Description
The Wythoff construction begins by choosing a ''generator point'' on a fundamental triangle. This point must be chosen at equal distance from all edges that it does not lie on, and a perpendicular line is then dropped from it to each such edge. The three numbers in Wythoff's symbol, ''p'', ''q'', and ''r'', represent the corners of the Schwarz triangle used in the construction, which are , , and radians respectively. The triangle is also represented with the same numbers, written (''p'' ''q'' ''r''). The vertical bar in the symbol specifies a categorical position of the generator point within the fundamental triangle according to the following: * indicates that the generator lies on the corner ''p'', * indicates that the generator lies on the edge between ''p'' and ''q'', * indicates that the generator lies in the interior of the triangle. In this notation the mirrors are labeled by the reflection-order of the opposite vertex. The ''p'', ''q'', ''r'' values are listed ''before'' the bar if the corresponding mirror is active. A special use is the symbol which is designated for the case where all mirrors are active, but odd-numbered reflected images are ignored. The resulting figure has rotational symmetry only. The generator point can either be on or off each mirror, activated or not. This distinction creates 8 (23) possible forms, but the one where the generator point is on all the mirrors is impossible. The symbol that would normally refer to that is reused for the snub tilings. The Wythoff symbol is functionally similar to the more general Coxeter-Dynkin diagram, in which each node represents a mirror and the arcs between them – marked with numbers – the angles between the mirrors. (An arc representing a right angle is omitted.) A node is circled if the generator point is not on the mirror.Example spherical, euclidean and hyperbolic tilings on right triangles
The fundamental triangles are drawn in alternating colors as mirror images. The sequence of triangles (''p'' 3 2) change from spherical (''p'' = 3, 4, 5), to Euclidean (''p'' = 6), to hyperbolic (''p'' ≥ 7). Hyperbolic tilings are shown as a Poincaré disk projection.See also
* Regular polytope * Regular polyhedron * List of uniform tilings * Uniform tilings in hyperbolic plane * List of uniform polyhedra * List of uniform polyhedra by Schwarz triangle * Lists of uniform tilings on the sphere, plane, and hyperbolic planeReferences
* Coxeter '' Regular Polytopes'', Third edition, (1973), Dover edition, (Chapter V: The Kaleidoscope, Section: 5.7 Wythoff's construction) * Coxeter ''The Beauty of Geometry: Twelve Essays'', Dover Publications, 1999, (Chapter 3: Wythoff's Construction for Uniform Polytopes) * Coxeter, Longuet-Higgins, Miller, ''Uniform polyhedra'', Phil. Trans. 1954, 246 A, 401–50. * pp. 9–10.External links
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