The Smith normal form of distance matrices of high dimensional trees
Abstract
Graham-Lov\'asz-Pollak GL,GP obtained the celebrated formula ( D(Tn+1))=(-1)nn2n-1, for the determinant of the distance matrix D(Tn+1) for any tree Tn+1 with n+1 vertices. Later, Hou and Woo HW extended this formula to the Smith normal form (SNF) obtaining that ( D(Tn+1))= I2 2 In-2 [2n], for any tree Tn+1 with n+1 vertices. A k- tree is either a complete graph on k vertices or a graph obtained from a smaller k-tree by adjoining a new vertex together with k edges connecting it to a k-clique. If τ and τ' are d-cliques in a k-tree T, a d- walk between τ and τ' is a finite sequence τ1σ1τ2σ2·sτl, where τ1=τ, τl=τ', and the d-cliques τi and τi+1 are incident to the same (d+1)-clique σi. For d∈\1,…,k\, the d- distance from the d-cliques τ and τ' is the number of (d+1)-cliques in a minimum d-walk from τ and τ', and is denoted by d(τ,τ'). Let cd denote the number of d-cliques in the k-tree T. Then the d-distance matrix Dd(T) of the k-tree T is the cd× cd matrix, indexed by the d-cliques of T, such that the (i,j)-entry is 0 if i=j, and d(τi,τj) otherwise. Here, we show that, for k and n fixed, the SNF of the k-distance matrix is the same for any k-tree with n vertices. Specifically, for any k-tree Tn with n vertices such that n≥ k+2, the Smith normal form of Dk(Tn) is I(k-1)(n-k)+2 (k+1) In-k-2 [k(k+1)(n-k)], which extends Graham-Lov\'asz-Pollak and Hou-Woo results.
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