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Time-based critical infrastructure dependency analysis for large-scale and cross-sectoral failures

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  • Stergiopoulos, George
  • Kotzanikolaou, Panayiotis
  • Theocharidou, Marianthi
  • Lykou, Georgia
  • Gritzalis, Dimitris

Abstract

Dependency analysis of critical infrastructures is a computationally intensive problem when dealing with large-scale, cross-sectoral, cascading and common-cause failures. The problem intensifies when attempting a dynamic, time-based dependency analysis. This paper extends a previous graph-based risk analysis methodology to dynamically assess the evolution of cascading failures over time. Various growth models are employed to capture slow, linear and rapidly evolving effects, but instead of using static projections, the evolution of each dependency is “objectified” by a fuzzy system that also considers the effects of nearby dependencies. To achieve this, the impact (and, eventually, risk) of each dependency is quantified on the time axis into a form of many-valued logic. In addition, the methodology is extended to analyze major failures triggered by concurrent common-cause cascading events. A critical infrastructure dependency analysis tool, CIDA, that implements the extended risk-based methodology is described. CIDA is designed to assist decision makers in proactively analyzing dynamic and complex dependency risk paths in two ways: (i) identifying potentially underestimated low risk dependencies and reclassifying them to a higher risk category before they are realized; and (ii) simulating the effectiveness of alternative mitigation controls with different reaction times. Thus, the CIDA tool can be used to evaluate alternative defense strategies for complex, large-scale and multi-sectoral dependency scenarios and to assess their resilience in a cost-effective manner.

Suggested Citation

  • Stergiopoulos, George & Kotzanikolaou, Panayiotis & Theocharidou, Marianthi & Lykou, Georgia & Gritzalis, Dimitris, 2016. "Time-based critical infrastructure dependency analysis for large-scale and cross-sectoral failures," International Journal of Critical Infrastructure Protection, Elsevier, vol. 12(C), pages 46-60.
  • Handle: RePEc:eee:ijocip:v:12:y:2016:i:c:p:46-60
    DOI: 10.1016/j.ijcip.2015.12.002
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    References listed on IDEAS

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    4. Petar Radanliev & David Roure & Max Kleek & Uchenna Ani & Pete Burnap & Eirini Anthi & Jason R. C. Nurse & Omar Santos & Rafael Mantilla Montalvo & La’Treall Maddox, 2021. "Dynamic real-time risk analytics of uncontrollable states in complex internet of things systems: cyber risk at the edge," Environment Systems and Decisions, Springer, vol. 41(2), pages 236-247, June.
    5. Giada Feletti & Mariachiara Piraina & Boris Petrenj & Paolo Trucco, 2022. "Collaborative capability building for critical infrastructure resilience: assessment and selection of good practices," Environment Systems and Decisions, Springer, vol. 42(2), pages 207-233, June.

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