List of convex uniform tilings

This table shows the 11 convex uniform tilings (regular and semiregular) of the Euclidean plane, and their dual tilings.

There are three regular and eight semiregular tilings in the plane. The semiregular tilings form new tilings from their duals, each made from one type of irregular face.

Uniform tilings are listed by their vertex configuration, the sequence of faces that exist on each vertex. For example 4.8.8 means one square and two octagons on a vertex.

These 11 uniform tilings have 32 different uniform colorings. A uniform coloring allows identical sided polygons at a vertex to be colored differently, while still maintaining vertex-uniformity and transformational congruence between vertices. (Note: Some of the tiling images shown below are not color-uniform)

In addition to the 11 convex uniform tilings, there are also 14 nonconvex tilings, using star polygons, and reverse orientation vertex configurations.

The dual tilings of these tilings have vertices at the centers of the regular polygons, and edges connecting centers of regular polygons that share an edge. The tiles of the dual tiling are not necessarily regular themselves, but each vertex has edges evenly spaced around it. These dual tilings are listed by their face configuration, the number of faces at each vertex of a face. For example V4.8.8 means isosceles triangle tiles with one corner with four triangles, and two corners containing eight triangles.

In the 1987 book, Tilings and Patterns, Branko Grünbaum calls the vertex-uniform tilings Archimedean in parallel to the Archimedean solids, and their dual tilings Laves tilings in honor of crystallographer Fritz Laves.^[1] John Conway calls the duals Catalan tilings, in parallel to the Catalan solid polyhedra.^[2]

Convex uniform tilings of the Euclidean plane

Correspondence between families, as shown by labeled nodes of the Coxeter-Dynkin diagrams. The , [3^[3]] family symmetry is completely contained within , [6,3] symmetry cases. A doubling of the [4,4] symmetry produces another [4,4] symmetry.

All reflectional forms can be made by Wythoff constructions, represented by Wythoff symbols, or Coxeter-Dynkin diagrams, each operating upon one of three Schwarz triangle (4,4,2), (6,3,2), or (3,3,3), with symmetry represented by Coxeter groups: [4,4], [6,3], or [3^[3]]. Alternated forms such as the snub can also be represented by special markups within each system. Only one uniform tiling can't be constructed by a Wythoff process, but can be made by an elongation of the triangular tiling. An orthogonal mirror construction [∞,2,∞] also exists, seen as two sets of parallel mirrors making a rectangular fundamental domain. If the domain is square, this symmetry can be doubled by a diagonal mirror into the [4,4] family.

Families:

• (4,4,2), , [4,4] - Symmetry of the regular square tiling
  • , [∞,2,∞]
• (6,3,2), , [6,3] - Symmetry of the regular hexagonal tiling and triangular tiling.
  • (3,3,3), , [3^[3]]

The [4,4] group family

Uniform tilings (Platonic and Archimedean)	Vertex figure and dual face Wythoff symbol(s) Symmetry group Coxeter diagram(s)	Dual-uniform tilings (called Laves or Catalan tilings)
Square tiling (quadrille)	4.4.4.4 (or 44) 4 | 2 4 p4m, [4,4], (*442)	280px self-dual (quadrille)
Truncated square tiling (truncated quadrille)	100px100px 4.8.8 2 | 4 4 4 4 2 | p4m, [4,4], (*442)	Tetrakis square tiling (kisquadrille)
280px Snub square tiling (snub quadrille)	100px100px 3.3.4.3.4 | 4 4 2 p4g, [4+,4], (4*2)	280px Cairo pentagonal tiling (4-fold pentille)

