Original graphs of link graphs

Abstract

Let ≥slant 0 be an integer, and G be a graph without loops. An -link of G is a walk of length in which consecutive edges are different. We identify an -link with its reverse sequence. The -link graph L(G) of G is defined to have vertices the -links of G, such that two vertices of L(G) are adjacent if their corresponding -links are the initial and final subsequences of an ( + 1)-link of G. A graph G is called an -root of a graph H if L(G) H. For example, L0(G) G. And the 1-link graph of a simple graph is the line graph of that graph. Moreover, let H be a finite connected simple graph. Whitney's isomorphism theorem (1932) states if H has two connected nonnull simple 1-roots, then H K3, and the two 1-roots are isomorphic to K3 and K1, 3 respectively. This paper investigates the -roots of finite graphs. We show that every -root is a certain combination of a finite minimal -root and trees of bounded diameter. This transfers the study of -roots into that of finite minimal -roots. As a qualitative generalisation of Whitney's isomorphism theorem, we bound from above the number, size, order and maximum degree of minimal -roots of a finite graph. This work forms the basis for solving the recognition and determination problems for -link graphs in our future papers. As a byproduct, we characterise the -roots of some special graphs including cycles. Similar results are obtained for path graphs introduced by Broersma and Hoede (1989). G is an -path root of a graph H if H is isomorphic to the -path graph of G. We bound from above the number, size and order of minimal -path roots of a finite graph.