Critical noise of majority-vote model on complex networks

TL;DR

This paper analytically and numerically investigates the critical noise in the majority-vote model on complex networks, revealing its dependence on network topology and finite-size effects.

Contribution

It derives an analytical expression for the critical noise based on network degree moments and explores finite-size effects using stochastic equations, validated by simulations.

Findings

Critical noise depends on degree distribution moments.

Finite-size critical noise decays as network size increases.

Theoretical results are confirmed by simulations on various networks.

Abstract

The majority-vote model with noise is one of the simplest nonequilibrium statistical model that has been extensively studied in the context of complex networks. However, the relationship between the critical noise where the order-disorder phase transition takes place and the topology of the underlying networks is still lacking. In the paper, we use the heterogeneous mean-field theory to derive the rate equation for governing the model's dynamics that can analytically determine the critical noise $f_c$ in the limit of infinite network size $N\rightarrow \infty$. The result shows that $f_c$ depends on the ratio of ${\left\langle k \right\rangle }$ to ${\left\langle k^{3/2} \right\rangle }$, where ${\left\langle k \right\rangle }$ and ${\left\langle k^{3/2} \right\rangle }$ are the average degree and the $3/2$ order moment of degree distribution, respectively. Furthermore, we consider the finite size effect where the stochastic fluctuation should be involved. To the end, we derive the Langevin equation and obtain the potential of the corresponding Fokker-Planck equation. This allows us to calculate the effective critical noise $f_c(N)$ at which the susceptibility is maximal in finite size networks. We find that the $f_c-f_c(N)$ decays with $N$ in a power-law way and vanishes for $N\rightarrow \infty$. All the theoretical results are confirmed by performing the extensive Monte Carlo simulations in random $k$-regular networks, Erd\"os-R\'enyi random networks and scale-free networks.