English

On Cycles in Random Graphs

Combinatorics 2010-10-01 v1 Discrete Mathematics

Abstract

We consider the geometric random (GR) graph on the dd-dimensional torus with the LσL_\sigma distance measure (1σ1 \leq \sigma \leq \infty). Our main result is an exact characterization of the probability that a particular labeled cycle exists in this random graph. For σ=2\sigma = 2 and σ=\sigma = \infty, we use this characterization to derive a series which evaluates to the cycle probability. We thus obtain an exact formula for the expected number of Hamilton cycles in the random graph (when σ=\sigma = \infty and σ=2\sigma = 2). We also consider the adjacency matrix of the random graph and derive a recurrence relation for the expected values of the elementary symmetric functions evaluated on the eigenvalues (and thus the determinant) of the adjacency matrix, and a recurrence relation for the expected value of the permanent of the adjacency matrix. The cycle probability features prominently in these recurrence relations. We calculate these quantities for geometric random graphs (in the σ=2\sigma = 2 and σ=\sigma = \infty case) with up to 2020 vertices, and compare them with the corresponding quantities for the Erd\"{o}s-R\'{e}nyi (ER) random graph with the same edge probabilities. The calculations indicate that the threshold for rapid growth in the number of Hamilton cycles (as well as that for rapid growth in the permanent of the adjacency matrix) in the GR graph is lower than in the ER graph. However, as the number of vertices nn increases, the difference between the GR and ER thresholds reduces, and in both cases, the threshold log(n)/n\sim \log(n)/n. Also, we observe that the expected determinant can take very large values. This throws some light on the question of the maximal determinant of symmetric 0/10/1 matrices.

Keywords

Cite

@article{arxiv.1009.6046,
  title  = {On Cycles in Random Graphs},
  author = {Madhav P. Desai},
  journal= {arXiv preprint arXiv:1009.6046},
  year   = {2010}
}

Comments

17 pages, 4 figures

R2 v1 2026-06-21T16:21:22.633Z