English

Degree distribution in random planar graphs

Combinatorics 2009-11-24 v1

Abstract

We prove that for each k0k\ge0, the probability that a root vertex in a random planar graph has degree kk tends to a computable constant dkd_k, so that the expected number of vertices of degree kk is asymptotically dknd_k n, and moreover that kdk=1\sum_k d_k =1. The proof uses the tools developed by Gimenez and Noy in their solution to the problem of the asymptotic enumeration of planar graphs, and is based on a detailed analysis of the generating functions involved in counting planar graphs. However, in order to keep track of the degree of the root, new technical difficulties arise. We obtain explicit, although quite involved expressions, for the coefficients in the singular expansions of the generating functions of interest, which allow us to use transfer theorems in order to get an explicit expression for the probability generating function p(w)=kdkwkp(w)=\sum_k d_k w^k. From this we can compute the dkd_k to any degree of accuracy, and derive the asymptotic estimate dkck1/2qkd_k \sim c\cdot k^{-1/2} q^k for large values of kk, where q0.67q \approx 0.67 is a constant defined analytically.

Keywords

Cite

@article{arxiv.0911.4331,
  title  = {Degree distribution in random planar graphs},
  author = {Michael Drmota and Omer Gimenez and Marc Noy},
  journal= {arXiv preprint arXiv:0911.4331},
  year   = {2009}
}
R2 v1 2026-06-21T14:14:48.247Z