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{{short description|Regular tiling of the plane}}
{{Uniform tiles db|Reg tiling stat table|Ut}}
In [[geometry]], the '''triangular tiling''' or '''triangular tessellation''' is one of the three regular [[tessellation|tiling]]s of the [[Euclidean plane]]. Because the internal angle of the equilateral [[triangle]] is 60 degrees, six triangles at a point occupy a full 360 degrees. The triangular tiling has [[Schläfli symbol]] of {3,6}.▼
▲In [[geometry]], the '''triangular tiling''' or '''triangular tessellation''' is one of the three
[[John Horton Conway|Conway]] calls it a '''deltille''', named from the triangular shape of the Greek letter delta (Δ). The triangular tiling can also be called a '''kishextille''' by a [[Conway kis operator|kis]] operation that adds a center point and triangles to replace the faces of a [[hextille]]. ▼
▲English mathematician [[John Horton Conway|John Conway]]
It is one of [[List_of_regular_polytopes#Euclidean_tilings|three regular tilings of the plane]]. The other two are the [[square tiling]] and the [[hexagonal tiling]].▼
▲It is one of [[
== Uniform colorings ==▼
▲== Uniform colorings ==
There are 9 distinct [[uniform coloring]]s of a triangular tiling. (Naming the colors by indices on the 6 triangles around a vertex: 111111, 111112, 111212, 111213, 111222, 112122, 121212, 121213, 121314) Three of them can be derived from others by repeating colors: 111212 and 111112 from 121213 by combining 1 and 3, while 111213 is reduced from 121314.<ref>Tilings and Patterns, p.102-107</ref>▼
[[File:Triangular_tiling_4-color.svg|thumb|A 2-uniform triangular tiling, 4 colored triangles, related to the [[geodesic polyhedron]] as {3,6+}<sub>2,0</sub>.]]
▲There are 9 distinct [[uniform coloring]]s of a triangular tiling. (Naming the colors by indices on the 6 triangles around a vertex: 111111, 111112, 111212, 111213, 111222, 112122, 121212, 121213, 121314) Three of them can be derived from others by repeating colors: 111212 and 111112 from 121213 by combining 1 and 3, while 111213 is reduced from 121314.<ref>''[[Tilings and
There is one class of [[Archimedean coloring]]s, 111112, (marked with a *) which is not 1-uniform, containing alternate rows of triangles where every third is colored. The example shown is 2-uniform, but there are infinitely many such Archimedean colorings that can be created by arbitrary horizontal shifts of the rows.
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|BGCOLOR="#c0c0ff"|111112(*)
|- align=center
|[[File:Uniform triangular tiling 111111.
|[[File:Uniform triangular tiling 121212.
|[[File:Uniform triangular tiling 111222.
|[[File:Uniform triangular tiling 112122.
|[[File:2-uniform_triangular_tiling_111112.
|- align=center
|p6m (*632)
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== A2 lattice and circle packings ==
{{distinguish|Strukturbericht designation#A-compounds{{!}}the A2 crystal lattice structure in the Strukturbericht classification system}}
[[File:Compound 3 triangular tilings.
The [[vertex arrangement]] of the triangular tiling is called an [[Root system#Explicit construction of the irreducible root systems|A<sub>2</sub> lattice]].<ref>{{Cite web|url=http://www.math.rwth-aachen.de/~Gabriele.Nebe/LATTICES/A2.html|title = The Lattice A2}}</ref> It is the 2-dimensional case of a [[simplectic honeycomb]].
The A{{sup sub|*|2}} lattice (also called A{{sup sub|3|2}}) can be constructed by the union of all three A<sub>2</sub> lattices, and equivalent to the A<sub>2</sub> lattice.
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== Geometric variations ==
Triangular tilings can be made with the equivalent {3,6} topology as the regular tiling (6 triangles around every vertex). With identical faces ([[Face-transitive|face-transitivity]]) and [[vertex-transitive|vertex-transitivity]], there are 5 variations. Symmetry given assumes all faces are the same color.<ref>''[[Tilings and Patterns]]'', from list of 107 isohedral tilings, p.473-481</ref>
<gallery>
Isohedral_tiling_p3-11.
Isohedral_tiling_p3-12.
Isohedral_tiling_p3-13.
Isohedral_tiling_p3-11b.png|[[Right triangle]]<BR/>cmm symmetry
Isohedral_tiling_p3-14.
</gallery>
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{| class="wikitable"
|- align=center
|[[File:Triakistetrahedron.jpg|60px]]<BR/>[[Triakis tetrahedron|V3.6.6]]
|[[File:Tetrakishexahedron.jpg|60px]]<BR/>[[Tetrakis hexahedron|V4.6.6]]
|[[File:Pentakisdodecahedron.jpg|60px]]<BR/>[[Pentakis dodecahedron|V5.6.6]]
|[[File:Uniform polyhedron-63-t2.
|[[File:
|}
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{| class=wikitable
|-
|[[File:Complex apeirogon 2-6-6.
|[[File:Complex apeirogon 3-4-6.png|160px]]
|[[File:Complex apeirogon 3-6-3.png|160px]]
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{| class=wikitable
|- align=center valign=bottom
|[[File:1-uniform 3 dual.svg|240px]]<br/>[[Kisrhombille tiling|Kisrhombille]]<BR/>30°-60°-90° right triangles
|[[File:1-uniform 2 dual.svg|240px]]<br/>[[Tetrakis square tiling|Kisquadrille]]<BR/>45°-45°-90° right triangles
|[[File:1-uniform 4 dual.svg|240px]]<br/>[[Triakis triangular tiling|Kisdeltile]]<BR/>30°-30°-120° isosceles triangles
|}
==See also==
{{
* [[Triangular tiling honeycomb]]
* [[Simplectic honeycomb]]
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== References ==
{{
== Sources ==
* [[Coxeter|Coxeter, H.S.M.]] ''[[Regular Polytopes (book)|Regular Polytopes]]'', (3rd edition, 1973), Dover edition, {{isbn|0-486-61480-8}} p. 296, Table II: Regular honeycombs
* {{cite book | author=
* {{The Geometrical Foundation of Natural Structure (book)}} p35
* John H. Conway, Heidi Burgiel, Chaim Goodman-
== External links ==
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