English

Smoothed analysis on connected graphs

Combinatorics 2015-08-13 v4

Abstract

The main paradigm of smoothed analysis on graphs suggests that for any large graph GG in a certain class of graphs, perturbing slightly the edges of GG at random (usually adding few random edges to GG) typically results in a graph having much "nicer" properties. In this work we study smoothed analysis on trees or, equivalently, on connected graphs. Given an nn-vertex connected graph GG, form a random supergraph GG^* of GG by turning every pair of vertices of GG into an edge with probability ϵn\frac{\epsilon}{n}, where ϵ\epsilon is a small positive constant. This perturbation model has been studied previously in several contexts, including smoothed analysis, small world networks, and combinatorics. Connected graphs can be bad expanders, can have very large diameter, and possibly contain no long paths. In contrast, we show that if GG is an nn-vertex connected graph then typically GG^* has edge expansion Ω(1logn)\Omega(\frac{1}{\log n}), diameter O(logn)O(\log n), vertex expansion Ω(1logn)\Omega(\frac{1}{\log n}), and contains a path of length Ω(n)\Omega(n), where for the last two properties we additionally assume that GG has bounded maximum degree. Moreover, we show that if GG has bounded degeneracy, then typically the mixing time of the lazy random walk on GG^* is O(log2n)O(\log^2 n). All these results are asymptotically tight.

Keywords

Cite

@article{arxiv.1307.4884,
  title  = {Smoothed analysis on connected graphs},
  author = {Michael Krivelevich and Daniel Reichman and Wojciech Samotij},
  journal= {arXiv preprint arXiv:1307.4884},
  year   = {2015}
}

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R2 v1 2026-06-22T00:53:37.497Z