Coarse-grained Monte Carlo simulations of the phase transition of Potts model on weighted networks

Abstract

Developing effective coarse grained (CG) approach is a promising way for studying dynamics on large size networks. In the present work, we have proposed a strength-based CG () method to study critical phenomena of the Potts model on weighted complex networks. By merging nodes with close strength together, the original network is reduced to a CG-network with much smaller size, on which the CG-Hamiltonian can be well-defined. In particular, we make error analysis and show that our strength-based CG approach satisfies the condition of statistical consistency, which demands that the equilibrium probability distribution of the CG-model matches that of the microscopic counterpart. Extensive numerical simulations are performed on scale-free networks, without or with strength-correlation, showing that this approach works very well in reproducing the phase diagrams, fluctuations, and finite size effects of the microscopic model, while the approach proposed in our recent work [Phys. Rev. E 82, 011107(2010)] does not.