English

Shotgun assembly of random regular graphs

Probability 2025-12-03 v3

Abstract

Mossel and Ross (2019) introduce the shotgun assembly problem for random graphs: what radius RR ensures that the random graph GG can be uniquely recovered from its list of rooted RR-neighborhoods, with high probability? Here we consider this question for random regular graphs of fixed degree d3d\ge3. A result of Bollob\'as (1982) implies efficient recovery at R=(1+ϵ)12logd1nR = (1 + \epsilon) \frac12 \log_{d-1}n with high probability -- moreover, this recovery algorithm uses only a summary of the distances in each neighborhood. We show that using the full neighborhood structure gives a sharper bound R=logn+loglogn2log(d1)+O(1), R = \frac{\log n + \log\log n}{2\log(d-1)} + O(1)\,, which we prove is tight up to the O(1)O(1) term. One consequence of our proof is that if G,HG,H are independent graphs where GG follows the random regular law, then with high probability the graphs are non-isomorphic; furthermore, this can be efficiently certified by testing the RR-neighborhood list of HH against the RR-neighborhood of a single adversarially chosen vertex of GG.

Keywords

Cite

@article{arxiv.1512.08473,
  title  = {Shotgun assembly of random regular graphs},
  author = {Brice Huang and Elchanan Mossel and Nike Sun and Claire Zhang and Leqi Zhou},
  journal= {arXiv preprint arXiv:1512.08473},
  year   = {2025}
}

Comments

58 pages, 10 figures. v2: includes new arguments to correct an error in the previous version. v3: corrected contact information of one of the authors

R2 v1 2026-06-22T12:19:03.168Z