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{{Honeycomb}}
== Symmetry ==
[[File:Hyperbolic subgroup tree 363.png|left|thumb|Subgroups of [3,6,3] and [6,3,6]]]
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It has two lower reflective symmetry constructions, as an [[Alternation (geometry)|alternated]] [[order-6 hexagonal tiling honeycomb]], {{CDD|node_h1|6|node|3|node|6|node}} ↔ {{CDD|branch_10ru|split2|node|6|node}}, and as {{CDD|node_1|splitsplit1|branch4|splitsplit2|node}} from {{CDD|node_1|3|node|6|node_g|3sg|node_g}}, which alternates 3 types (colors) of triangular tilings around every edge. In [[Coxeter notation]], the removal of the 3rd and 4th mirrors, [3,6,3<sup>*</sup>] creates a new [[Coxeter group]] [3<sup>[3,3]</sup>], {{CDD|node|splitsplit1|branch4|splitsplit2|node}}, subgroup index 6. The fundamental ___domain is 6 times larger. By Coxeter diagram there are 3 copies of the first original mirror in the new fundamental ___domain: {{CDD|node_c2|3|node_c1|6|node|3|node}} ↔ {{CDD|node_c2|splitsplit1|branch4_c1|splitsplit2|node_c1}}.
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== Related Tilings ==
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[[File:H3 363 boundary 0100.png|480px]]
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=== Truncated triangular tiling honeycomb===
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[[File:H3 363-1100.png|480px]]
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=== Bitruncated triangular tiling honeycomb===
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[[File:H3 363-0110.png|480px]]
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=== Cantellated triangular tiling honeycomb===
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[[File:H3 363-1010.png|480px]]
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=== Cantitruncated triangular tiling honeycomb===
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[[File:H3 363-1110.png|480px]]
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=== Runcinated triangular tiling honeycomb===
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[[File:H3 363-1001.png|480px]]
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=== Runcitruncated triangular tiling honeycomb===
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[[File:H3 363-1101.png|480px]]
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=== Omnitruncated triangular tiling honeycomb===
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[[File:H3 363-1111.png|480px]]
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=== Runcisnub triangular tiling honeycomb===
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The '''runcisnub triangular tiling honeycomb''', {{CDD|node_h|3|node_h|6|node|3|node_1}}, has [[trihexagonal tiling]], [[triangular tiling]], [[triangular prism]], and [[triangular cupola]] cells. It is [[vertex-transitive]], but not uniform, since it contains [[Johnson solid]] [[triangular cupola]] cells.
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== See also ==
* [[Convex uniform honeycombs in hyperbolic space]]
* [[
* [[Paracompact uniform honeycomb]]s
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*[[H.S.M. Coxeter|Coxeter]], ''[[Regular Polytopes (book)|Regular Polytopes]]'', 3rd. ed., Dover Publications, 1973. {{isbn|0-486-61480-8}}. (Tables I and II: Regular polytopes and honeycombs, pp. 294–296)
* ''The Beauty of Geometry: Twelve Essays'' (1999), Dover Publications, {{LCCN|99035678}}, {{isbn|0-486-40919-8}} (Chapter 10, [http://www.mathunion.org/ICM/ICM1954.3/Main/icm1954.3.0155.0169.ocr.pdf Regular Honeycombs in Hyperbolic Space]) Table III
* [[Jeffrey Weeks (mathematician)|Jeffrey R. Weeks]] ''The Shape of Space, 2nd edition'' {{isbn|0-8247-0709-5}} (Chapter 16-17: Geometries on Three-manifolds I, II)
* [[Norman Johnson (mathematician)|Norman Johnson]] ''Uniform Polytopes'', Manuscript
** [[Norman Johnson (mathematician)|N.W. Johnson]]: ''The Theory of Uniform Polytopes and Honeycombs'', Ph.D. Dissertation, University of Toronto, 1966
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