English

Sigma Partitioning: Complexity and Random Graphs

Combinatorics 2023-06-22 v7 Computational Complexity

Abstract

A sigma partitioning\textit{sigma partitioning} of a graph GG is a partition of the vertices into sets P1,,PkP_1, \ldots, P_k such that for every two adjacent vertices uu and vv there is an index ii such that uu and vv have different numbers of neighbors in PiP_i. The  sigma number\textit{ sigma number} of a graph GG, denoted by σ(G)\sigma(G), is the minimum number kk such that G G has a sigma partitioning P1,,PkP_1, \ldots, P_k. Also, a  lucky labeling\textit{ lucky labeling} of a graph GG is a function :V(G)N \ell :V(G) \rightarrow \mathbb{N}, such that for every two adjacent vertices v v and u u of G G , wv(w)wu(w) \sum_{w \sim v}\ell(w)\neq \sum_{w \sim u}\ell(w) (xy x \sim y means that x x and yy are adjacent). The  lucky number\textit{ lucky number} of G G , denoted by η(G)\eta(G), is the minimum number kk such that G G has a lucky labeling :V(G)Nk \ell :V(G) \rightarrow \mathbb{N}_k. It was conjectured in [Inform. Process. Lett., 112(4):109--112, 2012] that it is NP \mathbf{NP} -complete to decide whether η(G)=2 \eta(G)=2 for a given 3-regular graph GG. In this work, we prove this conjecture. Among other results, we give an upper bound of five for the sigma number of a uniformly random graph.

Keywords

Cite

@article{arxiv.1403.6288,
  title  = {Sigma Partitioning: Complexity and Random Graphs},
  author = {Ali Dehghan and Mohammad-Reza Sadeghi and Arash Ahadi},
  journal= {arXiv preprint arXiv:1403.6288},
  year   = {2023}
}
R2 v1 2026-06-22T03:33:48.592Z