600-cell

The vertices of a 600-cell of unit radius centered at the origin of 4-space, with edges of length 1/φ ≈ 0.618 (where φ = 1 + √5/2 ≈ 1.618 is the golden ratio), can be given[6] as follows:

8 vertices obtained from

(0, 0, 0, ±1)

by permuting coordinates, and 16 vertices of the form:

(±1/2, ±1/2, ±1/2, ±1/2)

The remaining 96 vertices are obtained by taking even permutations of

1/2(±φ, ±1, ±1/φ, 0)

Note that the first 8 are the vertices of a 16-cell, the second 16 are the vertices of a tesseract, and those 24 vertices together are the vertices of a 24-cell. The remaining 96 vertices are the vertices of a snub 24-cell, which can be found by partitioning each of the 96 edges of another 24-cell (dual to the first) in the golden ratio in a consistent manner.[7]

When interpreted as quaternions, these are the unit icosians.

The 120 vertices can be seen as the vertices of 4 sets of 6 orthogonal equatorial pentagons which do not share any vertices.[lower-alpha 4]

The mutual distances of the vertices, measured in degrees of arc on the circumscribed hypersphere, only have the values 36° = 𝜋/5, 60° = 𝜋/3, 72° = 2𝜋/5, 90° = 𝜋/2, 108° = 3𝜋/5, 120° = 2𝜋/3, 144° = 4𝜋/5, and 180° = 𝜋. Departing from an arbitrary vertex V one has at 36° and 144° the 12 vertices of an icosahedron, at 60° and 120° the 20 vertices of a dodecahedron, at 72° and 108° the 12 vertices of a larger icosahedron, at 90° the 30 vertices of an icosidodecahedron, and finally at 180° the antipodal vertex of V.[8] These can be seen in the H3 Coxeter plane projections with overlapping vertices colored.[9]

In the 24-cell, there are squares, hexagons and triangles that lie on great circles (in equatorial planes through four or six vertices).[lower-alpha 5] In the 600-cell there are twenty-five overlapping inscribed 24-cells, with each square unique to one 24-cell, each hexagon or triangle shared by two 24-cells, and each vertex shared among five 24-cells.[lower-alpha 7]

In the 600-cell there are also great circle pentagons and decagons (in equatorial planes through ten vertices).[lower-alpha 8]

Only the decagon edges are visible elements of the 600-cell (because they are the edges of the 600-cell). The edges of the other great circle polygons are interior chords of the 600-cell, which are not shown in any of the 600-cell renderings in this article.

By symmetry, an equal number of polygons of each kind pass through each vertex; so it is possible to account for all 120 vertices as the intersection of a set of polygons of any one kind.

Vertex geometry of the 600-cell, showing the 5 regular great circle polygons and the 8 vertex-to-vertex chord lengths[lower-alpha 5] with angles of arc. The golden ratio[lower-alpha 9] governs the fractional roots of every other chord,[lower-alpha 10] and the radial golden triangles[lower-alpha 11] which meet at the center.

The 120 vertices are distributed[11] at eight different chord lengths from each other. These edges and chords of the 600-cell are simply the edges and chords of its five great circle polygons.[12] In ascending order of length, they are √0.𝚫, √1, √1.𝚫, √2, √2.𝚽, √3, √3.𝚽, and √4.[lower-alpha 12]

Notice that the four hypercubic chords of the 24-cell (√1, √2, √3, √4) alternate with the four new chords of the 600-cell's additional great circles, the decagons and pentagons. The new chord lengths are necessarily square roots of fractions, but very special fractions related to the golden ratio[lower-alpha 9] including the two golden sections of √5, as shown in the diagram.[lower-alpha 10]

The vertex chords of the 600-cell are arranged in geodesic great circle polygons of five kinds: decagons, hexagons, pentagons, squares, and triangles.[13]

