Matrix-Forest Theorems

Abstract

The Laplacian matrix of a graph G is L(G)=D(G)-A(G), where A(G) is the adjacency matrix and D(G) is the diagonal matrix of vertex degrees. According to the Matrix-Tree Theorem, the number of spanning trees in G is equal to any cofactor of an entry of L(G). A rooted forest is a union of disjoint rooted trees. We consider the matrix W(G)=I+L(G) and prove that the (i,j)-cofactor of W(G) is equal to the number of spanning rooted forests of G, in which the vertices i and j belong to the same tree rooted at i. The determinant of W(G) equals the total number of spanning rooted forests, therefore the (i,j)-entry of the matrix W-1(G) can be considered as a measure of relative ''forest-accessibility'' of vertex i from j (or j from i). These results follow from somewhat more general theorems we prove, which concern weighted multigraphs. The analogous theorems for (multi)digraphs are also established. These results provide a graph-theoretic interpretation for the adjugate to the Laplacian characteristic matrix.

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