English

Parallel Dynamics and Computational Complexity of Network Growth Models

Statistical Mechanics 2009-11-10 v2

Abstract

The parallel computational complexity or depth of growing network models is investigated. The networks considered are generated by preferential attachment rules where the probability of attaching a new node to an existing node is given by a power, α\alpha of the connectivity of the existing node. Algorithms for generating growing networks very quickly in parallel are described and studied. The sublinear and superlinear cases require distinct algorithms. As a result, there is a discontinuous transition in the parallel complexity of sampling these networks corresponding to the discontinuous structural transition at α=1\alpha=1, where the networks become scale free. For α>1\alpha>1 networks can be generated in constant time while for 0α<10 \leq \alpha < 1 logarithmic parallel time is required. The results show that these networks have little depth and embody very little history dependence despite being defined by sequential growth rules.

Keywords

Cite

@article{arxiv.cond-mat/0408372,
  title  = {Parallel Dynamics and Computational Complexity of Network Growth Models},
  author = {Benjamin Machta and Jonthan Machta},
  journal= {arXiv preprint arXiv:cond-mat/0408372},
  year   = {2009}
}

Comments

10 pages, 2 figures