geometry Geometry (; ) is, with arithmetic, one of the oldest branches of mathematics. It is concerned with properties of space such as the distance, shape, size, and relative position of figures. A mathematician who works in the field of geometry is c ...

, the binary tiling (sometimes called the Böröczky tiling) is a tiling of the hyperbolic plane, resembling a

quadtree A quadtree is a tree data structure in which each internal node has exactly four children. Quadtrees are the two-dimensional analog of octrees and are most often used to partition a two-dimensional space by recursively subdividing it into four q ...

over the

Poincaré half-plane model In non-Euclidean geometry, the Poincaré half-plane model is the upper half-plane, denoted below as H = \, together with a metric, the Poincaré metric, that makes it a model of two-dimensional hyperbolic geometry. Equivalently the Poincaré ha ...

of the hyperbolic plane. It was first studied mathematically in 1974 by . However, a closely related tiling was used earlier in a 1957 print by

M. C. Escher Maurits Cornelis Escher (; 17 June 1898 – 27 March 1972) was a Dutch graphic artist who made mathematically inspired woodcuts, lithographs, and mezzotints. Despite wide popular interest, Escher was for most of his life neglected in t ...

. See especially text describing ''Regular Division of the Plane VI'', pp. 112 & 114, schematic diagram, p. 116, and reproduction of the print, p. 117.

Tiles

In one version of the tiling, the tiles are shapes bounded by three congruent horocyclic segments (two of which are part of the same horocycle), and two

line segments In geometry, a line segment is a part of a straight line that is bounded by two distinct end points, and contains every point on the line that is between its endpoints. The length of a line segment is given by the Euclidean distance between ...

. All tiles are congruent. In the

, the horocyclic segments are modeled as horizontal line segments (parallel to the boundary of the half-plane) and the line segments are modeled as vertical line segments (perpendicular to the boundary of the half-plane), giving each tile the overall shape in the model of a square or rectangle. However, in the hyperbolic plane, these tiles have five sides rather than four, and are not hyperbolic polygons, because their horocyclic edges are not straight. In the half-plane model, In this model, the hyperbolic length of a horizontal horocyclic segment is its Euclidean length in the model, divided by its Euclidean distance from the half-plane boundary. Therefore, in order to make the two horocyclic segments on the lower horizontal edge of each tile each have equal length to the single horocyclic segment on the top edge of the tile, it should be placed with its top edge twice as far from the half-plane boundary as its bottom. An alternative and combinatorially equivalent version of the tiling places its vertices at the same points, but connects them by hyperbolic line segments instead of horocyclic segments, so that each tile becomes a hyperbolic convex pentagon. In this form of the tiling, the tiles do not appear as rectangles in the halfplane model, and the horocycles formed by horizontal sequences of edges are replaced by apeirogons.

Enumeration and aperiodicity

There are uncountably many different tilings of the hyperbolic plane by these tiles, even when they are modified by adding protrusions and indentations to force them to meet edge-to-edge. None of these different tilings are periodic (having a

cocompact Cocompact may refer to: * Cocompact group action * Cocompact Coxeter group * Cocompact embedding * Cocompact lattice {{dab ...

symmetry group), although some (such as the one in which there exists a line that is completely covered by tile edges) have a one-dimensional infinite symmetry group. More strongly than having all tiles the same shape, all first coronas of tiles, the set of tiles touching a single central tile, have the same pattern of tiles (up to symmetries of the hyperbolic plane allowing reflections). For tilings of the Euclidean plane, having all first coronas the same implies that the tiling is periodic and

isohedral In geometry, a tessellation of dimension (a plane tiling) or higher, or a polytope of dimension (a polyhedron) or higher, is isohedral or face-transitive if all its faces are the same. More specifically, all faces must be not merely congruent ...

(having all tiles symmetric to each other); the binary tiling provides a strong counterexample for the corresponding property in the hyperbolic plane. Corresponding to the fact that these tilings are non-periodic but monohedral (having only one tile shape), the dual tilings of these tilings are non-periodic but ''monocoronal'' (having the same pattern of tiles surrounding each vertex). These dual tilings are formed by choosing a reference point within each tile of the binary tiling, and connecting pairs of reference points of tiles that share an edge with each other.

Application

Adjusting the distance between the two vertical sides of the tiles in the binary tiling causes their area to vary, proportional to this distance. By making this distance arbitrarily small, this tiling can be used to show that the hyperbolic plane has tilings by congruent tiles of arbitrarily small area. A 1957 print by

, ''Regular Division of the Plane VI'', has this tiling as its underlying structure, with each tile of the binary tiling (as seen in its quadtree form) subdivided into three right triangles. When interpreted as Euclidean shapes rather than hyperbolically, the tiles are squares and the subdivided triangles are isosceles right triangles. The print itself replaces each triangle by a stylized lizard.

References

{{Tessellation Aperiodic tilings Hyperbolic tilings Pentagonal tilings

Tiles

Enumeration and aperiodicity

Application

See also

References