Electromagnetic interference issue in safety systems applied at airports

• Autorzy: Siergiejczyk Mirosław , Rosiński Adam , Paś Jacek

Identyfikatory

DOI

10.2478/jok-2019-0015

• Języki publikacji: EN

Abstrakty

EN

The proper operation of electronic devices used in transport facilities is possible by protecting them against the effect of adverse electromagnetic fields. At present, all kinds of facilities, including critical infrastructure facilities, intended for functioning in peace conditions and emergency states, are equipped with power systems and numerous electronic devices, including electronic safety systems. On the basis of observing the process of their operation, it can be concluded that an artificially generated intended or unintended electromagnetic field, within various frequency ranges, may negatively affect the operation of electronic devices. It was found that the operation of the electronic safety systems applied at airports may be subject to interference as a result of the impact of adverse electromagnetic fields. Therefore, it is necessary to analyse the impact of electromagnetic interference on the operation of these systems. This article presents a developed author’s operation process model including electromagnetic interference within low frequencies. The reliability and operation analysis of the electronic safety systems carried out by the authors allows for numerical assessment of various types of solutions-both technical and organisational ones. As a result, they can be implemented, in order to minimise the impact of electromagnetic interference on the system functioning. This is a new approach to this issue, as there are currently designed and installed security systems at airports, but there is no analysis of the impact of electromagnetic interference on their functioning. In further research concerning this issue, the authors plan to further develop reliability-operational models, which will differentiate between the states of partial fitness. It will allow for more accurate mapping of the operation of the electronic safety systems which are applicable at airports.

Słowa kluczowe

EN

operation; electromagnetic interference; safety systems; modeling

• Wydawca: Wydawnictwo Instytutu Technicznego Wojsk Lotniczych
• Czasopismo: Journal of KONBiN
• Rocznik: 2019
• Tom: Vol. 49, iss. 1
• Strony: 299--312
• Opis fizyczny: Bibliogr. 24 poz., rys.

Twórcy

autor

Siergiejczyk Mirosław

• Warsaw University of Technology (Politechnika Warszawska)

autor

Rosiński Adam

• Warsaw University of Technology (Politechnika Warszawska)

autor

Paś Jacek

• Military University of Technology (Wojskowa Akademia Techniczna)

