Giant component sizes in scale-free networks with power-law degrees and cutoffs

Abstract

Scale-free networks arise from power-law degree distributions. Due to the finite size of real-world networks, the power law inevitably has a cutoff at some maximum degree . We investigate the relative size of the giant component S in the large-network limit. We show that S as a function of increases fast when is just large enough for the giant component to exist, but increases ever more slowly when increases further. This makes that while the degree distribution converges to a pure power law when ∞, S approaches its limiting value at a slow pace. The convergence rate also depends on the power-law exponent τ of the degree distribution. The worst rate of convergence is found to be for the case τ≈2, which concerns many of the real-world networks reported in the literature.