Development of informationally-protected system of marine water area monitoring

Authors

DOI:

https://doi.org/10.15587/1729-4061.2017.118851

Keywords:

information protection, monitoring of marine water areas, data transmission network, telecommunication system

Abstract

We report results of analysis of the systems of protection and monitoring of the situation at marine and coastal facilities, information, which is processed and transmitted via communication channels in information and telecommunication systems at facilities of marine infrastructure. The threats for information that circulates in different environments of functioning of the monitoring systems, models of possible intruders of different categories regarding possibilities of threats’ realization were identified. By analyzing the signal’s passing processes and the structure of the monitoring system, the types of information, which is processed in it, were determined. Taking into account the identified threats and conditions of functioning of the telecommunication network, the methods of information security of the monitoring system were selected. We proposed the generalizing index of security state and the technique for its calculation, which forms the mathematical basis for setting security goals and objectives, determining of criteria for evaluation of quality of construction and operation implementation of a complex information security system. Research results are aimed at developing, improvement of information security complexes in the networks of data transmission in systems for monitoring of marine and coastal facilities, improvement of effectiveness of measures for technical and cryptographic information security. Presented results provide baseline data for determining of directions of information leakage countermeasures, principles of organization of information security, provision of increased security levels for facilities of marine infrastructure

Author Biography

Oleksandr Blintsov, Admiral Makarov National University of Shipbuilding Heroiv Ukrainy ave., 9, Mykolaiv, Ukraine, 54025

Doctor of Tehcnical Sciences, Associate Professor

Department of Electrical Equipment of Ships and Information Security

References

  1. Blintsov, V. S., Kyryziuk, O. M., Krasnykh, O. V., Yakymiak, S. V. (2012). Bezekipazhna viyskovo-morska tekhnika – stan ta osnashchennia VMS ZS Ukrainy. Nauka i oborona, 4, 61–64.
  2. Lipkan, V. A. (2003). Informatsiyna bezpeka yak skladova natsionalnoi bezpeky Ukrainy. Informatsiyni tekhnolohiy v ekonomitsi, menedzhmenti i biznesi: Problemy nauky, praktyky i osvity. Zb. nauk. prats VIII Mizhnar. nauk.-prakt. konf. Kyiv: Vyd-vo Yevrop. un-tu, 443–453.
  3. Pocheptsov, G. G. (2000). Kommunikativnye tekhnologii dvadtsatogo veka. Moscow: Refl-buk; Kyiv: Vakler, 352.
  4. Kormych, V. A. (2004). Informatsiyna bezpeka Ukrainy: orhanizatsiyno-pravovi osnovy. Kyiv: Kondor, 384.
  5. Dergausov, M. M. (2000). Ukraina – derzhava morskaya. Donetsk: Izd-vo "Donechchina", 269.
  6. Rabynovych, P. M. (1994). Osnovy zahalnoi teoriy prava i derzhavy. Kyiv, 236.
  7. Kolodiy, A. M., Kopeichykov, V. V., Lysenkov, S. L. et. al.; Lysenkov, S. L., Kopeichykov, V. V. (Eds.) (2003). Teoriya derzhavy ta prava. Kyiv: Yurinkom Inter, 368.
  8. Anderson, B., Kleiner, A. (2014). Autonomous Surface Vehicles for Arctic Data Collection. OTC Arctic Technology Conference. doi: 10.4043/24556-ms
  9. Field, M., Beguery, L., Oziel, L., Gascard, J. C. (2015). Barents Sea monitoring with a SEA EXPLORER glider. OCEANS 2015 – Genova. doi: 10.1109/oceans-genova.2015.7271540
  10. Heo, J., Kim, J., Kwon, Y. (2017). Analysis of Design Directions for Unmanned Surface Vehicles (USVs). Journal of Computer and Communications, 05 (07), 92–100. doi: 10.4236/jcc.2017.57010
  11. Secrieru, D., Oaie, G., Radulescu, V., Voicaru, C. (2015). The Black Sea Security System – A New Early Warning and Environmental Monitoring System. Sustainable Development of Sea-Corridors and Coastal Waters, 109–115. doi: 10.1007/978-3-319-11385-2_12
  12. Kosai, S., Unesaki, H. (2016). Conceptualizing maritime security for energy transportation security. Journal of Transportation Security, 9 (3-4), 175–190. doi: 10.1007/s12198-016-0173-2
  13. Klimkowska, A., Lee, I., Choi, K. (2016). Possibilities of UAS for maritime monitoring. ISPRS – International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, XLI-B1, 885–891. doi: 10.5194/isprsarchives-xli-b1-885-2016
  14. De Sousa, J. B., McGuillivary, P., Vicente, J., Bento, M. N., Morgado, J. A. P., Matos, M. M. et. al. (2014). Unmanned Aircraft Systems for Maritime Operations. Handbook of Unmanned Aerial Vehicles, 2787–2811. doi: 10.1007/978-90-481-9707-1_75
  15. Marques, M. M., Dias, P., Santos, N. P., Lobo, V., Batista, R., Salgueiro, D. et. al. (2015). Unmanned aircraft systems in maritime operations: Challenges addressed in the scope of the SEAGULL project. OCEANS 2015 – Genova. doi: 10.1109/oceans-genova.2015.7271427

Downloads

Published

2017-12-25

How to Cite

Blintsov, O., & Maidaniuk, P. (2017). Development of informationally-protected system of marine water area monitoring. Eastern-European Journal of Enterprise Technologies, 6(9 (90), 10–16. https://doi.org/10.15587/1729-4061.2017.118851

Issue

Section

Information and controlling system