An analogue of the Descartes-Euler formula for infinite graphs and Higuchi’s conjecture

DeVos, Matt; Mohar, Bojan

doi:10.1090/s0002-9947-07-04125-6

Cited by 49 publications

(109 citation statements)

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“…Because Riemannian manifolds of positive sectional curvature κ uniformly bounded from below as κ(m) ≥ κ min > 0, ∀m ∈ M, have bounded diameter, and because graphs with positive local combinatorial curvature are finite [9,24,7], it follows that, at large scale, only nonpositive curvature is relevant. To define such a concept, let (X, d) be a geodesic metric space.…”

Section: Large Scale δ-Hyperbolic Spacesmentioning

confidence: 99%

“…First, it is easily observed that the complete graph is positively curved by the intuitive clustering coefficient definition of [8]. From a more precise standpoint, as a consequence of [7,Theorem 1.7], K n has a 2-cell embedding in either S 2 of PR 2 . As far as isometric embedding is concerned, the following can be said (see [15]): It turns out that K n is also positively curved by our definition: indeed, it is readily verified that ∀ K n ,…”

Section: Proof Consider a Euclidean Trianglementioning

confidence: 99%

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Scaled Gromov hyperbolic graphs

Jonckheere

Lohsoonthorn

Bonahon

2007

Journal of Graph Theory

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Abstract:In this article, the δ-hyperbolic concept, originally developed for infinite graphs, is adapted to very large but finite graphs. Such graphs can indeed exhibit properties typical of negatively curved spaces, yet the traditional δ-hyperbolic concept, which requires existence of an upper bound on the fatness δ of the geodesic triangles, is unable to capture those properties, as any finite graph has finite δ. Here the idea is to scale δ relative to the diameter of the geodesic triangles and use the Cartan-AlexandrovToponogov (CAT) theory to derive the thresholding value of δ/diam below which the geometry has negative curvature properties.

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Section: Large Scale δ-Hyperbolic Spacesmentioning

confidence: 99%

Section: Proof Consider a Euclidean Trianglementioning

confidence: 99%

Scaled Gromov hyperbolic graphs

Jonckheere

Lohsoonthorn

Bonahon

2007

Journal of Graph Theory

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“…DeVos and Mohar [8] obtained the following Gauss-Bonnet inequality (3.1), which solves a conjecture of Higuchi [11]. Higuchi's conjecture can be thought of as a combinatorial analogue of Myers' theorem [4,14] on Riemannian manifolds.…”

Section: The Characterization Of Embedded Graphs With Nonnegative Commentioning

confidence: 90%

“…For the motivation of combinatorial curvature, we refer to Gromov [10], Higuchi [11], and Ishida [12]. For the application of the Gaussian curvature and the combinatorial curvature on surfaces, we refer to the recent work of DeVos and Mohar [8] and the author's joint work with G. Chen [7].…”

Section: Vertices 1-cells Open Segments and 2-cells Open Convex Polmentioning

confidence: 99%

The Gauss-Bonnet formula of polytopal manifolds and the characterization of embedded graphs with nonnegative curvature

Chen¹

2008

Proc. Amer. Math. Soc.

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Abstract. Let M be a connected d-manifold without boundary obtained from a (possibly infinite) collection P of polytopes of R d by identifying them along isometric facets. Let V (M ) be the set of vertices of M . For each v ∈ V (M ), define the discrete Gaussian curvature κ M (v) as the normal angle-sum with sign, extended over all polytopes having v as a vertex. Our main result is as follows: If the absolute total curvature v∈V (M ) |κ M (v)| is finite, then the limiting curvature κ M (p) for every end p ∈ End M can be well-defined and the Gauss-Bonnet formula holds:In particular, if G is a (possibly infinite) graph embedded in a 2-manifold M without boundary such that every face has at least 3 sides, and if the combinatorial curvature Φ G (v) ≥ 0 for all v ∈ V (G), then the number of vertices with nonvanishing curvature is finite. Furthermore, if G is finite, then M has four choices: sphere, torus, projective plane, and Klein bottle. If G is infinite, then M has three choices: cylinder without boundary, plane, and projective plane minus one point. Polytopal manifolds

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“…We then have the Gauss-Bonnet formula of G of [9], We can also compare the combinatorial curvature with another version of curvature naturally obtained from the surface S(G), its generalized sectional (Gaussian) curvature. It turns out that the semiplanar graph G has nonnegative combinatorial curvature precisely if the polygonal surface S(G) is an Alexandrov space with nonnegative sectional curvature, i.e.…”

Section: Let χ(S(g)) Denote the Euler Characteristic Of The Surface Smentioning

confidence: 99%