English

Dual Power Assignment via Second Hamiltonian Cycle

Discrete Mathematics 2014-02-25 v1 Computational Geometry

Abstract

A power assignment is an assignment of transmission power to each of the wireless nodes of a wireless network, so that the induced graph satisfies some desired properties. The cost of a power assignment is the sum of the assigned powers. In this paper, we consider the dual power assignment problem, in which each wireless node is assigned a high- or low-power level, so that the induced graph is strongly connected and the cost of the assignment is minimized. We improve the best known approximation ratio from π26136+ϵ1.617\frac{\pi^2}{6}-\frac{1}{36}+\epsilon\thickapprox 1.617 to 1171.571\frac{11}{7}\thickapprox 1.571. Moreover, we show that the algorithm of Khuller et al. for the strongly connected spanning subgraph problem, which achieves an approximation ratio of 1.611.61, is 1.5221.522-approximation algorithm for symmetric directed graphs. The innovation of this paper is in achieving these results via utilizing interesting properties for the existence of a second Hamiltonian cycle.

Keywords

Cite

@article{arxiv.1402.5783,
  title  = {Dual Power Assignment via Second Hamiltonian Cycle},
  author = {Karim Abu-Affash and Paz Carmi and Anat Parush Tzur},
  journal= {arXiv preprint arXiv:1402.5783},
  year   = {2014}
}
R2 v1 2026-06-22T03:14:20.550Z