Conceptual model of critical infrastructures resilience in the context of modern theory of complex system security

the study was carried out within the framework of the State Research Program of the Institute for Informatics and Mathematical Modeling of the Kola Science Centre of RAS (project No. 0226- 2019-0035). Scientific justification of developments application for critical infrastructure resilience analysis of the Northern Sea Route was partially sponsored by the Russian Foundation for Basic Research under grant No. 18-07- 00167.

Authors

  • Andrey V. Masloboev Institute for Informatics and Mathematical Modeling of the Federal Research Centre «Kola Science Centre of the Russian Academy of Sciences»
  • Vitaly V. Bystrov Institute for Informatics and Mathematical Modeling of the Federal Research Centre «Kola Science Centre of the Russian Academy of Sciences»

DOI:

https://doi.org/10.18413/2687-0932-2020-43-3-555-572

Keywords:

critical infrastructure, resilience, control system, formalization, conceptual model, socio-economic security

Abstract

The research work proposes modern theory development of complex system security and its application range extension to the class of critical infrastructures for system interrelations and regularities analysis, which define critical infrastructure resilience under uncertainty and risk impacts. The survey of problems and state-of-theart issues in the field of critical infrastructure resilience support in Russia and abroad is carried out. Critical infrastructure resilience conceptual model based on functional-target approach and control theory is developed. Within the bounds of model the concept formalization of «critical infrastructure» and «resilience», which specify the content of this research field and objective by new formal constructions, is proposed. That allows formal apparatus extension of system security theory and makes it more constructive. Proposed formal representation provides the basis for general problem statement formalization of the critical infrastructure
resilience management and conceptual model design of the control system of critical infrastructure resilience.

Downloads

Download data is not yet available.

Author Biographies

Andrey V. Masloboev, Institute for Informatics and Mathematical Modeling of the Federal Research Centre «Kola Science Centre of the Russian Academy of Sciences»

Doctor of Technical Sciences, Associate Professor, Leading Researcher in Department of Information Technologies for Regional Development Management, Institute for Informatics and Mathematical Modeling of the Federal Research Center “Kola Science Center of the Russian Academy of Sciences”,

Apatity, Russia

Vitaly V. Bystrov, Institute for Informatics and Mathematical Modeling of the Federal Research Centre «Kola Science Centre of the Russian Academy of Sciences»

Candidate of Technical Sciences, Senior Researcher in Department of Information Technologies for Regional Development Management, Institute for Informatics and Mathematical Modeling of the Federal Research Center “Kola Science Center of the Russian Academy of Sciences”,

Apatity, Russia

References

Добровольский В.С. 2015. Проблемы и особенности обеспечения безопасности и защиты от чрезвычайных ситуаций объектов экономики. Проблемы безопасности и чрезвычайных ситуаций, 1: 87–98.

Горошко И.В., Бондаренко Ю.В. 2015. Согласование социальных и экономических показателей развития региона: понятие и механизмы. Проблемы управления, 1: 63–72.

Гутман С.С., Басова А.А. 2017. Индикаторы устойчивого развития Арктической зоны Российской Федерации: проблемы выбора и измерения. Арктика: экология и экономика. 4 (28): 32–48.

Маслобоев А.В., Путилов В.А. 2016. Информационное измерение региональной безопасности в Арктике. Апатиты, КНЦ РАН, 222.

Месарович М., Мако Д., Такахара И. 1973. Теория иерархических многоуровневых систем. М., Мир, 343.

Михалевич И.Ф., Рыжов А.П. 2018. Оценка устойчивости развития критической инфраструктуры Российской Федерации на базе технологии оценки и мониторинга информационной безопасности. Интеллектуальные системы. Теория и приложения. 2 (22): 7–18.

О Стратегии национальной безопасности Российской Федерации (Указ Президента РФ от 31 декабря 2015 г. N 683). [Электронный ресурс] URL: http://kremlin.ru/acts/bank/40391.

О Стратегии экономической безопасности Российской Федерации на период до 2030 года (Указ Президента РФ от 13.05.2017 г. № 208). [Электронный ресурс] URL: http://kremlin.ru/acts/bank/41921.

Соложенцев Е.Д. 2015. Логико-вероятностное управление риском состояния и развития социально-экономических систем и процессов. Проблемы анализа риска, 12 (1): 6–16.

Цыгичко В.Н., Черешкин Д.С., Смолян Г.Л. 2018. Безопасность критических инфраструктур. М., Красанд, 200.

Шульц В.Л., Кульба В.В., Шелков А.Б., Чернов И.В. 2015. Сценарный анализ в управлении геополитическим информационным противоборством. М., Наука, 542.

Aldrich P.A., Meyer M.A. 2015. Social Capital and Community Resilience. American Behavioral Scientist, 59 (2): 254–269.

Ahert J. 2011. From fail-safe to safe-to-fail: Sustainability and resilience in the new urban world. Landscape and Urban Planning, 100 (4): 341–343.

