The Component Connectivity of Alternating Group Graphs and Split-Stars

Abstract

For an integer ≥slant 2, the -component connectivity of a graph G, denoted by (G), is the minimum number of vertices whose removal from G results in a disconnected graph with at least components or a graph with fewer than vertices. This is a natural generalization of the classical connectivity of graphs defined in term of the minimum vertex-cut and is a good measure of robustness for the graph corresponding to a network. So far, the exact values of -connectivity are known only for a few classes of networks and small 's. It has been pointed out in~[Component connectivity of the hypercubes, Int. J. Comput. Math. 89 (2012) 137--145] that determining -connectivity is still unsolved for most interconnection networks, such as alternating group graphs and star graphs. In this paper, by exploring the combinatorial properties and fault-tolerance of the alternating group graphs AGn and a variation of the star graphs called split-stars Sn2, we study their -component connectivities. We obtain the following results: (i) 3(AGn)=4n-10 and 4(AGn)=6n-16 for n≥slant 4, and 5(AGn)=8n-24 for n≥slant 5; (ii) 3(Sn2)=4n-8, 4(Sn2)=6n-14, and 5(Sn2)=8n-20 for n≥slant 4.