Power-law and log-periodic degree tails for a family of probability generating function equations arising in evolving networks
Abstract
For a fixed integer j1 and 0<p<1, we study the probability generating function (pgf) equation \[ (1+2p)\,g(x)=2p\,xj+g(x-px+px2), 0 x1 , \] which governs the limiting degree distribution \pk\ of a family of evolving network models. The cases j=1 and j=2 are the treelike fast-growth model of Feng and Hu and the homogeneous evolving network of Feng, Li and Hu. We prove that for every j the equation has a unique pgf solution, of mean 2j, and we determine its coefficient tail exactly: \[ pk=k-1-ρ\,Ψj(λk)+o(k-1-ρ), \] where λ=1+p, ρ=(1+2p)/(1+p) is independent of j, and Ψj is continuous, strictly positive and 1-periodic, with explicit Fourier coefficients. This resolves two conjectures of Feng and coauthors: (1) the power-law order pk=Θ(k-1-ρ) and (2) its refinement to the multiplicatively periodic form pkΨj(λk)\,k-1-ρ. The periodic factor is genuinely non-constant for p near 1, and, for the two network models, for all p outside a discrete set. Consequently, pk is asymptotic to no constant multiple of k-1-ρ. Our method is a self-contained local analysis of the supercritical Galton-Watson process with offspring law 1+Bernoulli(p), inspected at an independent geometric time. This time-changed process solves the equation observed by Feng and coauthors. The main results of this paper were obtained by the multi-agent system Eureka and have subsequently been verified by the authors.
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