Triangle Contact Representations and Duality

A contact representation by triangles of a graph is a set of triangles in the plane such that two triangles intersect on at most one point, each triangle represents a vertex of the graph and two triangles intersects if and only if their corresponding vertices are adjacent. De Fraysseix, Ossona de Mendez and Rosenstiehl proved that every planar graph admits a contact representation by triangles. We strengthen this in terms of a simultaneous contact representation by triangles of a planar map and of its dual.A primal–dual contact representation by triangles of a planar map is a contact representation by triangles of the primal and a contact representation by triangles of the dual such that for every edge uv, bordering faces f and g, the intersection between the triangles corresponding to u and v is the same point as the intersection between the triangles corresponding to f and g. We prove that every 3-connected planar map admits a primal–dual contact representation by triangles. Moreover, the interiors of the triangles form a tiling of the triangle corresponding to the outer face and each contact point is a corner of exactly three triangles. Then we show that these representations are in one-to-one correspondence with generalized Schnyder woods defined by Felsner for 3-connected planar maps.

[1]  Oded Schramm,et al.  Combinatorically Prescribed Packings and Applications to Conformal and Quasiconformal Maps , 2007, 0709.0710.

[2]  Stefan Felsner,et al.  Convex Drawings of Planar Graphs and the Order Dimension of 3-Polytopes , 2001, Order.

[3]  Stefan Felsner,et al.  Geometric Graphs and Arrangements , 2004 .

[4]  Michael Kaufmann,et al.  Max-tolerance graphs as intersection graphs: cliques, cycles, and recognition , 2006, SODA '06.

[5]  Ezra Miller,et al.  Planar graphs as minimal resolutions of trivariate monomial ideals , 2002, Documenta Mathematica.

[6]  Stefan Felsner,et al.  Geodesic Embeddings and Planar Graphs , 2003, Order.

[7]  Patrice Ossona de Mendez,et al.  Barycentric systems and stretchability , 2007, Discret. Appl. Math..

[8]  E. M. Andreev ON CONVEX POLYHEDRA OF FINITE VOLUME IN LOBAČEVSKIĬ SPACE , 1970 .

[9]  János Pach,et al.  Small sets supporting fary embeddings of planar graphs , 1988, STOC '88.

[10]  Patrice Ossona de Mendez,et al.  On Triangle Contact Graphs , 1994, Combinatorics, Probability and Computing.

[11]  Michael Kaufmann,et al.  Optimal Polygonal Representation of Planar Graphs , 2011, Algorithmica.

[12]  Michael Kaufmann,et al.  Optimal Polygonal Representation of Planar Graphs , 2010, LATIN.

[13]  Benjamin Lévêque,et al.  Triangle Contact Representations and Duality , 2010, Graph Drawing.

[14]  Stefan Felsner,et al.  Schnyder Woods and Orthogonal Surfaces , 2008, Discret. Comput. Geom..

[15]  W. Schnyder Planar graphs and poset dimension , 1989 .

[16]  H. de Fraysseix,et al.  On topological aspects of orientations , 2001, Discret. Math..

[17]  Stefan Felsner,et al.  Homothetic Triangle Contact Representations of Planar Graphs , 2007, CCCG.

[18]  Stefan Felsner,et al.  Lattice Structures from Planar Graphs , 2004, Electron. J. Comb..

[19]  Stefan Felsner,et al.  Convex Drawings of 3-Connected Plane Graphs , 2004, SODA '05.

[20]  Yifan Hu,et al.  On Touching Triangle Graphs , 2010, GD.