English

Oriented Diameter of Star Graphs

Discrete Mathematics 2019-11-26 v1 Distributed, Parallel, and Cluster Computing Combinatorics

Abstract

An {\em orientation} of an undirected graph GG is an assignment of exactly one direction to each edge of GG. Converting two-way traffic networks to one-way traffic networks and bidirectional communication networks to unidirectional communication networks are practical instances of graph orientations. In these contexts minimising the diameter of the resulting oriented graph is of prime interest. The nn-star network topology was proposed as an alternative to the hypercube network topology for multiprocessor systems by Akers and Krishnamurthy [IEEE Trans. on Computers (1989)]. The nn-star graph SnS_n consists of n!n! vertices, each labelled with a distinct permutation of [n][n]. Two vertices are adjacent if their labels differ exactly in the first and one other position. SnS_n is an (n1)(n-1)-regular, vertex-transitive graph with diameter 3(n1)/2\lfloor 3(n-1)/2 \rfloor. Orientations of SnS_n, called unidirectional star graphs and distributed routing protocols over them were studied by Day and Tripathi [Information Processing Letters (1993)] and Fujita [The First International Symposium on Computing and Networking (CANDAR 2013)]. Fujita showed that the (directed) diameter of this unidirectional star graph Sn\overrightarrow{S_n} is at most 5n/2+2\lceil{5n/2}\rceil + 2. In this paper, we propose a new distributed routing algorithm for the same Sn\overrightarrow{S_n} analysed by Fujita, which routes a packet from any node ss to any node tt at an undirected distance dd from ss using at most min{4d+4,2n+4}\min\{4d+4, 2n+4\} hops. This shows that the (directed) diameter of Sn\overrightarrow{S_n} is at most 2n+42n+4. We also show that the diameter of Sn\overrightarrow{S_n} is at least 2n2n when n7n \geq 7, thereby showing that our upper bound is tight up to an additive factor.

Keywords

Cite

@article{arxiv.1911.10340,
  title  = {Oriented Diameter of Star Graphs},
  author = {K. S. Ajish Kumar and Deepak Rajendraprasad and K. S. Sudeep},
  journal= {arXiv preprint arXiv:1911.10340},
  year   = {2019}
}

Comments

Full version of the paper to be presented in CALDAM 2020

R2 v1 2026-06-23T12:25:08.798Z