ANSI/ASIS 2009. Organizational Resilience: Security, Preparedness, and Continuity Management Systems - Requirements with Guidance for Use. ANSI/ASIS.SPC.1:2009. [Электронный ресурс] URL: https://www.ndsu.edu/fileadmin/emgt/ASIS_SPC.1-2009_Item_No._1842.pdf.

Bearse R. 2014. The Return on Investing in Personal resilience. The CIP Report. Center for Infrastructure Protection and Homeland Security, 12 (7): 21–24.

BRT - Benchmark Resilience Tool. 2019. [Электронный ресурс] URL: https://www.resorgs.org.nz/resources/organisational-resilience-publications.

Bertocchi G., Bologna S., Carducci G., Carrozzi L., Cavallini S., Lazari A., Oliva G., Traballesi A. 2016. Guidelines for Critical Infrastructures Resilience Evaluation. Associazione Italiana esperti Infrastrutture Critiche (AIIC) - Italian Association of Critical Infrastructures Experts. Technical Report. DOI: 10.13140/RG.2.1.4814.6167.

Björck F., Henkel M., Stirna J., Zdravkovic J. 2015. Cyber Resilience - Fundamentals for a Definition. Advances in Intelligent Systems and Computing, 353: 311–316.

Cassotta S., Sidortsov R., Pursiainen C., Goodsite M.E. 2019. Cyber Threats, Harsh Environment and the European High North (EHN) in a Human Security and Multi-Level Regulatory Global Dimension: Which Framework Applicable to Critical Infrastructures under «Exceptionally Critical Infrastructure Conditions» (ECIC)?. Beijing Law Review, 10: 317–360.

European Council. 2008. Council Directive 2008/114/EC of 8 December 2008 on the identification and designation of European critical infrastructures and the assessment of the need to improve their protection. [Электронный ресурс] URL: https://eur-lex.europa.eu/LexUriServ/LexUriServ.do?uri=OJ:L:2008:345: 0075:0082:EN:PDF.

Flynn S.E. 2008. America the Resilient: Defying Terrorism and Mitigating Natural Disasters. Foreign Affairs, 83 (2): 2–8.

Hollnagel E. 2014. Safety-I and Safety-II. The Past and Future of Safety Management. Ashgate, England, 187.

Holling C.S. 1973. Resilience and stability of ecological systems. Annual Review of Ecology and Systematics, 4 (1): 1–23.

Labaka, L., Hernantes, J., Sarriegi J.M. 2015. Resilience framework for Critical Infrastructures: An Empirical Study in a Nuclear Plant. Reliability Engineering and System Safety, 141: 92–105.

Lee A.V., Vargo J., Seville E. 2013. Developing a Tool to Measure and Compare Organizations’ Resilience. Natural Hazards Review, 14 (1): 29–41.

Petersen L. et al. 2016. Social resilience criteria for critical infrastructures during crises. IMPROVER D4.1. [Электронный ресурс] URL: www.improverproject.eu.

Pursiainen C.H., Rød B., Baker G., Honfi D., Lange D. 2017. Critical Infrastructure Resilience Index: in book «Risk, Reliability and Safety: Innovating Theory and Practice». CRC Press, 2183–2189.

Righi A.W., Saurin T.A., Wachs, P. 2015. A systematic literature review of resilience engineering: Research areas and a research agenda proposal. Reliability Engineering and System Safety, 141: 142–152.

SEI. 2013. Arctic Resilience Interim Report. Stockholm Environment Institute and the Stockholm Resilience Centre. [Электронный ресурс] URL: https://mediamanager.sei.org/documents/Publications/ArcticResilienceInterimReport2013-LowRes.pdf.

UNISDR/UNDRR (n.d.). Terminology on disaster risk reduction. [Электронный ресурс] URL: https://www.unisdr.org/we/inform/terminology.

Wang C., Blackmore J. 2009. Resilience Concepts for Water Resource Systems. Journal of Water Resources Planning and Management, 135 (6): 528–536.

Youn B.D., Hu. C., Wang P. 2011. Resilience-driven System Design of Complex Engineered Systems. Journal of Mech Design, 133 (10): 10108–10110.


Abstract views: 566

Share

Published

2020-10-30

How to Cite

Masloboev, A. V., & Bystrov, V. V. (2020). Conceptual model of critical infrastructures resilience in the context of modern theory of complex system security: the study was carried out within the framework of the State Research Program of the Institute for Informatics and Mathematical Modeling of the Kola Science Centre of RAS (project No. 0226- 2019-0035). Scientific justification of developments application for critical infrastructure resilience analysis of the Northern Sea Route was partially sponsored by the Russian Foundation for Basic Research under grant No. 18-07- 00167. Economics. Information Technologies, 47(3), 555-572. https://doi.org/10.18413/2687-0932-2020-43-3-555-572

Issue

Section

COMPUTER SIMULATION HISTORY