A Geometric Fractal Growth Model for Scale Free Networks
Abstract
We introduce a deterministic model for scale-free networks, whose degree distribution follows a power-law with the exponent γ. At each time step, each vertex generates its offsprings, whose number is proportional to the degree of that vertex with proportionality constant m-1 (m>1). We consider the two cases: first, each offspring is connected to its parent vertex only, forming a tree structure, and secondly, it is connected to both its parent and grandparent vertices, forming a loop structure. We find that both models exhibit power-law behaviors in their degree distributions with the exponent γ=1+ (2m-1)/ m. Thus, by tuning m, the degree exponent can be adjusted in the range, 2 <γ < 3. We also solve analytically a mean shortest-path distance d between two vertices for the tree structure, showing the small-world behavior, that is, d N/ k, where N is system size, and k is the mean degree. Finally, we consider the case that the number of offsprings is the same for all vertices, and find that the degree distribution exhibits an exponential-decay behavior.
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