Bibliografia

• 1. Burdzik R., Konieczny Ł., Figlus T.: Concept of on-board comfort vibration monitoring system for vehicles. In: Activities of Transport Telematics, TST 2013. Springer, Heidelberg 2013.
• 2. Charoy A.: Interference in electronic equipment. WNT, Warsaw 1999.
• 3. Dabrowski T., Bednarek M., Fokow K., Wisnios M.: The method of threshold-comparative diagnosing insensitive on disturbances of diagnostic signals. Przeglad Elektrotechniczny-Electrical Review, Vol. 88, Issue: 11A, 2012.
• 4. Duer S., Zajkowski K., Płocha I., Duer R.: Training of an artificial neural network in the diagnostic system of a technical object. Neural Computing & Applications 2013. Vol. 22, No. 7. DOI 10.1007/s00521-012-1052-9.
• 5. Kasprzyk Z., Rychlicki M.: Analysis of phiysical layer model of WLAN 802.11g data transmission protocol in wireless networks used by telematic systems. In: Proceedings of the Ninth International Conference Dependability and Complex Systems DepCoS-RELCOMEX. Given as the monographic publishing series-„Advances in intelligent systems and computing”. Vol. 286. Springer, 2014.
• 6. Kierzkowski, A. & Kisiel, T. Simulation model of security control system functioning: A case study of the Wroclaw Airport terminal. Journal of Air Transport Management. 2017. Vol. 64. Part B. P. 173-185. DOI 10.1016/j.jairtraman.2016.09.008.
• 7. Kierzkowski A., Kisiel T.: Airport security screeners reliability analysis. In: Proceedings of the IEEE International Conference on Industrial Engineering and Engineering Management IEEM 2015. Singapore 2015.
• 8. Kovář S., Valouch J., Urbančoková H., Adámek M.: Electromagnetic interference of CCTV. In: International Conference on Information and Digital Technologies 2015. Zilina, Slovakia. DOI 10.1109/DT.2015.7222968.
• 9. Kovář S., Valouch J., Urbančoková H., Adámek M.: Impact of security cameras on electromagnetic environment in far and near-field. In: International Conference on Information and Digital Technologies (IDT) 2016. Rzeszow, Poland. DOI 10.1109/DT.2016.7557166.
• 10. Kozuba J., Sarnowski W.: Logistical process in military aviation organization, Scientific Journal of Silesian University of Technology. Series Transport 2017, Vol. 94. DOI 10.20858/sjsutst.2017.94.8
• 11. Lheurette E. (ed.): Metamaterials and Wave Control. ISTE and Wiley, 2013.
• 12. Łubkowski P., Laskowski D.: Selected issues of reliable identification of object in transport systems using video monitoring services. In: Communication in Computer and Information Science. Springer Berlin Heidelberg, Switzerland. Vol. 471, 2015, DOI 10.1007/978-3-662-45317-9_7.
• 13. Młyńczak J., Hejczyk T., Wszołek B., Gałuszka A., Surma D., Ogaza R., Burdzik R.: Passenger safety and information module in intelligent integrated traffic management system. Vibroengineering PROCEDIA Vol. 6, 2015.
• 14. NO-04-A004-9:2016. Obiekty wojskowe-Systemy alarmowe-Część 9: Wymagania dotyczące monitorowania alarmów. Warszawa: Wojskowe Centrum Normalizacji. [In Polish: Military installations-Alarm systems-Part 9: Requirements concerning monitoring of alarms. Warsaw: Military Centre for Standardization.]
• 15. Ott H.W.: Electromagnetic compatibility engineering. Wiley, 2009.
• 16. Paszek J., Kaniewski P.: Simulation of random errors of inertial sensors. In: 13th International Conference on Modern Problems of Radio Engineering, Telecommunications and Computer Science (TCSET). Lviv-Slavske, Ukraine, 2016.
• 17. PN-EN 50131-1:2009. Systemy alarmowe-Systemy sygnalizacji włamania i napadu-Część 1: Wymagania systemowe. Warszawa: Polski Komitet Normalizacyjny. [In Polish: Alarm systems-Intrusion and hold-up systems-Part 1: System requirements. Warsaw: Polish Committee of Standardization.]
• 18. Siergiejczyk M., Paś J., Rosiński A.: Issue of reliability-exploitation evaluation of electronic transport systems used in the railway environment with consideration of electromagnetic interference. IET Intelligent Transport Systems. 2016. 10 (9), DOI 10.1049/iet-its.2015.0183.
• 19. Skorupski J., Uchroński P.: Fuzzy Inference System for the Efficiency Assessment of Hold Baggage Security Control at the Airport. Safety Science Vol. 79, 2015. DOI 10.1016/j.ssci.2015.06.020.
• 20. Skorupski J., Uchroński P.: Managing the Process of Passenger Security Control at an Airport Using the Fuzzy Inference System. Expert Systems With Applications, Vol. 54, 2016. DOI 10.1016/j.eswa.2015.11.014.
• 21. Stawowy M.: Model for information quality determination of teleinformation systems of transport. In: Proceedings of the European Safety and Reliability Conference ESREL 2014. CRC Press/Balkema, 2015.
• 22. Stawowy M., Kasprzyk Z.: Identifying and simulation of status of an ICT system using rough sets. In: Proceedings of the Tenth International Conference on Dependability and Complex Systems DepCoS-RELCOMEX. Given as the monographic publishing series-Advances in intelligent systems and computing. Vol. 365. Springer, 2015. DOI 10.1007/978-3-319-19216-1_45.
• 23. Urbančoková H., Valouch J., Adámek M.: Testing of an Intrusion and Hold-up Systems for Electromagnetic Susceptibility-EFT/B. International Journal Of Circuits, Systems And Signal Processing, Vol. 9, 2015.
• 24. Valouch J.: Technical requirements for Electromagnetic Compatibility of Alarm Systems. International Journal Of Circuits, Systems And Signal Processing, Vol. 9, 2015.