Socolar tiling

There are 3 Socolar tile, a 30° rhombus, square, and a regular hexagon with tiling rules defined by the fins.	The rules of tiling can fill a regular dodecagon.

Pattern blocks

contain the 3 tiles and 3 more.

A Socolar tiling is an example of an aperiodic tiling, developed in 1989 by Joshua Socolar in the exploration of quasicrystals.^[1] There are 3 tiles a 30° rhombus, square, and regular hexagon. The 12-fold symmetry set exist similar to the 10-fold Penrose rhombic tilings, and 8-fold Ammann–Beenker tilings.^[2]

The 12-fold tiles easily tile periodically, so special rules are defined to limit their connections and force nonperiodic tilings. The rhombus and square are disallowed from touching another of itself, while the hexagon can connect to both tiles as well as itself, but only in alternate edges.

Dodecagonal rhomb tiling

The dodecagonal rhomb tiling include three tiles, a 30° rhombus, a 60° rhombus, and a square.^[3] And expanded set can also include an equilateral triangle, half of the 60° rhombus.60° rhombus.^[4]

References

PMID 9947860

^ "Tilings Encyclopedia | Socolar".

^ Crystallography of Quasicrystals: Concepts, Methods and Structures, By Steurer Walter, Sofia Deloudi, pp. 40-41 [1]

^ A Quasiperiodic Tiling With 12-Fold Rotational Symmetry and Inflation Factor 1 + √3 Theo P. Schaad and Peter Stampfli, 10 Feb 2021

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Tessellation
Periodic

Pythagorean

Rhombille

Schwarz triangle

Rectangle
Domino

Uniform tiling and honeycomb
Coloring

Convex

Kisrhombille

Wallpaper group

Wythoff

Aperiodic

Ammann–Beenker

Aperiodic set of prototiles
List

Einstein problem
Socolar–Taylor

Gilbert

Penrose

Pentagonal

Pinwheel

Quaquaversal

Rep-tile and Self-tiling
Sphinx

Socolar

Truchet

Other

Anisohedral and Isohedral

Architectonic and catoptric

Circle Limit III

Computer graphics

Honeycomb

Isotoxal

List

Packing

Problems
Domino

Wang

Heesch's

Squaring

Dividing a square into similar rectangles

Prototile
Conway criterion

Girih

Regular Division of the Plane

Regular grid

Substitution

Voronoi

Voderberg

By vertex type
Spherical

2ⁿ

3³.n

V3³.n

4².n

V4².n

Regular

2^∞

3⁶

4⁴

6³

Semi-
regular

3².4.3.4

V3².4.3.4

3³.4²

3³.∞

3⁴.6

V3⁴.6

3.4.6.4

(3.6)²

3.12²

4².∞

4.6.12

4.8²

Hyper-
bolic

3².4.3.5

3².4.3.6

3².4.3.7

3².4.3.8

3².4.3.∞

3².5.3.5

3².5.3.6

3².6.3.6

3².6.3.8

3².7.3.7

3².8.3.8

3³.4.3.4

3².∞.3.∞

3⁴.7

3⁴.8

3⁴.∞

3⁵.4

3⁷

3⁸

3^∞

(3.4)³

(3.4)⁴

3.4.6².4

3.4.7.4

3.4.8.4

3.4.∞.4

3.6.4.6

(3.7)²

(3.8)²

3.14²

3.16²

3.∞²

4².5.4

4².6.4

4².7.4

4².8.4

4².∞.4

4⁵

4⁶

4⁷

4⁸

4^∞

(4.5)²

(4.6)²

4.6.12

4.6.14

V4.6.14

4.6.16

V4.6.16

4.6.∞

(4.7)²

(4.8)²

4.8.10

V4.8.10

4.8.12

4.8.14

4.8.16

4.8.∞

4.10²

4.10.12

4.12²

4.12.16

4.14²

4.16²

4.∞²

5⁴

5⁵

5⁶

5^∞

5.4.6.4

(5.6)²

5.8²

5.10²

5.12²

6⁴

6⁵

6⁶

6⁸

6.4.8.4

(6.8)²

6.8²

6.10²

6.12²

6.16²

7³

7⁴

7⁷

7.6²

7.8²

7.14²

8³

8⁴

8⁶

8⁸

8.6²

8.12²

8.16²

∞³

∞⁴

∞⁵

∞^∞

∞.6²

∞.8²

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Retrieved from "https://en.wikipedia.org/w/index.php?title=Socolar_tiling&oldid=1175272092"

[1] PMID 9947860

[2] "Tilings Encyclopedia | Socolar".

[3] Crystallography of Quasicrystals: Concepts, Methods and Structures, By Steurer Walter, Sofia Deloudi, pp. 40-41 [1]

[4] A Quasiperiodic Tiling With 12-Fold Rotational Symmetry and Inflation Factor 1 + √3 Theo P. Schaad and Peter Stampfli, 10 Feb 2021

[1]

[2]

[3]

[4]

Dodecagonal rhomb tiling

See also

References