English

Parametrized Complexity of Weak Odd Domination Problems

Computational Complexity 2015-01-15 v2 Quantum Physics

Abstract

Given a graph G=(V,E)G=(V,E), a subset BVB\subseteq V of vertices is a weak odd dominated (WOD) set if there exists DVBD \subseteq V {\setminus} B such that every vertex in BB has an odd number of neighbours in DD. κ(G)\kappa(G) denotes the size of the largest WOD set, and κ(G)\kappa'(G) the size of the smallest non-WOD set. The maximum of κ(G)\kappa(G) and Vκ(G)|V|-\kappa'(G), denoted κQ(G)\kappa_Q(G), plays a crucial role in quantum cryptography. In particular deciding, given a graph GG and k>0k>0, whether κQ(G)k\kappa_Q(G)\le k is of practical interest in the design of graph-based quantum secret sharing schemes. The decision problems associated with the quantities κ\kappa, κ\kappa' and κQ\kappa_Q are known to be NP-Complete. In this paper, we consider the approximation of these quantities and the parameterized complexity of the corresponding problems. We mainly prove the fixed-parameter intractability (W[1][1]-hardness) of these problems. Regarding the approximation, we show that κQ\kappa_Q, κ\kappa and κ\kappa' admit a constant factor approximation algorithm, and that κ\kappa and κ\kappa' have no polynomial approximation scheme unless P=NP.

Keywords

Cite

@article{arxiv.1206.4081,
  title  = {Parametrized Complexity of Weak Odd Domination Problems},
  author = {David Cattanéo and Simon Perdrix},
  journal= {arXiv preprint arXiv:1206.4081},
  year   = {2015}
}

Comments

16 pages, 5 figures

R2 v1 2026-06-21T21:21:36.955Z