3-connected Reduction for Regular Graph Covers

Abstract

A graph G covers a graph H if there exists a locally bijective homomorphism from G to H. We deal with regular coverings in which this homomorphism is prescribed by an action of a semiregular subgroup of Aut(G); so H G / . In this paper, we study the behaviour of regular graph covering with respect to 1-cuts and 2-cuts in G. We describe reductions which produce a series of graphs G = G0,…,Gr such that Gi+1 is created from Gi by replacing certain inclusion minimal subgraphs with colored edges. The process ends with a primitive graph Gr which is either 3-connected, or a cycle, or K2. This reduction can be viewed as a non-trivial modification of reductions of Mac Lane (1937), Trachtenbrot (1958), Tutte (1966), Hopcroft and Tarjan (1973), Cuningham and Edmonds (1980), Walsh (1982), and others. A novel feature of our approach is that in each step all essential information about symmetries of G are preserved. A regular covering projection G0 H0 induces regular covering projections Gi Hi where Hi is the i-th quotient reduction of H0. This property allows to construct all possible quotients H0 of G0 from the possible quotients Hr of Gr. By applying this method to planar graphs, we give a proof of Negami's Theorem (1988). Our structural results are also used in subsequent papers for regular covering testing when G is a planar graph and for an inductive characterization of the automorphism groups of planar graphs (see Babai (1973) as well).