Adjacency Graphs of Polyhedral Surfaces

Discrete and Computational Geometry Pub Date : 2023-10-18 DOI:10.1007/s00454-023-00537-6

Elena Arseneva, Linda Kleist, Boris Klemz, Maarten Löffler, André Schulz, Birgit Vogtenhuber, Alexander Wolff

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Abstract

Abstract We study whether a given graph can be realized as an adjacency graph of the polygonal cells of a polyhedral surface in $${\mathbb {R}}^3$$ R 3 . We show that every graph is realizable as a polyhedral surface with arbitrary polygonal cells, and that this is not true if we require the cells to be convex. In particular, if the given graph contains $$K_5$$ K 5 , $$K_{5,81}$$ K 5 , 81 , or any nonplanar 3-tree as a subgraph, no such realization exists. On the other hand, all planar graphs, $$K_{4,4}$$ K 4 , 4 , and $$K_{3,5}$$ K 3 , 5 can be realized with convex cells. The same holds for any subdivision of any graph where each edge is subdivided at least once, and, by a result from McMullen et al. (Isr. J. Math. 46 (1–2), 127–144 (1983)), for any hypercube. Our results have implications on the maximum density of graphs describing polyhedral surfaces with convex cells: The realizability of hypercubes shows that the maximum number of edges over all realizable n -vertex graphs is in $$\Omega (n\log n)$$ Ω ( n log n ) . From the non-realizability of $$K_{5,81}$$ K 5 , 81 , we obtain that any realizable n -vertex graph has $${\mathcal {O}}(n^{9/5})$$ O ( n 9 / 5 ) edges. As such, these graphs can be considerably denser than planar graphs, but not arbitrarily dense.

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多面体曲面的邻接图

摘要研究了在$${\mathbb {R}}^3$$ r3中给定的图是否可以被实现为多面体表面多边形细胞的邻接图。我们证明了每个图都可以实现为具有任意多边形细胞的多面体表面，如果我们要求细胞是凸的，这就不成立了。特别是，如果给定的图包含$$K_5$$ k5, $$K_{5,81}$$ k5, 81或任何非平面3-tree作为子图，则不存在这种实现。另一方面，所有的平面图，$$K_{4,4}$$ k4,4和$$K_{3,5}$$ k3,5都可以用凸单元来实现。这同样适用于任何图的任何细分，其中每条边至少细分一次，并且根据McMullen等人的结果。数学学报，46(1-2)，127-144(1983))。我们的结果对描述具有凸胞的多面体表面的图的最大密度有影响:超立方体的可实现性表明，所有可实现的n顶点图的最大边数是$$\Omega (n\log n)$$ Ω (n log n)。根据$$K_{5,81}$$ K 5,81的不可实现性，我们得到任何可实现的n顶点图都有$${\mathcal {O}}(n^{9/5})$$ O (n 9 / 5)条边。因此，这些图可以比平面图密集得多，但不是任意密集。

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Discrete and Computational Geometry

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