On the largest component of a hyperbolic model of complex networks
Publication date
2015-08-14
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Abstract
We consider a model for complex networks that was introduced by Krioukov et al. In this model, N points are chosen randomly inside a disk on the hyperbolic plane and any two of them are joined by an edge if they are within a certain hyperbolic distance. The N points are distributed according to a quasi-uniform distribution, which is a distorted version of the uniform distribution. The model turns out to behave similarly to the well-known Chung-Lu model, but without the independence between the edges. Namely, it exhibits a power-law degree sequence and small distances but, unlike the Chung-Lu model and many other well-known models for complex networks, it also exhibits clustering. The model is controlled by two parameters α and ν where, roughly speaking, α controls the exponent of the power-law and ν controls the average degree. The present paper focuses on the evolution of the component structure of the random graph. We show that (a) for α > 1 and ν arbitrary, with high probability, as the number of vertices grows, the largest component of the random graph has sublinear order; (b) for α < 1 and ν arbitrary with high probability there is a "giant" component of linear order, and (c) when α = 1 then there is a non-trivial phase transition for the existence of a linear-sized component in terms of ν.
Keywords
Component structure, Giant component, Phase transition, Random graphs on the hyperbolic plane, Geometry and Topology, Theoretical Computer Science, Computational Theory and Mathematics
Citation
Bode, M, Fountoulakis, N & Müller, T 2015, 'On the largest component of a hyperbolic model of complex networks', Electronic Journal of Combinatorics, vol. 22, no. 3, #P3.24, pp. 1-46. https://doi.org/10.37236/4958