The √0.𝚫 = 𝚽 edges form 72 flat regular central decagons, 6 of which cross at each vertex.[lower-alpha 1] Just as the icosidodecahedron can be partitioned into 6 central decagons (60 edges = 6 × 10), the 600-cell can be partitioned into 72 decagons (720 edges = 72 × 10). The 720 √0.𝚫 edges divide the surface into 1200 triangular faces and 600 tetrahedral cells: a 600-cell. The 720 edges occur in 360 parallel pairs, √3.𝚽 apart. As in the decagon and the icosidodecahedron, the edges occur in golden triangles[lower-alpha 14] which meet at the center of the polytope.[lower-alpha 11]

The √1 chords form 200 central hexagons (25 sets of 16, with each hexagon in two sets),[lower-alpha 6] 10 of which cross at each vertex (4 from each of five 24-cells, with each hexagon in two of the 24-cells). Each set of 16 hexagons consists of the 96 edges and 24 vertices of one of the 25 overlapping inscribed 24-cells. The √1 chords join vertices which are two √0.𝚫 edges apart. Each √1 chord is the long diameter of a face-bonded pair of tetrahedral cells (a triangular bipyramid), and passes through the center of the shared face. As there are 1200 faces, there are 1200 √1 chords, in 600 parallel pairs, √3 apart.

The √1.𝚫 chords form 144 central pentagons, 6 of which cross at each vertex.[lower-alpha 8] The √1.𝚫 chords run vertex-to-every-second-vertex in the same planes as the 72 decagons: two pentagons are inscribed in each decagon. The √1.𝚫 chords join vertices which are two √0.𝚫 edges apart on a geodesic great circle. The 720 √1.𝚫 chords occur in 360 parallel pairs, √2.𝚽 = φ apart.

The √2 chords form 450 central squares (25 disjoint sets of 18), 15 of which cross at each vertex (3 from each of five 24-cells). Each set of 18 squares consists of the 72 √2 chords and 24 vertices of one of the 25 overlapping inscribed 24-cells. The √2 chords join vertices which are three √0.𝚫 edges apart (and two √1 chords apart). Each √2 chord is the long diameter of an octahedral cell in just one 24-cell. There are 1800 √2 chords, in 900 parallel pairs, √2 apart.

The √2.𝚽 = φ chords form the legs of 720 central isosceles triangles (72 sets of 10 inscribed in each decagon), 6 of which cross at each vertex. The third edge (base) of each isosceles triangle is of length √3.𝚽. The √2.𝚽 chords run vertex-to-every-third-vertex in the same planes as the 72 decagons, joining vertices which are three √0.𝚫 edges apart on a geodesic great circle. There are 720 distinct √2.𝚽 chords, in 360 parallel pairs, √1.𝚫 apart.

The √3 chords form 400 equilateral central triangles (25 sets of 32, with each triangle in two sets), 20 of which cross at each vertex (4 from each of five 24-cells). Each set of 32 triangles consists of the 96 √3 chords and 24 vertices of one of the 25 overlapping inscribed 24-cells. The √3 chords run vertex-to-every-other-vertex in the same planes as the 200 hexagons: two triangles are inscribed in each hexagon. The √3 chords join vertices which are four √0.𝚫 edges apart (and two √1 chords apart on a geodesic great circle). Each √3 chord is the long diameter of two cubic cells in the same 24-cell.[lower-alpha 15] There are 1200 √3 chords, in 600 parallel pairs, √1 apart.

The √3.𝚽 chords (the diagonals of the pentagons) form the legs of 720 central isosceles triangles (144 sets of 5 inscribed in each pentagon), 6 of which cross at each vertex. The third edge (base) of each isosceles triangle is an edge of the pentagon of length √1.𝚫, so these are golden triangles.[lower-alpha 14] The √3.𝚽 chords run vertex-to-every-fourth-vertex in the same planes as the 72 decagons, joining vertices which are four √0.𝚫 edges apart on a geodesic great circle. There are 720 distinct √3.𝚽 chords, in 360 parallel pairs, √0.𝚫 apart.

