Distributed and optimal resilient planning of large-scale interdependent critical infrastructures
Pages 1096 - 1107
Abstract
The complex interconnections between various critical infrastructure sectors make the system of systems (SoS) vulnerable to failures and highlight the importance of robustness and resilience. To this end, we first establish holistic probabilistic networks to model the interdependencies between infrastructure components. To capture the underlying failure and recovery dynamics, we further propose a Markov decision processes (MDP) model in which the response policy determines a long-term performance. To address the challenge of a large dimensionality, we exploit the sparsity of the network interconnections and solve an approximate linear program by the variable elimination, which leads to a distributed control policy under mild assumptions. Finally, we use a case study of the interdependent power and subway systems to corroborate the results and show that the optimal resilience resource planning and allocation can reduce the failure probability and mitigate the impact of failures caused by natural or artificial disasters.
References
[1]
Chen, J., C. Touati, and Q. Zhu. 2017. "A Dynamic Game Analysis and Design of Infrastructure Network Protection and Recovery". ACM SIGMETRICS Performance Evaluation Review 45(2):125--128.
[2]
Farias, D., and D. Pucci. 2002. The Linear Programming Approach to Approximate Dynamic Programming: Theory and Application. Ph. D. thesis, Stanford University.
[3]
Gao, J., D. Li, and S. Havlin. 2014. "From a Single Network to a Network of Networks". National Science Review 1(3):346--356.
[4]
Guestrin, C., D. Koller, R. Parr, and S. Venkataraman. 2003, October. "Efficient Solution Algorithms for Factored MDPs". Journal of Artificial Intelligence Research 19(1):399--468.
[5]
Hayel, Y., and Q. Zhu. 2015. "Resilient and Secure Network Design for Cyber Attack-induced Cascading Link Failures in Critical Infrastructures". In Proceedings of the 2015 49th Annual Conference on Information Sciences and Systems (CISS), 1--3. IEEE.
[6]
Huang, L., J. Chen, and Q. Zhu. 2017a, April. "A Factored MDP Approach to Optimal Mechanism Design for Resilient Large-Scale Interdependent Critical Infrastructures". In Proceedings of the 2017 Workshop on Modeling and Simulation of Cyber-Physical Energy Systems (MSCPES), 1--6. IEEE.
[7]
Huang, L., J. Chen, and Q. Zhu. 2017b. "A Large-Scale Markov Game Approach to Dynamic Protection of Interdependent Infrastructure Networks". In Proceedings of the International Conference on Decision and Game Theory for Security, edited by S. e. a. Rass, 357--376. Cham: Springer.
[8]
Kwasinski, A. 2013. "Lessons from Field Damage Assessments about Communication Networks Power Supply and Infrastructure Performance during Natural Disasters with a Focus on Hurricane Sandy". In FCC Workshop on Network Resiliency 2013, Volume 2013.
[9]
Lee II, E. E., J. E. Mitchell, and W. A.Wallace. 2007. "Restoration of Services in Interdependent Infrastructure Systems: A Network Flows Approach". IEEE Transactions on Systems, Man, and Cybernetics, Part C (Applications and Reviews) 37(6):1303--1317.
[10]
Obama, B. 2013. "Presidential Policy Directive 21: Critical Infrastructure Security and Resilience". Washington, DC.
[11]
Ouyang, M. 2014. "Review on Modeling and Simulation of Interdependent Critical Infrastructure Systems". Reliability engineering & System safety 121:43--60.
[12]
Rinaldi, S. M., J. P. Peerenboom, and T. K. Kelly. 2001. "Identifying, Understanding, and Analyzing Critical Infrastructure Interdependencies". IEEE Control Systems 21(6):11--25.
[13]
Rosato, V., L. Issacharoff, F. Tiriticco, S. Meloni, S. Porcellinis, and R. Setola. 2008. "Modelling Interdependent Infrastructures Using Interacting Dynamical Models". International Journal of Critical Infrastructures 4(1--2):63--79.
[14]
Wang, X., N. Hovakimyan, and L. Sha. 2013, April. "L1Simplex: Fault-tolerant Control of Cyber-physical Systems". In Proceedings of the 2013 ACM/IEEE International Conference on Cyber-Physical Systems (ICCPS), 41--50. IEEE.
[15]
Yuan, Y., F. Sun, and Q. Zhu. 2015. "Resilient Control in the Presence of DoS Attack: Switched System Approach". International Journal of Control, Automation and Systems 13(6):1423--1435.
[16]
Zhu, Q., and T. Basar. 2015. "Game-theoretic Methods for Robustness, Security, and Resilience of Cyberphysical Control Systems: Games-in-games Principle for Optimal Cross-layer Resilient Control Systems". IEEE Control Systems 35(1):46--65.
[17]
Zimmerman, R., Q. Zhu, F. de Leon, and Z. Guo. 2017. "Conceptual Modeling Framework to Integrate Resilient and Interdependent Infrastructure in Extreme Weather". Journal of Infrastructure Systems 23(4):04017034.
[18]
Zimmerman, R., Q. Zhu, and C. Dimitri. 2016. "Promoting Resilience for Food, Energy, and Water Interdependencies". Journal of Environmental Studies and Sciences 6(1):50--61.
[19]
Zimmerman, R., Q. Zhu, and C. Dimitri. 2018. "A Network Framework for Dynamic Models of Urban Food, Energy and Water systems (FEWS)". Environmental Progress & Sustainable Energy 37(1):122--131.
Recommendations
Evaluation of network expansion decisions for resilient interdependent critical infrastructures with different topologies
AbstractResilient interdependent critical infrastructures (CIs) can better withstand cascading failures in disruptive events. This study proposes network expansion as a resilience improvement strategy for interdependent CIs and evaluates the influence of ...
Resilient routing layers for network disaster planning
ICN'05: Proceedings of the 4th international conference on Networking - Volume Part IIMost research on network recovery has been centered around two common assumptions regarding failure characteristics: Failures do not occur simultaneously and failures do mostly strike links. Even this may be the characteristics of everyday failures, we ...
Optimal Recovery from Large-Scale Failures in IP Networks
ICDCS '12: Proceedings of the 2012 IEEE 32nd International Conference on Distributed Computing SystemsQuickly recovering IP networks from failures is critical to enhancing Internet robustness and availability. Due to their serious impact on network routing, large-scale failures have received increasing attention in recent years. We propose an approach ...
Comments
Please enable JavaScript to view thecomments powered by Disqus.Information & Contributors
Information
Published In
Sponsors
Publisher
IEEE Press
Publication History
Published: 09 December 2018
Check for updates
Qualifiers
- Research-article
Conference
WSC '18
Sponsor:
Acceptance Rates
WSC '18 Paper Acceptance Rate 183 of 260 submissions, 70%;
Overall Acceptance Rate 3,413 of 5,075 submissions, 67%
Contributors
Other Metrics
Bibliometrics & Citations
Bibliometrics
Article Metrics
- 0Total Citations
- 36Total Downloads
- Downloads (Last 12 months)2
- Downloads (Last 6 weeks)0
Reflects downloads up to 14 Nov 2024
Other Metrics
Citations
View Options
Get Access
Login options
Check if you have access through your login credentials or your institution to get full access on this article.
Sign in