Integrated Security Analysis on Cascading Failure in Complex Networks
Title | Integrated Security Analysis on Cascading Failure in Complex Networks |
Publication Type | Journal Article |
Year of Publication | 2014 |
Authors | Jun Yan, Haibo He, Yan Sun |
Journal | Information Forensics and Security, IEEE Transactions on |
Volume | 9 |
Pagination | 451-463 |
Date Published | March |
ISSN | 1556-6013 |
Keywords | Analytical models, cascading failure, Complex network security, complex networks, extended topological analysis, extended topological metric, integrated security analysis, network security perspective, power grid components, power grids, power system faults, Power system protection, power transfer distribution factor-based model, security, security of data, standard IEEE 118-bus test system, structural vulnerability, Topology |
Abstract | The security issue of complex networks has drawn significant concerns recently. While pure topological analyzes from a network security perspective provide some effective techniques, their inability to characterize the physical principles requires a more comprehensive model to approximate failure behavior of a complex network in reality. In this paper, based on an extended topological metric, we proposed an approach to examine the vulnerability of a specific type of complex network, i.e., the power system, against cascading failure threats. The proposed approach adopts a model called extended betweenness that combines network structure with electrical characteristics to define the load of power grid components. By using this power transfer distribution factor-based model, we simulated attacks on different components (buses and branches) in the grid and evaluated the vulnerability of the system components with an extended topological cascading failure simulator. Influence of different loading and overloading situations on cascading failures was also evaluated by testing different tolerance factors. Simulation results from a standard IEEE 118-bus test system revealed the vulnerability of network components, which was then validated on a dc power flow simulator with comparisons to other topological measurements. Finally, potential extensions of the approach were also discussed to exhibit both utility and challenge in more complex scenarios and applications. |
DOI | 10.1109/TIFS.2014.2299404 |
Citation Key | 6708453 |
- power grids
- Topology
- structural vulnerability
- standard IEEE 118-bus test system
- security of data
- security
- power transfer distribution factor-based model
- Power system protection
- power system faults
- Analytical models
- power grid components
- network security perspective
- integrated security analysis
- extended topological metric
- extended topological analysis
- complex networks
- Complex network security
- cascading failure