The √4 chords occur as 60 long diameters (75 sets of 4 orthogonal axes), the 120 long radii of the 600-cell. The √4 chords join opposite vertices which are five √0.𝚫 edges apart on a geodesic great circle. There are 25 distinct but overlapping sets of 12 diameters, each comprising one of the 25 inscribed 24-cells.[lower-alpha 16]

The sum of the squared lengths[lower-alpha 17] of all these distinct chords of the 600-cell is 14,400 = 120².[lower-alpha 18]

The 600-cell rounds out the 24-cell by adding 96 more vertices between the 24-cell's existing 24 vertices, in effect adding twenty-four more overlapping 24-cells inscribed in the 600-cell.[lower-alpha 19] The new surface thus formed is a tessellation of smaller, more numerous cells[lower-alpha 20] and faces: tetrahedra of edge length 1/φ ≈ 0.618 instead of octahedra of edge length 1. It encloses the √1 edges of the 24-cells, which become interior chords in the 600-cell, like the √2 and √3 chords.

Since the tetrahedra are made of shorter triangle edges than the octahedra (by a factor of 1/φ, the inverse golden ratio), the 600-cell does not have unit edge-length in a unit-radius coordinate system the way the 24-cell and the tesseract do; unlike those two, the 600-cell is not radially equilateral. Like them it is radially triangular in a special way, but one in which golden triangles rather than equilateral triangles meet at the center.[lower-alpha 11]

The boundary envelope of 600 small tetrahedral cells wraps around the twenty-five envelopes of 24 octahedral cells (adding some 4-dimensional space in places between these 3-dimensional envelopes). The shape of those interstices must be an octahedral 4-pyramid of some kind, but in the 600-cell it is not regular.[lower-alpha 21]

The 600-cell incorporates the geometries of every convex regular polytope in the first four dimensions, except the 5-cell, the 120-cell, and the polygons {7} and above.[16] Consequently, there are numerous ways to construct or deconstruct the 600-cell, but none of them are trivial. The construction of the 600-cell from its regular predecessor the 24-cell can be difficult to visualize.

Thorold Gosset discovered the semiregular 4-polytopes, including the snub 24-cell with 96 vertices, which falls between the 24-cell and the 600-cell in the sequence of convex 4-polytopes of increasing size and complexity in the same radius. Gosset's construction of the 600-cell from the 24-cell is in two steps, using the snub 24-cell as an intermediate form. In the first, more complex step (described elsewhere) the snub 24-cell is constructed by a special snub truncation of a 24-cell at the golden sections of its edges.[7] In the second step the 600-cell is constructed in a straightforward manner by adding 4-pyramids (vertices) to facets of the snub 24-cell.[17]

The snub 24-cell is a diminished 600-cell from which 24 vertices (and the cluster of 20 tetrahedral cells around each) have been truncated, leaving a "flat" icosahedral cell in place of each removed icosahedral pyramid.[lower-alpha 1] The snub 24-cell thus has 24 icosahedral cells and the remaining 120 tetrahedral cells. The second step of Gosset's construction of the 600-cell is simply the reverse of this diminishing: an icosahedral pyramid of 20 tetrahedral cells is placed on each icosahedral cell.

Constructing the unit-radius 600-cell from its precursor the unit-radius 24-cell by Gosset's method actually requires three steps. The 24-cell precursor to the snub-24 cell is not of the same radius: it is larger, since the snub-24 cell is its truncation. Starting with the unit-radius 24-cell, the first step is to reciprocate it around its midsphere to construct its outer canonical dual: a larger 24-cell, since the 24-cell is self-dual. That larger 24-cell can then be snub truncated into a unit-radius snub 24-cell.

Since it is so indirect, Gosset's construction may not help us very much to directly visualize how the 600 tetrahedral cells fit together into a 3-dimensional surface envelope,[lower-alpha 20] or how they lie on the underlying surface envelope of the 24-cell's octahedral cells. For that it is helpful to build up the 600-cell directly from clusters of tetrahedral cells.

Most of us have difficulty visualizing the 600-cell from the outside in 4-space, or recognizing an outside view of the 600-cell due to our total lack of sensory experience in 4-dimensional spaces, but we should be able to visualize the surface envelope of 600 cells from the inside because that volume is a 3-dimensional space that we could actually "walk around in" and explore.[18] In this exercise of building the 600-cell up from cell clusters, we are entirely within a 3-dimensional space, albeit a strangely small, closed curved one, in which we can go a mere ten edge lengths away in a straight line in any direction and return to our starting point.

