User:Mike40033/List of regular polytopes

This page lists the regular polytopes in Euclidean, spherical and hyperbolic spaces.

The Schläfli symbol notation describes every regular polytope, and is used widely below as a compact reference name for each.

The regular polytopes are grouped by dimension and subgrouped by convex, nonconvex and infinite forms. Nonconvex forms use the same vertices as the convex forms, but have intersecting facets. Infinite forms tessellate a one lower dimensional Euclidean space.

Infinite forms can be extended to tessellate a hyperbolic space. Hyperbolic space is like normal space at a small scale, but parallel lines diverge at a distance. This allows vertex figures to have negative angle defects, like making a vertex with 7 equilateral triangles and allowing it to lie flat. It can't be done in a regular plane, but can be at the right scale of a hyperbolic plane.

Regular polytope summary count by dimension[edit]

Dimension	Convex	Nonconvex	Convex Euclidean tessellations	Convex hyperbolic tessellations	Nonconvex hyperbolic tessellations
2	∞ polygons	∞ star polygons	1	1
3	5 Platonic solids	4 Kepler-Poinsot solids	3 tilings	∞	∞
4	6 convex polychora	10 Schläfli-Hess polychora	1 honeycomb	4	0
5	3 convex 5-polytopes	0 nonconvex 5-polytopes	3 tessellations	5	4
6+	3	0	1	0	0

Two-dimensional regular polytopes[edit]

The two dimensional polytopes are called polygons. Regular polygons are equilateral and cyclic.

Usually only convex polygons are considered regular, but star polygons, like the pentagram, can also be considered regular. They use the same vertices as the convex forms, but connect in an alternate connectivity which passes around the circle more than once to complete.

Star polygons should be called nonconvex rather than concave because the intersecting edges do not generate new vertices and all the vertices exist on a circle boundary.

Three-dimensional regular polytopes[edit]

In three dimensions, the regular polytopes are called polyhedra:

A regular polyhedron with Schläfli symbol {p,q} has a regular face type {p}, and regular vertex figure {q}.

A polyhedral vertex figure is an imaginary polygon which can be seen by connecting those vertices which are one edge away from a given vertex. For regular polyhedra, this vertex figure is always a regular (and planar) polygon.

Existence of a regular polyhedron {p,q} is constrained by an inequality, related to the vertex figure's angle defect:

1/p + 1/q > 1/2 : Polyhedron (existing in Euclidean 3-space)
1/p + 1/q = 1/2 : Euclidean plane tiling
1/p + 1/q < 1/2 : Hyperbolic plane tiling

By enumerating the permutations, we find 6 convex forms, 10 nonconvex forms and 3 plane tilings, all with polygons {p} and {q} limited to: {3}, {4}, {5}, {5/2}, and {6}.

Beyond Euclidean space, there's an infinite set of regular hyperbolic tilings.

Four-dimensional regular polytopes[edit]

Regular polychora with Schläfli symbol symbol {p,q,r} have cells of type {p,q}, faces of type {p}, edge figures {r}, and vertex figures {q,r}.

A polychoral vertex figure is an imaginary polyhedron that can be seen by the arrangement of neighboring vertices around a given vertex. For regular polychora, this vertex figure is a regular polyhedron.

A polychoral edge figure is an imaginary polygon that can be seen by the arrangement of faces around an edge. For regular polychora, this edge figure will always be a regular polygon.

The existence of a regular polychoron {p,q,r} is constrained by the existence of the regular polyhedra {p,q}, {q,r}.

Each will exist in a space dependent upon this expression:

sin(π/p) sin(π/r) − cos(π/q)
- > 0 : Hyperspherical surface polychoron (in 4-space)
- = 0 : Euclidean 3-space honeycomb
- < 0 : Hyperbolic 3-space honeycomb

These constraints allow for 21 forms: 6 are convex, 10 are nonconvex, one is a Euclidean 3-space honeycomb, and 4 are hyperbolic honeycombs.

The Euler characteristic χ for polychora is χ = V + F − E − C and is zero for all forms.

Five-dimensional regular polytopes[edit]

In five dimensions, a regular polytope can be named as {p,q,r,s} where {p,q,r} is the hypercell (or teron) type, {p,q} is the cell type, {p} is the face type, and {s} is the face figure, {r,s} is the edge figure, and {q,r,s} is the vertex figure.

A 5-polytope has been called a polyteron, and if infinite (i.e. a honeycomb) a 5-polytope can be called a tetracomb.

A polyteron vertex figure is an imaginary polychoron that can be seen by the arrangement of neighboring vertices to each vertex.

A polyteron edge figure is an imaginary polyhedron that can be seen by the arrangement of faces around each edge.

A polyteron face figure is an imaginary polygon that can be seen by the arrangement of cells around each face.

A regular polytope {p,q,r,s} exists only if {p,q,r} and {q,r,s} are regular polychora.

The space it fits in is based on the expression:

(cos²(π/q)/sin²(π/p)) + (cos²(π/r)/sin²(π/s))
- < 1 : Spherical polytope
- = 1 : Euclidean 4-space tessellation
- > 1 : hyperbolic 4-space tessellation

Enumeration of these constraints produce 3 convex polytopes, zero nonconvex polytopes, 3 4-space tessellations, and 5 hyperbolic 4-space tessellations.

