Are randomly grown graphs really random?
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.
Cite
@article{arxiv.cond-mat/0104546,
title = {Are randomly grown graphs really random?},
author = {Duncan S. Callaway and John E. Hopcroft and Jon M. Kleinberg and M. E. J. Newman and Steven H. Strogatz},
journal= {arXiv preprint arXiv:cond-mat/0104546},
year = {2009}
}
Comments
8 pages, 5 figures