English

Random Walks on Small World Networks

Discrete Mathematics 2020-02-27 v3

Abstract

We study the mixing time of random walks on small-world networks modelled as follows: starting with the 2-dimensional periodic grid, each pair of vertices {u,v}\{u,v\} with distance d>1d>1 is added as a "long-range" edge with probability proportional to drd^{-r}, where r0r\geq 0 is a parameter of the model. Kleinberg studied a close variant of this network model and proved that the (decentralised) routing time is O((logn)2)O((\log n)^2) when r=2r=2 and nΩ(1)n^{\Omega(1)} when r2r\neq 2. Here, we prove that the random walk also undergoes a phase transition at r=2r=2, but in this case the phase transition is of a different form. We establish that the mixing time is Θ(logn)\Theta(\log n) for r<2r<2, O((logn)4)O((\log n)^4) for r=2r=2 and nΩ(1)n^{\Omega(1)} for r>2r>2.

Keywords

Cite

@article{arxiv.1707.02467,
  title  = {Random Walks on Small World Networks},
  author = {Martin E. Dyer and Andreas Galanis and Leslie Ann Goldberg and Mark Jerrum and Eric Vigoda},
  journal= {arXiv preprint arXiv:1707.02467},
  year   = {2020}
}

Comments

To appear in Transactions of Algorithms (TALG)

R2 v1 2026-06-22T20:41:28.484Z