessing the level of flight safety in airline with small and medium operations,” in Proc. The 4th International Scientific and Practical Conference Transport systems, logistics and engineering – 2016.

B. V. Zubkov, R. V. Sakac, and V. A. Kostjakov, Bezopasnostj poletov. 3 parts, Moscow, 2007. (in Russian)

Ministerstvo Transporta Rossijskoj federacii, “Informacija bezopasnostji poletov No 21.” [Online]. Available: http://szfavt.ru/wp-content/uploads/2013/11/21ibp.pdf. Accessed on: March 18, 2017.

Analiz sostojanija bezopasnosti poletov v grazdanskoi aviacii Rossiskoi Federacii v 2015 godu. [Online]. Available: http://szfavt.ru/wp-content/uploads/Анализ-по-БП-2015-год.pdf Accessed on: March 20, 2017. (in Russian)

M. J. W. Thomas, R. M. Petrilli, and D. Dawson, “An Exploratory Study of Error Detection Processes During Normal Line Operations,” Centre for Applied Behavioural Science, University of South Australia [Online]. Available: http://www.unisanet.unisa.edu.au/staff/MatthewThomas/Paper/Thomas_ErrorDetection.pdf. Accessed on: March 4, 2017.