A regular icosahedron colored in snub octahedron symmetry.[lower-alpha 22] Icosahedra in the 600-cell are face bonded to each other at the yellow faces, and to clusters of 5 tetrahedral cells at the blue faces. The apex of the icosahedral pyramid (not visible) is a 13th 600-cell vertex inside the icosahedron (but above its hyperplane).

A cluster of 5 tetrahedral cells: four cells face-bonded around a fifth cell (not visible). The four cells lie in different hyperplanes.

The vertex figure of the 600-cell is the icosahedron.[lower-alpha 1] Twenty tetrahedral cells meet at each vertex, forming an icosahedral pyramid whose apex is the vertex, surrounded by its base icosahedron. The 600-cell has a dihedral angle of 𝜋/3 + arccos(−1/4) ≈ 164.4775°.[20]

An entire 600-cell can be assembled from 24 such icosahedral pyramids (bonded face-to-face at 8 of the 20 faces of the icosahedron, colored yellow in the illustration), plus 24 clusters of 5 tetrahedral cells (four cells face-bonded around one) which fill the voids remaining between the icosahedra. Six clusters of 5 cells surround each icosahedron, and six icosahedra surround each cluster of 5 cells. Five tetrahedral cells surround each icosahedron edge: two from the icosahedral pyramid, and three from a cluster of 5 cells (one of which is the central tetrahedron of the five). Each icosahedron is face-bonded to each adjacent cluster of 5 cells by two blue faces that share an edge (which is also one of the six edges of the central tetrahedron of the five).

The apexes of the 24 icosahedral pyramids are the vertices of a 24-cell inscribed in the 600-cell. The other 96 vertices (the vertices of the icosahedra) are the vertices of an inscribed snub 24-cell, which has exactly the same structure of icosahedra and tetrahedra described here, except that the icosahedra are not 4-pyramids filled by tetrahedral cells; they are only "flat" 3-dimensional icosahedral cells.

The partitioning of the 600-cell into clusters of 20 cells and clusters of 5 cells is artificial, since all the cells are the same. One can begin by picking out an icosahedral pyramid cluster centered at any arbitrarily chosen vertex. Thus there are 120 overlapping icosahedra in the 600-cell.

Coloring the icosahedra with 8 yellow and 12 blue faces can be done in 5 distinct ways.[lower-alpha 23] Thus each icosahedral pyramid's apex vertex is a vertex of 5 distinct 24-cells, and the 120 vertices comprise 25 (not 5) 24-cells.[lower-alpha 19]

The icosahedra are face-bonded into geodesic "straight lines" by their opposite faces, bent in the fourth dimension into a ring of 6 icosahedral pyramids. Their apexes are the vertices of a great circle hexagon. This hexagonal geodesic traverses a ring of 12 tetrahedral cells, alternately bonded face-to-face and vertex-to-vertex. The long diameter of each face-bonded pair of tetrahedra (each triangular bipyramid) is a hexagon edge (a 24-cell edge).

The tetrahedral cells are face-bonded into helices, bent in the fourth dimension into rings of 30 tetrahedral cells.[lower-alpha 24] Their edges form geodesic "straight lines" of 10 edges: great circle decagons. Each tetrahedron, having six edges, participates in six different decagons.

There is another useful way to partition the 600-cell surface, into 24 clusters of 25 tetrahedral cells, which reveals more structure[21] and a direct construction of the 600-cell from its predecessor the 24-cell.

Begin with any one of the clusters of 5 cells (above), and consider its central cell to be the center object of a new larger cluster of tetrahedral cells. The central cell is the first section of the 600-cell beginning with a cell. By surrounding it with more tetrahedral cells, we can reach the deeper sections beginning with a cell.

