English

Local Boxicity and Maximum Degree

Combinatorics 2022-01-26 v4 Discrete Mathematics

Abstract

The \emph{local boxicity} of a graph GG, denoted by lbox(G)lbox(G), is the minimum positive integer ll such that GG can be obtained using the intersection of kk (, where klk \geq l,) interval graphs where each vertex of GG appears as a non-universal vertex in at most ll of these interval graphs. Let GG be a graph on nn vertices having mm edges. Let Δ\Delta denote the maximum degree of a vertex in GG. We show that, (i) lbox(G)213logΔΔlbox(G) \leq 2^{13\log^{*}{\Delta}} \Delta. There exist graphs of maximum degree Δ\Delta having a local boxicity of Ω(ΔlogΔ)\Omega(\frac{\Delta}{\log\Delta}). (ii) lbox(G)O(nlogn)lbox(G) \in O(\frac{n}{\log{n}}). There exist graphs on nn vertices having a local boxicity of Ω(nlogn)\Omega(\frac{n}{\log n}). (iii) lbox(G)(213logm+2)mlbox(G) \leq (2^{13\log^{*}{\sqrt{m}}} + 2 )\sqrt{m}. There exist graphs with mm edges having a local boxicity of Ω(mlogm)\Omega(\frac{\sqrt{m}}{\log m}). (iv) the local boxicity of GG is at most its \emph{product dimension}. This connection helps us in showing that the local boxicity of the \emph{Kneser graph} K(n,k)K(n,k) is at most k2loglogn\frac{k}{2} \log{\log{n}}. The above results can be extended to the \emph{local dimension} of a partially ordered set due to the known connection between local boxicity and local dimension. Finally, we show that the \emph{cubicity} of a graph on nn vertices of girth greater than g+1g+1 is O(n1g/2logn)O(n^{\frac{1}{\lfloor g/2\rfloor}}\log n).

Keywords

Cite

@article{arxiv.1810.02963,
  title  = {Local Boxicity and Maximum Degree},
  author = {Atrayee Majumder and Rogers Mathew},
  journal= {arXiv preprint arXiv:1810.02963},
  year   = {2022}
}

Comments

17 pages

R2 v1 2026-06-23T04:30:30.520Z