Abstract

We analyze a minimal model of a growing network. At each time step, a new vertex is added; then, with probability delta, two vertices are chosen uniformly at random and joined by an undirected edge. This process is repeated for t time steps. In the limit of large t, the resulting graph displays surprisingly rich characteristics. In particular, a giant component emerges in an infinite-order phase transition at delta=1/8. At the transition, the average component size jumps discontinuously but remains finite. In contrast, a static random graph with the same degree distribution exhibits a second-order phase transition at delta=1/4, and the average component size diverges there. These dramatic differences between grown and static random graphs stem from a positive correlation between the degrees of connected vertices in the grown graph-older vertices tend to have higher degree, and to link with other high-degree vertices, merely by virtue of their age. We conclude that grown graphs, however randomly they are constructed, are fundamentally different from their static random graph counterparts.

Keywords

CombinatoricsRandom graphMathematicsGiant componentVertex (graph theory)Discrete mathematicsConnected componentDegree distributionGraphComplex network

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Publication Info

Year
2001
Type
article
Volume
64
Issue
4
Pages
041902-041902
Citations
443
Access
Closed

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Duncan S. Callaway, John E. Hopcroft, Jon Kleinberg et al. (2001). Are randomly grown graphs really random?. Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics , 64 (4) , 041902-041902. https://doi.org/10.1103/physreve.64.041902

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DOI
10.1103/physreve.64.041902