Flow-based vulnerability measures for network component importance: Experimentation with preparedness planning

Charles D. Nicholson; Kash Barker; Jose E. Ramirez-Marquez

doi:10.1016/j.ress.2015.08.014

Flow-based vulnerability measures for network component importance: Experimentation with preparedness planning

Charles D. Nicholson, Kash Barker, Jose E. Ramirez-Marquez

Department of Systems and Enterprises

University of Oklahoma

Research output: Contribution to journal › Article › peer-review

93 Scopus citations

Abstract

This work develops and compares several flow-based vulnerability measures to prioritize important network edges for the implementation of preparedness options. These network vulnerability measures quantify different characteristics and perspectives on enabling maximum flow, creating bottlenecks, and partitioning into cutsets, among others. The efficacy of these vulnerability measures to motivate preparedness options against experimental geographically located disruption simulations is measured. Results suggest that a weighted flow capacity rate, which accounts for both (i) the contribution of an edge to maximum network flow and (ii) the extent to which the edge is a bottleneck in the network, shows most promise across four instances of varying network sizes and densities.

Original language	English
Pages (from-to)	62-73
Number of pages	12
Journal	Reliability Engineering and System Safety
Volume	145
DOIs	https://doi.org/10.1016/j.ress.2015.08.014
State	Published - 1 Jan 2016

Keywords

Flow
Networks
Resilience
Vulnerability

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title = "Flow-based vulnerability measures for network component importance: Experimentation with preparedness planning",

abstract = "This work develops and compares several flow-based vulnerability measures to prioritize important network edges for the implementation of preparedness options. These network vulnerability measures quantify different characteristics and perspectives on enabling maximum flow, creating bottlenecks, and partitioning into cutsets, among others. The efficacy of these vulnerability measures to motivate preparedness options against experimental geographically located disruption simulations is measured. Results suggest that a weighted flow capacity rate, which accounts for both (i) the contribution of an edge to maximum network flow and (ii) the extent to which the edge is a bottleneck in the network, shows most promise across four instances of varying network sizes and densities.",

keywords = "Flow, Networks, Resilience, Vulnerability",

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N2 - This work develops and compares several flow-based vulnerability measures to prioritize important network edges for the implementation of preparedness options. These network vulnerability measures quantify different characteristics and perspectives on enabling maximum flow, creating bottlenecks, and partitioning into cutsets, among others. The efficacy of these vulnerability measures to motivate preparedness options against experimental geographically located disruption simulations is measured. Results suggest that a weighted flow capacity rate, which accounts for both (i) the contribution of an edge to maximum network flow and (ii) the extent to which the edge is a bottleneck in the network, shows most promise across four instances of varying network sizes and densities.

AB - This work develops and compares several flow-based vulnerability measures to prioritize important network edges for the implementation of preparedness options. These network vulnerability measures quantify different characteristics and perspectives on enabling maximum flow, creating bottlenecks, and partitioning into cutsets, among others. The efficacy of these vulnerability measures to motivate preparedness options against experimental geographically located disruption simulations is measured. Results suggest that a weighted flow capacity rate, which accounts for both (i) the contribution of an edge to maximum network flow and (ii) the extent to which the edge is a bottleneck in the network, shows most promise across four instances of varying network sizes and densities.

KW - Flow

KW - Networks

KW - Resilience

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Flow-based vulnerability measures for network component importance: Experimentation with preparedness planning

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Keywords

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