Classical Convex Polytopes[edit]

Two Dimensions[edit]

The Schläfli symbol {p} represents a regular p-gon:

The infinite set of convex regular polygons are:

Name	Schläfli Symbol {p}
equilateral triangle	{3}
square	{4}
pentagon	{5}
hexagon	{6}
heptagon	{7}
octagon	{8}
enneagon	{9}
decagon	{10}
Hendecagon	{11}
Dodecagon	{12}
...n-gon	{n}

{3}	{4}	{5}	{6}	{7}	{8}	{9}	{10}	{11}	{12}

A digon, {2}, can be considered a degenerate regular polygon.

Three Dimensions[edit]

The convex regular polyhedra are called the 5 Platonic solids:

Name	Schläfli Symbol {p,q}	Faces {p}	Edges	Vertices {q}	χ	Symmetry	dual
Tetrahedron	{3,3}	4 {3}	6	4 {3}	2	T_d	Self-dual
Cube (hexahedron)	{4,3}	6 {4}	12	8 {3}	2	O_h	Octahedron
Octahedron	{3,4}	8 {3}	12	6 {4}	2	O_h	Cube
Dodecahedron	{5,3}	12 {5}	30	20 {3}	2	I_h	Icosahedron
Icosahedron	{3,5}	20 {3}	30	12 {5}	2	I_h	Dodecahedron

{3,3}	{4,3}	{3,4}	{5,3}	{3,5}

In spherical geometry, hosohedron, {2,n} and dihedron {n,2} can be considered regular polyhedra (tilings of the sphere).

Four Dimensions[edit]

The 6 convex polychora are as follows:

Name	Schläfli Symbol {p,q,r}	Cells {p,q}	Faces {p}	Edges {r}	Vertices {q,r}	Dual {r,q,p}
5-cell (pentachoron)	{3,3,3}	5 {3,3}	10 {3}	10 {3}	5 {3,3}	Self-dual
8-cell (Tesseract)	{4,3,3}	8 {4,3}	24 {4}	32 {3}	16 {3,3}	16-cell
16-cell	{3,3,4}	16 {3,3}	32 {3}	24 {4}	8 {3,4}	Tesseract
24-cell	{3,4,3}	24 {3,4}	96 {3}	96 {3}	24 {4,3}	Self-dual
120-cell	{5,3,3}	120 {5,3}	720 {5}	1200 {3}	600 {3,3}	600-cell
600-cell	{3,3,5}	600 {3,3}	1200 {3}	720 {5}	120 {3,5}	120-cell

Stereoscopic projections

{3,3,3}	{4,3,3}	{3,3,4}	{3,4,3}	{5,3,3}	{3,3,5}

Five Dimensions[edit]

There are three kinds of convex regular polytopes in five dimensions:

Name	Schläfli Symbol {p,q,r,s}	Facets {p,q,r}	Cells {p,q}	Faces {p}	Edges	Vertices	Face figure {s}	Edge figure {r,s}	Vertex figure {q,r,s}	Dual
5-simplex (or hexateron)	{3,3,3,3}	6 {3,3,3}	15 {3,3}	20 {3}	15	6	{3}	{3,3}	{3,3,3}	Self-dual
measure 5-polytope (or decateron or penteract)	{4,3,3,3}	10 {4,3,3}	40 {4,3}	80 {4}	80	32	{3}	{3,3}	{3,3,3}	triacontaditeron
cross-5-polytope (or triacontaditeron or pentacross)	{3,3,3,4}	32 {3,3,3}	80 {3,3}	80 {3}	40	10	{4}	{3,4}	{3,3,4}	decateron

Higher dimensions[edit]

In dimensions 5 and higher , there are only three kinds of convex regular polytopes.

Name	Schläfli Symbol {p₁,p₂,...,p_n-1}	Facet type	Vertex figure	Dual
n-simplex	{3,3,3,...,3}	{3,3,...,3}	{3,3,...,3}	Self-dual
measure n-polytope	{4,3,3,...,3}	{4,3,...,3}	{3,3,...,3}	cross-n-polytope
cross-n-polytope	{3,...,3,3,4}	{3,...,3,3}	{3,...,3,4}	measure n-polytope

Finite Non-Convex Polytopes - Stellations[edit]

Two Dimensions[edit]

There exist non-convex regular polytopes in two dimensions, whose Schläfli symbols consist of rational numbers: star polygons.

In general, for any natural number n, there are n-pointed non-convex regular polygonal stars with Schläfli symbols {n/m} for all m such that m < n/2 (strictly speaking {n/m}={n/(n-m)}) and m and n are coprime.

Name	Schläfli Symbol {n/m}
pentagram	{5/2}
heptagrams	{7/2}, {7/3}
octagram	{8/3}
enneagrams	{9/2}, {9/4}
decagram	{10/3}
hendecagrams	{11/2} {11/3}, {11/4}, {11/5}
dodecagram	{12/5}
...n-agrams	{n/m}

{5/2}	{7/2}	{7/3}	{8/3}