The additive-multiplicative distance matrix of a graph, and a novel third invariant

Abstract

Graham showed with Pollak and Hoffman-Hosoya that for any directed graph G with strong blocks Ge, the determinant (DG) and cofactor-sum cof(DG) of the distance matrix DG can be computed from the same quantities for the blocks Ge. This was extended to trees - and in our recent work to any graph - with multiplicative and q-distance matrices. For trees, we went further and unified all previous variants with weights in a unital commutative ring, into a distance matrix with additive and multiplicative edge-data. In this work: (1) We introduce the additive-multiplicative distance matrix DG of every strongly connected graph G, using what we term the additive-multiplicative block-datum G. This subsumes the previously studied additive, multiplicative, and q-distances for all graphs. (2) We introduce an invariant (DG) that seems novel to date, and use it to show "master" Graham-Hoffman-Hosoya (GHH) identities, which express (DG), cof(DG) in terms of the blocks Ge. We show how these imply all previous variants. (3) We show (.), cof(.), (.) depend only on the block-data for not just DG, but also several minors of DG. This was not studied in any setting to date; we show it in the "most general" additive-multiplicative setting, hence in all known settings. (4) We compute DG-1 in closed-form; this specializes to all known variants. In particular, we recover our previous formula for DT-1 for additive-multiplicative trees (which itself specializes to a result of Graham-Lovasz and answers a 2006 question of Bapat-Lal-Pati.) (5) We also show that not the Laplacian, but a closely related matrix is the "correct" one to use in DG-1 - for the most general additive-multiplicative matrix DG of each G. As examples, we compute in closed form (DG), cof(DG), (DG), DG-1 for hypertrees.