On Representing Graphs by Touching Cuboids

Bremner, David; Evans, William S.; Frati, Fabrizio; Heyer, Laurie J.; Kobourov, Stephen G.; Lenhart, William; Liotta, Giuseppe; Rappaport, David; Whitesides, Sue

doi:10.1007/978-3-642-36763-2_17

Cited by 13 publications

(42 citation statements)

References 19 publications

(21 reference statements)

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“…Note that by moving the cubes in the representation by an arbitrarily small amount, we can make sure that for each triangle xyz in P * , the three cubes for x, y and z form a corner surrounded by three mutually touching walls at right angles to each other. Now observe that each of the three graphs G a , G b and G c is a planar 3-tree; thus using the algorithm of either [5] or [10], we can place the internal vertices of these three graphs in their corresponding corners, thereby completing the representation.…”

Section: Cube-contact Representation For Extended Piecesmentioning

confidence: 99%

“…Thomassen [17] shows that any planar graph has a proper contact representation with touching boxes, while Felsner and Francis [10] find a (not necessarily proper) contact representation of any planar graph with touching cubes. Recently, Bremner et al [5] asked whether any planar graph can be represented by proper contacts of cubes. They answered the question positively for the case of partial planar 3-trees and some planar grids, but the problem remains open for general planar graphs.…”

Section: Introductionmentioning

confidence: 99%

“…We also show that several classes of planar graphs admit proportional box-contact representations. Specifically, we show how to compute a proportional box-contact representation for plane 3-trees, while a cube-contact representation for the same graph class follows from [5]. We also show how to compute a proportional box-contact representation and a cube-contact representation for nested maximal outerplanar graphs, which are defined as follows.…”

Section: Introductionmentioning

confidence: 99%

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On Contact Graphs with Cubes and Proportional Boxes

Alam

Kaufmann

Kobourov

2016

Lecture Notes in Computer Science

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Abstract. We study two variants of the problem of contact representation of planar graphs with axis-aligned boxes. In a cube-contact representation we realize each vertex with a cube, while in a proportional box-contact representation each vertex is an axis-aligned box with a prespecified volume. We present algorithms for constructing cube-contact representation and proportional box-contact representation for several classes of planar graphs.

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Section: Cube-contact Representation For Extended Piecesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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On Contact Graphs with Cubes and Proportional Boxes

Alam

Kaufmann

Kobourov

2016

Lecture Notes in Computer Science

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“…On the other hand, there is much less known about contact representations in the 3D space. Contact graphs using 3D objects have been studied for spheres [4], [18], cylinders [3], tetrahedra [2] and axis-aligned cuboids [6], [15], [22]. Thomassen shows that any planar graph has a contact representation by cuboids [22].…”

Section: A Related Workmentioning

confidence: 99%

“…For axis-aligned polyhedra, the notion of polyhedral complexity can be measured by the number of cuboids that make a polyhedra, or by the number of corners, edges and faces in the polyhedra. Previous results on axis-aligned contact representations in 3D only consider axisaligned cuboids to represent vertices [6], [15], [22]. However, there are graphs, even as simple as K 5 , for which cuboids are not sufficient.…”

Section: Introductionmentioning

confidence: 99%

3D proportional contact representations of graphs

Alam

Kobourov

Liotta

et al. 2014

IISA 2014, the 5th International Conference on Information, Intelligence, Systems and Applications

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Abstract-In 3D contact representations, the vertices of a graph are represented by 3D polyhedra and the edges are realized by non-zero-area common boundaries between corresponding polyhedra. While contact representations with cuboids have been studied in the literature, we consider a novel generalization of the problem in which vertices are represented by axis-aligned polyhedra that are union of two cuboids. In particular, we study the weighted (proportional) version of the problem, where the volumes of the polyhedra and the areas of the common boundaries realize prespecified vertex and edge weights. For some classes of graphs (e.g., outerplanar, planar bipartite, planar, complete), we provide algorithms to construct such representations for arbitrary given weights. We also show that not all graphs can be represented in 3D with axis-aligned polyhedra of constant complexity.

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Representing Graphs and Hypergraphs by Touching Polygons in 3D

Evans

Rzążewski

Saeedi

et al. 2019

Lecture Notes in Computer Science

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Contact representations of graphs have a long history. Most research has focused on problems in 2d, but 3d contact representations have also been investigated, mostly concerning fully-dimensional geometric objects such as spheres or cubes. In this paper we study contact representations with convex polygons in 3d. We show that every graph admits such a representation. Since our representations use super-polynomial coordinates, we also construct representations on grids of polynomial size for specific graph classes (bipartite, subcubic). For hypergraphs, we represent their duals, that is, each vertex is represented by a point and each edge by a polygon. We show that even regular and quite small hypergraphs do not admit such representations. On the other hand, the two smallest Steiner triple systems can be represented.

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On Representing Graphs by Touching Cuboids

Cited by 13 publications

References 19 publications

On Contact Graphs with Cubes and Proportional Boxes

On Contact Graphs with Cubes and Proportional Boxes

3D proportional contact representations of graphs

Representing Graphs and Hypergraphs by Touching Polygons in 3D

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