On Oriented Diameter of (n, k)-Star Graphs

Abstract

Assignment of one of the two possible directions to every edge of an undirected graph G=(V,E) is called an orientation of G. The resulting directed graph is denoted by G. A strong orientation is one in which every vertex is reachable from every other vertex via a directed path. The diameter of G, i.e., the maximum distance from one vertex to another, depends on the particular orientation. The minimum diameter among all possible orientations is called the oriented diameter diam(G) of G. Let n,k be two integers with 1 ≤ k < n. In the realm of interconnection networks of processing elements, an (n,k)-star graph Sn,k offers a topology that circumvents the lack of scalability of n-star graphs Sn. In this paper, we present a strong orientation for Sn,k that combines approaches suggested by Cheng and Lipman [Journal of Interconnection Networks (2002)] for Sn,k with the one proposed by Fujita [The First International Symposium on Computing and Networking (CANDAR 2013)] for Sn. Next, we propose a distributed routing algorithm for Sn,k inspired by an algorithm proposed by Kumar, Rajendraprasad and Sudeep [Discrete Applied Mathematics (2021)] for Sn. With the aid of both the orientation scheme and the routing algorithm, we show that diam(Sn,k) ≤ n+k2 + 2k + 6 - δ(n,k) where δ(n,k) is a non-negative function. The function δ(n,k) takes on values 2k-n, 0, and n-3k2 respectively for three disjoint intervals k>n2, n3 < k ≤ n2 and k≤ n3. For every value of n, k, our upper bound performs better than all known bounds in literature.