Influence of various types of information displays on the work capacity of aviation specialists in ergatic systems

Over the past decade more than 70% of all the aviation events have occurred due to the impact of a human factor, meanwhile the reduction of all emergencies should be ensured maintaining the neuro-mental health of aviation personnel. One of the possible functional disorders in the state of the human body is fatigue, which is studied in detail by the International Civil Aviation Organization specialists and described in the publications of the supervision manual over the use of fatigue control mechanisms. Fatigue can result from the long-term work of aviation specialists, whose activities, as a rule, are associated with the use of digital information displays. Within the framework of professional competence, these displays, being a valuable resource, allow aviation staff to perform their duties competently. Nevertheless, displays, distinguishing in various characteristics such as a type of matrix, resolution and the screen diagonal, exert varied influence on the aviation specialist’s working capacity and fatigue formation. Empirical data in the form of average values of the test execution quality, depending on the type of display and its appropriate characteristics, were obtained by means of the software application developed by our team in the C# language in the Unity3D environment and the methodology to assess the reaction rates after a series of experiments. This allowed us to draw up a conclusion that the use of LCD screens with an IPS matrix and a larger screen diagonal is preferable. However, it is worth paying attention to the cutting-edge LED displays, which are characterized by brighter and more saturated colors of the image, in comparison with the mentioned LCD screens, which can be applicable for the specific tasks of aviation personnel.

1. Banks, S., Landon, L.B., Dorrian, J., Waggoner, L.B., Centofanti, S.A., Roma, P.G. & Van Dongen Hans, P.A. (2019). Effects of fatigue on teams and their role in 24/7 operations. Sleep Medicine Reviews, vol. 48. ID: 101216. DOI: 10.1016/j.smrv.2019.101216 (accessed: 25.11.2021).

2. Abd-Elfattah, H.M., Abdelazeim, F.H. & Elshennawy, S. (2015). Physical and cognitive consequences of fatigue: A review. Journal of Advanced Research, vol. 6, issue 3, pp. 351– 358. DOI: 10.1016/j.jare.2015.01.011

3. Wingelaar-Jagt, Y.Q., Wingelaar, T.T., Riedel, W.J. & Ramaekers, J.G. (2021). Fatigue in aviation: Safety risks, preventive strategies and pharmacological interventions. Frontiers in Physiology, vol. 12, ID: 712628. DOI: 10.3389/fphys.2021.712628 (accessed: 25.11.2021).

4. Honn, K.A., Van Dongen Hans, P.A. & Dawson, D. (2019). Working time society consensus statements: Prescriptive rule sets and risk management-based approaches for the management of fatigue-related risk in working time arrangements. Industrial Health, vol. 57, pp. 264–280. DOI: 10.2486/indhealth.SW-8

5. Göker, Z. (2018). Fatigue in the aviation: An overview of the measurements and countermeasures. Journal of Aviation, vol. 2, issue 2, pp. 185–194. DOI: 10.30518/jav.451741

6. Miller, M. & Holley, S. (2021). Air traffic controller resource management: An approach for reducing cognitive loading and increasing situational awareness. Advances in Human Aspects of Transportation. AHFE 2021. Lecture Notes in Networks and Systems, vol. 270, pp. 535–542. DOI: 10.1007/978-3-030-80012-3_61

7. Yevstigneev, D.A. & Torosyan A.A. (2020). Phenomena of emotional tension and stability in air traffic control. V sbornike nauchnykh statey: Psikhologicheskiye issledovaniya v Ulyanovskom institute grazhdanskoy aviatsii, in Yevstigneev D.A. (Ed.). Ulyanovsk: UIGA, pp. 71–82. (in Russian)

8. Yevstigneev, D.A. (2012). Aviation psychology: a textbook for universities. In two volumes. Volume 2. Ulyanovsk: UVAUGA, 220 p. (in Russian).

9. Soldatov, S.K., Zasyadko, K.I., Bogomolov, A.V., Vonarshenko, A.P. & Solomka, A.V. (2017). Professionally important skills of air traffic controllers. Aerospace and Environmental Medicine, vol. 51, no. 1, pp. 30–34. DOI: 10.21687/0233-528X-2017-51-1-30-34 (in Russian)

10. Bulatova, A.E., Evsevichev, D.A., Maksimova, O.V. & Samokhvalov, M.K. (2020). The development of a program for calculating the luminance characteristics of display devices at the air traffic controller’s workplace. Radioelektronnaya tekhnika, no. 1 (13), pp. 202– 206. (in Russian)

11. Bulatova, A.E. & Vvedenskii, A.V. (2021). The usage of informational displays at aviation specialists workplace. Integratsiya nauki, obshchestva, proizvodstva i promyshlennosti: problemy i perspektivy: materialy Mezhdunarodnoy nauchno-prakticheskoy konferentsii. Volgograd, pp. 89–91. (in Russian)

12. Brezonakova, A., Skvarekova, I., Pecho, P., Davies, R., Bugaj, M. & Kandera, B. (2019). The effects of back lit aircraft instrument displays on Pilots fatigue and performance. Transportation Research Procedia, vol. 40, pp. 1273– 1280. DOI: 10.1016/j.trpro.2019.07.177

13. Khalfina, R.R., Galin, M.R. & Minullin, A.Z. (2014). Psychophysiological features of the sensorimotor qualities of employees providing state protection. Uspekhi sovremennogo yestestvoznaniya, no. 11-3, pp. 99–102. (in Russian)

14. Polevshchikov, M.M., Dorogova, Y.A. & Rozhentsov, V.V. (2017). Assessment of reaction to a moving object. Online Scientific & Educational Bulletin Zdorove i Obrazovanie v XXI veke, no. 7, pp. 34–36. Available at: https://cyberleninka.ru/article/n/otsenka-reaktsiina-dvizhuschiysya-obekt/viewer (accessed: 25.11.2021). (in Russian)

15. Smirnova, T.M., Bystritskaya, A.F., Krutko, V.N. & Morozov, V.S. (2005). The system for assessing mental performance as an important indicator of health. Proceedings of the Institute for Systems Analysis Russian Academy of Sciences, no. 13, pp. 170–194. (in Russian)