Positively curved graphs

Abstract: This paper consists of two halves. In the first half of the paper, we consider real-valued functions f whose domain is the vertex set of a graph G and that are Lipschitz with respect to the graph distance. By placing a uniform distribution on the vertex set, we treat as a random variable. We investigate the link between the isoperimetric function of G and the functions f that have maximum variance or meet the bound established by the subgaussian inequality. We present several results Question 1.2 (Alon et al. … Show more

“…Our result connects the distance between two vertices with the length of a path formed by locally-optimal choices over a spectral function, although we use a different spectral formulation than (2). In particular, we replace the Fiedler vector of the Laplacian with the "spread" of a graph, which we will define in Section 3 (its connection to the Fiedler vector of a Laplacian is described in Section 1.3 of [5]).…”

“…Chung and Yau [3] established an upper bound on L D when the graph satisfies graph curvature conditions. There are many different variations of graph curvature; we survey eight variations of positive curvature on Page 545 of [5] and five variations of negative curvature are discussed at various places in [6]; neither survey includes either of the two curvature variations in [3]. The central definition of curvature in [3] is simply called "curvature;" let κ denote the curvature of G when it is well-defined.…”

Remarks on the Spectral Approach to Finding Short Paths

“…Our result connects the distance between two vertices with the length of a path formed by locally-optimal choices over a spectral function, although we use a different spectral formulation than (2). In particular, we replace the Fiedler vector of the Laplacian with the "spread" of a graph, which we will define in Section 3 (its connection to the Fiedler vector of a Laplacian is described in Section 1.3 of [5]).…”

“…Chung and Yau [3] established an upper bound on L D when the graph satisfies graph curvature conditions. There are many different variations of graph curvature; we survey eight variations of positive curvature on Page 545 of [5] and five variations of negative curvature are discussed at various places in [6]; neither survey includes either of the two curvature variations in [3]. The central definition of curvature in [3] is simply called "curvature;" let κ denote the curvature of G when it is well-defined.…”

Remarks on the Spectral Approach to Finding Short Paths