On the Sum of Ricci-Curvatures for Weighted Graphs

Abstract

In this paper, we generalize Lin-Lu-Yau's Ricci curvature to weighted graphs and give a simple limit-free definition. We prove two extremal results on the sum of Ricci curvatures for weighted graph. A weighted graph G=(V,E,d) is an undirected graph G=(V,E) associated with a distance function d E [0,∞). By redefining the weights if possible, without loss of generality, we assume that the shortest weighted distance between u and v is exactly d(u,v) for any edge uv. Now consider a random walk whose transitive probability from an vertex u to its neighbor v (a jump move along the edge uv) is proportional to wuv:=F(d(u,v))/d(u,v) for some given function F(). We first generalize Lin-Lu-Yau's Ricci curvature definition to this weighted graph and give a simple limit-free representation of (x, y) using a so called -coupling functions. The total curvature K(G) is defined to be the sum of Ricci curvatures over all edges of G. We proved the following theorems: if F() is a decreasing function, then K(G)≥ 2|V| -2|E|; if F() is an increasing function, then K(G)≤ 2|V| -2|E|. Both equalities hold if and only if d is a constant function plus the girth is at least 6. In particular, these imply a Gauss-Bonnet theorem for (unweighted) graphs with girth at least 6, where the graph Ricci curvature is defined geometrically in terms of optimal transport.