English

Structure Entropy and Resistor Graphs

Discrete Mathematics 2018-01-11 v1 Information Theory math.IT

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 GG, the resistance of GG is R(G)=H1(G)H2(G)\mathcal{R}(G)=\mathcal{H}^1(G)-\mathcal{H}^2(G), where H1(G)\mathcal{H}^1(G) and H2(G)\mathcal{H}^2(G) are the one- and two-dimensional structure entropy of GG, respectively. According to this, we define the notion of {\it security index of a graph} to be the normalized resistance, that is, θ(G)=R(G)H1(H)\theta (G)=\frac{\mathcal{R}(G)}{\mathcal{H}^1(H)}. We say that a connected graph is an (n,θ)(n,\theta)-{\it resistor graph}, if GG has nn vertices and has security index θ(G)θ\theta (G)\geq\theta. We show that trees and grid graphs are (n,θ)(n,\theta)-resistor graphs for large constant θ\theta, that the graphs with bounded degree dd and nn vertices, are (n,2do(1))(n,\frac{2}{d}-o(1))-resistor graphs, and that for a graph GG generated by the security model \cite{LLPZ2015, LP2016}, with high probability, GG is an (n,θ)(n,\theta)-resistor graph, for a constant θ\theta arbitrarily close to 11, provided that nn 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 θ0<1\theta_0<1 such that expander graphs cannot be (n,θ)(n,\theta)-resistor graph for any θθ0\theta\geq\theta_0. In particular, for the complete graph GG, the resistance of GG is a constant O(1)O(1), and hence the security index of GG is θ(G)=o(1)\theta (G)=o(1). Finally, we show that for any simple and connected graph GG, if GG is an (n,1o(1))(n, 1-o(1))-resistor graph, then there is a large kk such that the kk-th largest eigenvalue of the Laplacian of GG is o(1)o(1), giving rise to an algebraic characterization for the graphs that are secure against intentional virus attack.

Keywords

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}
}
R2 v1 2026-06-22T23:41:42.656Z