Structure Entropy and Resistor Graphs
Abstract
We propose the notion of {\it resistance of a graph} as an accompanying notion of the structure entropy to measure the force of the graph to resist cascading failure of strategic virus attacks. We show that for any connected network , the resistance of is , where and are the one- and two-dimensional structure entropy of , respectively. According to this, we define the notion of {\it security index of a graph} to be the normalized resistance, that is, . We say that a connected graph is an -{\it resistor graph}, if has vertices and has security index . We show that trees and grid graphs are -resistor graphs for large constant , that the graphs with bounded degree and vertices, are -resistor graphs, and that for a graph generated by the security model \cite{LLPZ2015, LP2016}, with high probability, is an -resistor graph, for a constant arbitrarily close to , provided that is sufficiently large. To the opposite side, we show that expander graphs are not good resistor graphs, in the sense that, there is a global constant such that expander graphs cannot be -resistor graph for any . In particular, for the complete graph , the resistance of is a constant , and hence the security index of is . Finally, we show that for any simple and connected graph , if is an -resistor graph, then there is a large such that the -th largest eigenvalue of the Laplacian of is , giving rise to an algebraic characterization for the graphs that are secure against intentional virus attack.
Cite
@article{arxiv.1801.03404,
title = {Structure Entropy and Resistor Graphs},
author = {Angsheng Li and Yicheng Pan},
journal= {arXiv preprint arXiv:1801.03404},
year = {2018}
}