First, note that a cluster of 5 cells consists of 4 overlapping pairs of face-bonded tetrahedra (triangular dipyramids) whose long diameter is a 24-cell edge (a hexagon edge) of length √1. Six more triangular dipyramids fit into the concavities on the surface of the cluster of 5,[lower-alpha 25] so the exterior chords connecting its 4 apical vertices are also 24-cell edges of length √1. They form a tetrahedron of edge length √1, which is the second section of the 600-cell beginning with a cell.[lower-alpha 26] There are 600 of these √1 tetrahedral sections in the 600-cell.[lower-alpha 27]

With the six triangular dipyamids fit into the concavities, there are 12 new cells and 6 new vertices in addition to the 5 cells and 8 vertices of the original cluster. The 6 new vertices form the third section of the 600-cell beginning with a cell, an octahedron of edge length √1, obviously the cell of a 24-cell. As partially filled so far (by 17 tetrahedral cells), this √1 octahedron has concave faces into which a short triangular pyramid fits; it has the same volume as a regular tetrahedral cell but an irregular tetrahedral shape.[lower-alpha 28] Each octahedral cell consists of 1 + 4 + 12 + 8 = 25 tetrahedral cells: 17 regular tetrahedral cells plus 8 volumetrically equivalent tetrahedral cells each consisting of 6 one-sixth fragments from 6 different regular tetrahedral cells that each span three adjacent octahedral cells.

Thus the unit-radius 600-cell is constructed directly from its predecessor,[lower-alpha 21] the unit-radius 24-cell, by placing on each of its octahedral facets a truncated[lower-alpha 29] irregular octahedral pyramid of 14 vertices[lower-alpha 30] constructed (in the above manner) from 25 regular tetrahedral cells of edge length 1/φ ≈ 0.618.

The 600-cell is generated by rotations of the 24-cell in increments of 36° = 𝜋/5 (the arc of one 600-cell edge length).

There are 25 inscribed 24-cells in the 600-cell. Therefore there are also 25 inscribed snub 24-cells, 75 inscribed tesseracts and 75 inscribed 16-cells.[lower-alpha 19]

The 8-vertex 16-cell has 4 long diameters inclined at 90° = 𝜋/2 to each other, often taken as the 4 orthogonal axes of the coordinate system.

The 24-vertex 24-cell has 12 long diameters inclined at 60° = 𝜋/3 to each other: 3 disjoint sets of 4 orthogonal axes, each set comprising the diameters of one of 3 inscribed 16-cells, isoclinically rotated by 𝜋/3 with respect to each other.

The 120-vertex 600-cell has 60 long diameters: not just 5 disjoint sets of 12 diameters, each comprising one of 5 inscribed 24-cells (as we might suspect by analogy), but 25 distinct but overlapping sets of 12 diameters, each comprising one of 25 inscribed 24-cells. There are 5 disjoint 24-cells in the 600-cell, but not just 5: there are 10 different ways to partition the 600-cell into 5 disjoint 24-cells.[lower-alpha 16]

The 24-cells are rotated with respect to each other in increments of 𝜋/5. The rotational distance between inscribed 24-cells is always a double rotation of between 0 and 4 increments of 𝜋/5 in one invariant plane, combined with 0 to 4 increments of 𝜋/5 in the orthogonal invariant plane, where the invariant planes are any two orthogonal central decagons. The product of these two 5-click simple rotations produces 25 distinct ways we can pick the 24 vertices of a 24-cell out of the 120 vertices of a 600-cell. Any five 24-cells which can be reached by either 5-click simple rotation by itself have disjoint vertices.

We can give the 25 24-cells physical addresses of the form (i, j) corresponding to their inclination from an origin 24-cell,[lower-alpha 31] where i and j are integers between 0 and 4 corresponding to multiples of 𝜋/5 in the two orthogonal planes.[lower-alpha 32] The 25 overlapping 24-cells are thus arranged logically by address (not physically) in a 5 x 5 array.[lower-alpha 33] The five 24-cells in each row of this array (any five 24-cells with the same i) are disjoint: they have disjoint sets of vertices that together account for all 120 vertices of the 600-cell. The five 24-cells in each column of the array (any five with the same j) are similarly disjoint. No other set of five 24-cells is disjoint; these are the only ten ways to partition the 25 24-cells into five disjoint 24-cells.

