English

Integer Linear Programming Formulations for Double Roman Domination Problem

Combinatorics 2020-04-14 v2 Discrete Mathematics Optimization and Control

Abstract

For a graph G=(V,E)G= (V,E), a double Roman dominating function (DRDF) is a function f:V{0,1,2,3}f : V \to \{0,1,2,3\} having the property that if f(v)=0f (v) = 0, then vertex vv must have at least two neighbors assigned 22 under ff or {at least} one neighbor uu with f(u)=3f (u) = 3, and if f(v)=1f (v) = 1, then vertex vv must have at least one neighbor uu with f(u)2f (u) \ge 2. In this paper, we consider the double Roman domination problem, which is an optimization problem of finding the DRDF ff such that vVf(v)\sum_{v\in V} f (v) is minimum. We propose {five integer linear programming (ILP) formulations and one mixed integer linear programming formulation with polynomial number of constraints for this problem. Some additional valid inequalities and bounds are also proposed for some of these formulations.} Further, we prove that {the first four models indeed solve the double Roman domination problem, and the last two models} are equivalent to the others regardless of the variable relaxation or usage of a smaller number of constraints and variables. Additionally, we use one ILP formulation to give an H(2(Δ+1))H(2(\Delta+1))-approximation algorithm. All proposed formulations and approximation algorithm are evaluated on randomly generated graphs to compare the performance.

Cite

@article{arxiv.1902.07863,
  title  = {Integer Linear Programming Formulations for Double Roman Domination Problem},
  author = {Qingqiong Cai and Neng Fan and Yongtang Shi and Shunyu Yao},
  journal= {arXiv preprint arXiv:1902.07863},
  year   = {2020}
}

Comments

20 pages, to appear in Optimization Methods and Software

R2 v1 2026-06-23T07:46:40.974Z