中文

Matrix-Forest Theorems

组合数学 2023-11-03 v2 离散数学 环与代数

摘要

The Laplacian matrix of a graph GG is L(G)=D(G)A(G)L(G)=D(G)-A(G), where A(G)A(G) is the adjacency matrix and D(G)D(G) is the diagonal matrix of vertex degrees. According to the Matrix-Tree Theorem, the number of spanning trees in GG is equal to any cofactor of an entry of L(G)L(G). A rooted forest is a union of disjoint rooted trees. We consider the matrix W(G)=I+L(G)W(G)=I+L(G) and prove that the (i,j)(i,j)-cofactor of W(G)W(G) is equal to the number of spanning rooted forests of GG, in which the vertices ii and jj belong to the same tree rooted at ii. The determinant of W(G)W(G) equals the total number of spanning rooted forests, therefore the (i,j)(i,j)-entry of the matrix W1(G)W^{-1}(G) can be considered as a measure of relative ''forest-accessibility'' of vertex ii from jj (or jj from ii). 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.

关键词

引用

@article{arxiv.math/0602575,
  title  = {Matrix-Forest Theorems},
  author = {Pavel Chebotarev and Elena Shamis},
  journal= {arXiv preprint arXiv:math/0602575},
  year   = {2023}
}

备注

Unpublished manuscript (1994-1997); 11 pages