The 600-cell can be constructed radially from 720 golden triangles of edge lengths √0.𝚫 √1 √1 which meet at the center of the 4-polytope, each contributing two √1 radii and a √0.𝚫 edge.[lower-alpha 11] They form 1200 triangular pyramids with their apexes at the center: irregular tetrahedra with equilateral √0.𝚫 bases (the faces of the 600-cell). These form 600 tetrahedral pyramids with their apexes at the center: irregular 5-cells with regular √0.𝚫 tetrahedron bases (the cells of the 600-cell).

This configuration matrix[23] represents the 600-cell. The rows and columns correspond to vertices, edges, faces, and cells. The diagonal numbers say how many of each element occur in the whole 600-cell. The non-diagonal numbers say how many of the column's element occur in or at the row's element.

${\displaystyle {\begin{bmatrix}{\begin{matrix}120&12&30&20\\2&720&5&5\\3&3&1200&2\\4&6&4&600\end{matrix}}\end{bmatrix}}}$

Here is the configuration expanded with k-face elements and k-figures. The diagonal element counts are the ratio of the full Coxeter group order, 14400, divided by the order of the subgroup with mirror removal.

H4		k-face	fk	f0	f1	f2	f3	k-fig	Notes
H3		( )	f0	120	12	30	20	{3,5}	H4/H3 = 14400/120 = 120
A1H2		{ }	f1	2	720	5	5	{5}	H4/H2A1 = 14400/10/2 = 720
A2A1		{3}	f2	3	3	1200	2	{ }	H4/A2A1 = 14400/6/2 = 1200
A3		{3,3}	f3	4	6	4	600	( )	H4/A3 = 14400/24 = 600

The H3 decagonal projection shows the plane of the van Oss polygon.

Orthographic projections by Coxeter planes

H4	-	F4
[30]	[20]	[12]
H3	A2 / B3 / D4	A3 / B2
[10]	[6]	[4]

A three-dimensional model of the 600-cell, in the collection of the Institut Henri Poincaré, was photographed in 1934–1935 by Man Ray, and formed part of two of his later "Shakesperean Equation" paintings.[26]

Vertex-first projection
	This image shows a vertex-first perspective projection of the 600-cell into 3D. The 600-cell is scaled to a vertex-center radius of 1, and the 4D viewpoint is placed 5 units away. Then the following enhancements are applied: The 20 tetrahedra meeting at the vertex closest to the 4D viewpoint are rendered in solid color. Their icosahedral arrangement is clearly shown. The tetrahedra immediately adjoining these 20 cells are rendered in transparent yellow. The remaining cells are rendered in edge-outline. Cells facing away from the 4D viewpoint (those lying on the "far side" of the 600-cell) have been culled, to reduce visual clutter in the final image.
Cell-first projection.
	This image shows the 600-cell in cell-first perspective projection into 3D. Again, the 600-cell to a vertex-center radius of 1 and the 4D viewpoint is placed 5 units away. The following enhancements are then applied: The nearest cell to the 4d viewpoint is rendered in solid color, lying at the center of the projection image. The cells surrounding it (sharing at least 1 vertex) are rendered in transparent yellow. The remaining cells are rendered in edge-outline. Cells facing away from the 4D viewpoint have been culled for clarity. This particular viewpoint shows a nice outline of 5 tetrahedra sharing an edge, towards the front of the 3D image.
Simple Rotation
	A 3D projection of a 600-cell performing a simple rotation.
Concentric Hulls
	The 600-cell is projected to 3D using an orthonormal basis. The vertices are sorted and tallied by their 3D norm. Generating the increasingly transparent hull of each set of tallied norms shows pairs of: 1) points at the origin 2) icosahedrons 3) dodecahedrons 4) icosahedrons 5) and a single icosadodecahedron for a total of 120 vertices.

Frame synchronized animated comparison of the 600 cell using orthogonal isometric (left) and perspective (right) projections.

Stereographic projection (on 3-sphere)
	Cell-Centered. The 720 edges of the 600-cell can be seen here as 72 circles, each divided into 10 arc-edges at the intersections. Each vertex has 6 circles intersecting.