Order-4-5 square honeycomb
Order-4-5 square honeycomb | |||
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Type | Regular honeycomb | ||
Schläfli symbols | {4,4,5} | ||
Coxeter diagrams | |||
Cells | {4,4} [[File:Uniform tiling 44-t0.svg | Faces | {4} |
Edge figure | {5} | ||
Vertex figure | {4,5} | ||
Dual | {5,4,4} | ||
Coxeter group | [4,4,5] | ||
Properties | Regular |
In the geometry of hyperbolic 3-space, the order-4-5 square honeycomb is a regular space-filling tessellation (or honeycomb) with Schläfli symbol {4,4,5}. It has five square tiling {4,4} around each edge. All vertices are ultra-ideal (existing beyond the ideal boundary) with infinitely many square tiling existing around each vertex in an order-5 square tiling vertex arrangement.
Images
[edit]Poincaré disk model |
Ideal surface |
Related polytopes and honeycombs
[edit]It a part of a sequence of regular polychora and honeycombs with square tiling cells: {4,4,p}
{4,4,p} honeycombs | |||||||||||
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Space | E3 | H3 | |||||||||
Form | Affine | Paracompact | Noncompact | ||||||||
Name | {4,4,2} | {4,4,3} | {4,4,4} | {4,4,5} | {4,4,6} | ...{4,4,∞} | |||||
Coxeter |
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Image | |||||||||||
Vertex figure |
{4,2} |
{4,3} |
{4,4} |
{4,5} |
{4,6} |
{4,∞} |
Order-4-6 square honeycomb
[edit]Order-4-6 square honeycomb | |
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Type | Regular honeycomb |
Schläfli symbols | {4,4,6} {4,(4,3,4)} |
Coxeter diagrams | = |
Cells | {4,4} |
Faces | {4} |
Edge figure | {6} |
Vertex figure | {4,6} {(4,3,4)} |
Dual | {6,4,4} |
Coxeter group | [4,4,6] [4,((4,3,4))] |
Properties | Regular |
In the geometry of hyperbolic 3-space, the order-4-6 square honeycomb is a regular space-filling tessellation (or honeycomb) with Schläfli symbol {4,4,6}. It has six square tiling, {4,4}, around each edge. All vertices are ultra-ideal (existing beyond the ideal boundary) with infinitely many square tiling existing around each vertex in an order-6 square tiling vertex arrangement.
Poincaré disk model |
Ideal surface |
It has a second construction as a uniform honeycomb, Schläfli symbol {4,(4,3,4)}, Coxeter diagram, , with alternating types or colors of square tiling cells. In Coxeter notation the half symmetry is [4,4,6,1+] = [4,((4,3,4))].
Order-4-infinite square honeycomb
[edit]Order-4-infinite square honeycomb | |
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Type | Regular honeycomb |
Schläfli symbols | {4,4,∞} {4,(4,∞,4)} |
Coxeter diagrams | = |
Cells | {4,4} |
Faces | {4} |
Edge figure | {∞} |
Vertex figure | {4,∞} {(4,∞,4)} |
Dual | {∞,4,4} |
Coxeter group | [∞,4,3] [4,((4,∞,4))] |
Properties | Regular |
In the geometry of hyperbolic 3-space, the order-4-infinite square honeycomb is a regular space-filling tessellation (or honeycomb) with Schläfli symbol {4,4,∞}. It has infinitely many square tiling, {4,4}, around each edge. All vertices are ultra-ideal (existing beyond the ideal boundary) with infinitely many square tiling existing around each vertex in an infinite-order square tiling vertex arrangement.
Poincaré disk model |
Ideal surface |
It has a second construction as a uniform honeycomb, Schläfli symbol {4,(4,∞,4)}, Coxeter diagram, = , with alternating types or colors of square tiling cells. In Coxeter notation the half symmetry is [4,4,∞,1+] = [4,((4,∞,4))].
See also
[edit]References
[edit]- Coxeter, 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 99-35678, ISBN 0-486-40919-8 (Chapter 10, Regular Honeycombs in Hyperbolic Space) Table III
- Jeffrey R. Weeks The Shape of Space, 2nd edition ISBN 0-8247-0709-5 (Chapters 16–17: Geometries on Three-manifolds I, II)
- George Maxwell, Sphere Packings and Hyperbolic Reflection Groups, JOURNAL OF ALGEBRA 79,78-97 (1982) [1]
- Hao Chen, Jean-Philippe Labbé, Lorentzian Coxeter groups and Boyd-Maxwell ball packings, (2013)[2]
- Visualizing Hyperbolic Honeycombs arXiv:1511.02851 Roice Nelson, Henry Segerman (2015)
External links
[edit]- John Baez, Visual insights: {7,3,3} Honeycomb (2014/08/01) {7,3,3} Honeycomb Meets Plane at Infinity (2014/08/14)
- Danny Calegari, Kleinian, a tool for visualizing Kleinian groups, Geometry and the Imagination 4 March 2014. [3]