The [6,3] group family

Platonic and Archimedean tilings	Vertex figure and dual face Wythoff symbol(s) Symmetry group Coxeter diagram(s)	Dual Laves tilings
280px Hexagonal tiling (hextille)	6.6.6 (or 63) 3 | 6 2 2 6 | 3 3 3 3 | p6m, [6,3], (*632)	Triangular tiling (deltille)
Trihexagonal tiling (hexadeltille)	100px (3.6)2 2 | 6 3 3 3 | 3 p6m, [6,3], (*632) =	Rhombille tiling (rhombille)
Truncated hexagonal tiling (truncated hextille)	3.12.12 2 3 | 6 p6m, [6,3], (*632)	Triakis triangular tiling (kisdeltille)
Triangular tiling (deltille)	100px 3.3.3.3.3.3 (or 36) 6 | 3 2 3 | 3 3 | 3 3 3 p6m, [6,3], (*632) =	Hexagonal tiling (hextille)
280px Rhombitrihexagonal tiling (rhombihexadeltille)	100px100px 3.4.6.4 3 | 6 2 p6m, [6,3], (*632)	Deltoidal trihexagonal tiling (tetrille)
Truncated trihexagonal tiling (truncated hexadeltille)	100px100px 4.6.12 2 6 3 | p6m, [6,3], (*632)	Kisrhombille tiling (kisrhombille)
280px Snub trihexagonal tiling (snub hextille)	100px100px 3.3.3.3.6 | 6 3 2 p6, [6,3]+, (632)	Floret pentagonal tiling (6-fold pentille)

Non-Wythoffian uniform tiling

Platonic and Archimedean tilings	Vertex figure and dual face Wythoff symbol(s) Symmetry group Coxeter diagram	Dual Laves tilings
Elongated triangular tiling (isosnub quadrille)	3.3.3.4.4 2 | 2 (2 2) cmm, [∞,2+,∞], (2*22)	Prismatic pentagonal tiling (iso(4-)pentille)

Uniform colorings

There are a total of 32 uniform colorings of the 11 uniform tilings:

1. Triangular tiling - 9 uniform colorings, 4 wythoffian, 5 nonwythoffian
   • 
2. Square tiling - 9 colorings: 7 wythoffian, 2 nonwythoffian
   • 
3. Hexagonal tiling - 3 colorings, all wythoffian
   • 
4. Trihexagonal tiling - 2 colorings, both wythoffian
   • 
5. Snub square tiling - 2 colorings, both alternated wythoffian
   • 
6. Truncated square tiling - 2 colorings, both wythoffian
   • 
7. Truncated hexagonal tiling - 1 coloring, wythoffian
   • 
8. Rhombitrihexagonal tiling - 1 coloring, wythoffian
   • 
9. Truncated trihexagonal tiling - 1 coloring, wythoffian
   • 
10. Snub hexagonal tiling - 1 coloring, alternated wythoffian
    • 
11. Elongated triangular tiling - 3 coloring, nonwythoffian
    • 

See also

• Uniform tiling
• Convex uniform honeycomb - The 28 uniform 3-dimensional tessellations, a parallel construction to the convex uniform Euclidean plane tilings.
• Uniform tilings in hyperbolic plane
• Percolation threshold

References

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Further reading

• John H. Conway, Heidi Burgiel, Chaim Goodman-Strass, The Symmetries of Things 2008, ISBN 978-1-56881-220-5 [1] (Chapter 19, Archimedean tilings, table 19.1, Chapter 21, Naming Archimedean and Catalan polyhedra and tilings, p288 table).
• H.S.M. Coxeter, M.S. Longuet-Higgins, J.C.P. Miller, Uniform polyhedra, Phil. Trans. 1954, 246 A, 401–50.
• Lua error in package.lua at line 80: module 'strict' not found. (Section 2–3 Circle packings, plane tessellations, and networks, pp 34–40).
• Asaro, et. al. "Uniform edge-c-colorings of the Archimedean Tilings", [2].
• Grünbaum, Branko & Shepard, Geoffrey (Nov. 1977). "Tilings by Regular polygons", Vol. 50, No. 5.
• Dale Seymour and Jill Britton, Introduction to Tessellations, 1989, ISBN 978-0866514613, pp. 50–57, 71-74

External links

• Weisstein, Eric W., "Uniform tessellation", MathWorld.
• Uniform Tessellations on the Euclid plane
• Tessellations of the Plane
• David Bailey's World of Tessellations
• k-uniform tilings
• n-uniform tilings

1. ↑ Lua error in package.lua at line 80: module 'strict' not found.
2. ↑ The Symmetries of things, Chapter 21, Naming the Archimedean and Catalan polyhedra and tilings, Euclidean Plane Tessellations, p. 288