Alternation (geometry)

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Two snub cubes from great rhombicuboctahedronSee that red and green dots are placed at alternate vertices. A snub cube is generated from deleting either set of vertices, one resulting in clockwise gyrated squares, and other counterclockwise.
Two snub cubes from great rhombicuboctahedron

See that red and green dots are placed at alternate vertices. A snub cube is generated from deleting either set of vertices, one resulting in clockwise gyrated squares, and other counterclockwise.

In geometry, an alternation (also called partial truncation) is an operation on a polyhedron or tiling that fully truncates alternate vertices. Only even-sided polyhedra can be alternated, for example the zonohedra. Every 2n-sided face becomes n-sided. Square faces disappear into new edges.

An alternation of a regular polyhedron or tiling is sometimes labeled by the regular form, prefixed by an h, standing for half. For example h{4,3} is an alternated cube (creating a tetrahedron), and h{4,4} is an alternated square tiling (still a square tiling).

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[edit] Snub

A snub is a related operation. It is an alternation applied to an omnitruncated regular polyhedron. An omnitruncated regular polyhedron or tiling always has even-sided faces and so can always be alternated.

For instance the snub cube is created in two steps. First it is omnitruncated, creating the great rhombicuboctahedron. Secondly that polyhedron is alternated into a snub cube. You can see from the picture on the right that there are two ways to alternate the vertices, and they are mirror images of each other, creating two chiral forms.

Another example is the uniform antiprisms. A uniform n-gonal antiprism can be constructed as an alternation of a 2n-gonal prism, and the snub of an n-edge hosohedron. In the case of prisms both alternated forms are identical.

Non-uniform zonohedra can also be alternated. For instance, the Rhombic triacontahedron can be snubbed into either an icosahedron or a dodecahedron depending on which vertices are removed.

[edit] Examples

[edit] Platonic solid generators

Three forms: regular --> omnitruncated --> snub.

The Coxeter-Dynkin diagrams are given as well. The omnitruncation actives all of the mirrors (ringed). The alternation is shown as rings with holes.

Symmetry
(p q 2)		 Regular
Image:CDW_ring.pngImage:CDW_p.pngImage:CDW_dot.pngImage:CDW_q.pngImage:CDW_dot.png		 Omnitruncated
Image:CDW_ring.pngImage:CDW_p.pngImage:CDW_ring.pngImage:CDW_q.pngImage:CDW_ring.png		 Snub
Image:CDW_hole.pngImage:CDW_p.pngImage:CDW_hole.pngImage:CDW_q.pngImage:CDW_hole.png
Tetrahedral
(3 3 2)
Tetrahedron
Image:CDW_ring.pngImage:CDW_3.pngImage:CDW_dot.pngImage:CDW_3.pngImage:CDW_dot.png
truncated octahedron
Image:CDW_ring.pngImage:CDW_3.pngImage:CDW_ring.pngImage:CDW_3.pngImage:CDW_ring.png
icosahedron
(snub tetrahedron)
Image:CDW_hole.pngImage:CDW_3.pngImage:CDW_hole.pngImage:CDW_3.pngImage:CDW_hole.png
Octahedral
(4 3 2)
Cube
Image:CDW_ring.pngImage:CDW_4.pngImage:CDW_dot.pngImage:CDW_3.pngImage:CDW_dot.png
Great rhombicuboctahedron
Image:CDW_ring.pngImage:CDW_4.pngImage:CDW_ring.pngImage:CDW_3.pngImage:CDW_ring.png
snub cube
Image:CDW_hole.pngImage:CDW_4.pngImage:CDW_hole.pngImage:CDW_3.pngImage:CDW_hole.png
Icosahedral
(5 3 2)
Dodecahedron
Image:CDW_ring.pngImage:CDW_5.pngImage:CDW_dot.pngImage:CDW_3.pngImage:CDW_dot.png
Great rhombicosidodecahedron
Image:CDW_ring.pngImage:CDW_5.pngImage:CDW_ring.pngImage:CDW_3.pngImage:CDW_ring.png
snub dodecahedron
Image:CDW_hole.pngImage:CDW_5.pngImage:CDW_hole.pngImage:CDW_3.pngImage:CDW_hole.png

[edit] Regular tiling generators

Symmetry
(p q 2)		 Regular
Image:CDW_ring.pngImage:CDW_p.pngImage:CDW_dot.pngImage:CDW_q.pngImage:CDW_dot.png		 Omnitruncated
Image:CDW_ring.pngImage:CDW_p.pngImage:CDW_ring.pngImage:CDW_q.pngImage:CDW_ring.png		 Snub
Image:CDW_hole.pngImage:CDW_p.pngImage:CDW_hole.pngImage:CDW_q.pngImage:CDW_hole.png
Square
(4 4 2)
(4.4.4.4)
Image:CDW_ring.pngImage:CDW_4.pngImage:CDW_dot.pngImage:CDW_4.pngImage:CDW_dot.png
(4.8.8)
Image:CDW_ring.pngImage:CDW_4.pngImage:CDW_ring.pngImage:CDW_4.pngImage:CDW_ring.png
(3.3.4.3.4)
Image:CDW_hole.pngImage:CDW_4.pngImage:CDW_hole.pngImage:CDW_4.pngImage:CDW_hole.png
Hexagonal
(6 3 2)
(6.6.6)
Image:CDW_ring.pngImage:CDW_6.pngImage:CDW_dot.pngImage:CDW_3.pngImage:CDW_dot.png
(3.4.6.4)
Image:CDW_ring.pngImage:CDW_6.pngImage:CDW_ring.pngImage:CDW_3.pngImage:CDW_ring.png
3.3.3.3.6
Image:CDW_hole.pngImage:CDW_6.pngImage:CDW_hole.pngImage:CDW_3.pngImage:CDW_hole.png

[edit] Uniform prism generators (dihedral symmetry)

Alternate truncations can be applied to prisms. (A square antiprism may be called a snubbed 4-edge hosohedron, as well as an alternated octagonal prism.)

Two steps: 2n-gonal prisms --> n-gonal antiprism.

[edit] Alternate truncations

A similar operation can truncate alternate vertices, rather than just removing them. Below is a set of polyhedra that can be generated from the duals of Catalan solids. These have two types of vertices which can be alternately truncated. Truncating the "higher order" vertices produces these forms:

Name Original Truncation Truncated name
Cube
Dual of rectified tetrahedron		 Alternate truncated cube
Rhombic dodecahedron
Dual of cuboctahedron		 Truncated rhombic dodecahedron
Rhombic triacontahedron
Dual of icosidodecahedron		 Truncated rhombic triacontahedron
Triakis tetrahedron
Dual of truncated tetrahedron		 Truncated triakis tetrahedron
Triakis octahedron
Dual of truncated cube		 Truncated triakis octahedron
Triakis icosahedron
Dual of truncated dodecahedron		 Truncated triakis icosahedron

[edit] Higher dimensions

This alternation operation applies to higher dimensional polytopes and honeycombs as well, however in general most forms won't have uniform solution. The voids created by the deleted vertices will not in general create uniform facets.

Examples:

[edit] See also

[edit] References

[edit] External links

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