English

Laplacian Distribution and Domination

Combinatorics 2016-09-16 v1 Commutative Algebra

Abstract

Let mG(I)m_G(I) denote the number of Laplacian eigenvalues of a graph GG in an interval II, and let γ(G)\gamma(G) denote its domination number. We extend the recent result mG[0,1)γ(G)m_G[0,1) \leq \gamma(G), and show that isolate-free graphs also satisfy γ(G)mG[2,n]\gamma(G) \leq m_G[2,n]. In pursuit of better understanding Laplacian eigenvalue distribution, we find applications for these inequalities. We relate these spectral parameters with the approximability of γ(G)\gamma(G), showing that γ(G)mG[0,1)∉O(logn)\frac{\gamma(G)}{m_G[0,1)} \not\in O(\log n). However, γ(G)mG[2,n](c+1)γ(G)\gamma(G) \leq m_G[2, n] \leq (c + 1) \gamma(G) for cc-cyclic graphs, c1c \geq 1. For trees TT, γ(T)mT[2,n]2γ(G)\gamma(T) \leq m_T[2, n] \leq 2 \gamma(G).

Keywords

Cite

@article{arxiv.1609.04482,
  title  = {Laplacian Distribution and Domination},
  author = {Domingos M. Cardoso and David P. Jacobs and Vilmar Trevisan},
  journal= {arXiv preprint arXiv:1609.04482},
  year   = {2016}
}
R2 v1 2026-06-22T15:50:14.964Z