Hypercube

A diagram showing how to create a tesseract from a point.

An animation showing how to create a tesseract from a point.

A hypercube can be defined by increasing the numbers of dimensions of a shape:

0 – A point is a hypercube of dimension zero.

1 – If one moves this point one unit length, it will sweep out a line segment, which is a unit hypercube of dimension one.

2 – If one moves this line segment its length in a perpendicular direction from itself; it sweeps out a 2-dimensional square.

3 – If one moves the square one unit length in the direction perpendicular to the plane it lies on, it will generate a 3-dimensional cube.

4 – If one moves the cube one unit length into the fourth dimension, it generates a 4-dimensional unit hypercube (a unit tesseract).

This can be generalized to any number of dimensions. This process of sweeping out volumes can be formalized mathematically as a Minkowski sum: the d-dimensional hypercube is the Minkowski sum of d mutually perpendicular unit-length line segments, and is therefore an example of a zonotope.

The 1-skeleton of a hypercube is a hypercube graph.

A unit hypercube of n dimensions is the convex hull of the points given by all sign permutations of the Cartesian coordinates ${\displaystyle \left(\pm {\frac {1}{2}},\pm {\frac {1}{2}},\cdots ,\pm {\frac {1}{2}}\right)}$. It has an edge length of 1 and an n-dimensional volume of 1.

An n-dimensional hypercube is also often regarded as the convex hull of all sign permutations of the coordinates ${\displaystyle (\pm 1,\pm 1,\cdots ,\pm 1)}$. This form is often chosen due to ease of writing out the coordinates. Its edge length is 2, and its n-dimensional volume is 2ⁿ.

Every n-cube of n > 0 is composed of elements, or n-cubes of a lower dimension, on the (n−1)-dimensional surface on the parent hypercube. A side is any element of (n−1)-dimension of the parent hypercube. A hypercube of dimension n has 2n sides (a 1-dimensional line has 2 endpoints; a 2-dimensional square has 4 sides or edges; a 3-dimensional cube has 6 2-dimensional faces; a 4-dimensional tesseract has 8 cells). The number of vertices (points) of a hypercube is ${\displaystyle 2^{n}}$ (a cube has ${\displaystyle 2^{3}}$ vertices, for instance).

The number of m-dimensional hypercubes (just referred to as m-cube from here on) on the boundary of an n-cube is

${\displaystyle E_{m,n}=2^{n-m}{n \choose m}}$,[3]     where ${\displaystyle {n \choose m}={\frac {n!}{m!\,(n-m)!}}}$ and n! denotes the factorial of n.

For example, the boundary of a 4-cube (n=4) contains 8 cubes (3-cubes), 24 squares (2-cubes), 32 lines (1-cubes) and 16 vertices (0-cubes).

This identity can be proved by combinatorial arguments; each of the ${\displaystyle 2^{n}}$ vertices defines a vertex in a m-dimensional boundary. There are ${\displaystyle {n \choose m}}$ ways of choosing which lines ("sides") that defines the subspace that the boundary is in. But, each side is counted ${\displaystyle 2^{m}}$ times since it has that many vertices, we need to divide by this number.

This identity can also be used to generate the formula for the n-dimensional cube surface area. The surface area of a hypercube is: ${\displaystyle 2ns^{n-1}}$.

These numbers can also be generated by the linear recurrence relation

${\displaystyle E_{m,n}=2E_{m,n-1}+E_{m-1,n-1}\!}$,     with ${\displaystyle E_{0,0}=1\!}$,  and undefined elements (where ${\displaystyle n<m}$, ${\displaystyle n<0}$, or ${\displaystyle m<0}$ ) ${\displaystyle =0}$.

For example, extending a square via its 4 vertices adds one extra line (edge) per vertex, and also adds the final second square, to form a cube, giving ${\displaystyle E_{1,3}\!}$ = 12 lines in total.

Hypercube elements ${\displaystyle E_{m,n}\!}$ (sequence A038207 in the OEIS)

			m	0	1	2	3	4	5	6	7	8	9	10
n	n-cube	Names	Schläfli Coxeter	Vertex 0-face	Edge 1-face	Face 2-face	Cell 3-face	4-face	5-face	6-face	7-face	8-face	9-face	10-face
0	0-cube	Point Monon	( )	1
1	1-cube	Line segment Dion[4]	{}	2	1
2	2-cube	Square Tetragon	{4}	4	4	1
3	3-cube	Cube Hexahedron	{4,3}	8	12	6	1
4	4-cube	Tesseract Octachoron	{4,3,3}	16	32	24	8	1
5	5-cube	Penteract Deca-5-tope	{4,3,3,3}	32	80	80	40	10	1
6	6-cube	Hexeract Dodeca-6-tope	{4,3,3,3,3}	64	192	240	160	60	12	1
7	7-cube	Hepteract Tetradeca-7-tope	{4,3,3,3,3,3}	128	448	672	560	280	84	14	1
8	8-cube	Octeract Hexadeca-8-tope	{4,3,3,3,3,3,3}	256	1024	1792	1792	1120	448	112	16	1
9	9-cube	Enneract Octadeca-9-tope	{4,3,3,3,3,3,3,3}	512	2304	4608	5376	4032	2016	672	144	18	1
10	10-cube	Dekeract Icosa-10-tope	{4,3,3,3,3,3,3,3,3}	1024	5120	11520	15360	13440	8064	3360	960	180	20	1

Graphs

An n-cube can be projected inside a regular 2n-gonal polygon by a skew orthogonal projection, shown here from the line segment to the 15-cube.

Petrie polygon Orthographic projections

Line segment	Square	Cube	Tesseract	5-cube
6-cube	7-cube	8-cube	9-cube	10-cube
11-cube	12-cube	13-cube	14-cube	15-cube

Projection of a rotating tesseract.

The hypercubes are one of the few families of regular polytopes that are represented in any number of dimensions.

The hypercube (offset) family is one of three regular polytope families, labeled by Coxeter as γ_n. The other two are the hypercube dual family, the cross-polytopes, labeled as β_n, and the simplices, labeled as α_n. A fourth family, the infinite tessellations of hypercubes, he labeled as δ_n.

Another related family of semiregular and uniform polytopes is the demihypercubes, which are constructed from hypercubes with alternate vertices deleted and simplex facets added in the gaps, labeled as hγ_n.

n-cubes can be combined with their duals (the cross-polytopes) to form compound polytopes:

• In two dimensions, we obtain the octagrammic star figure {8/2},
• In three dimensions we obtain the compound of cube and octahedron,
• In four dimensions we obtain the compound of tesseract and 16-cell.

The graph of the n-hypercube's edges is isomorphic to the Hasse diagram of the (n−1)-simplex's face lattice. This can be seen by orienting the n-hypercube so that two opposite vertices lie vertically, corresponding to the (n-1)-simplex itself and the null polytope, respectively. Each vertex connected to the top vertex then uniquely maps to one of the (n-1)-simplex's facets (n-2 faces), and each vertex connected to those vertices maps to one of the simplex's n-3 faces, and so forth, and the vertices connected to the bottom vertex map to the simplex's vertices.

This relation may be used to generate the face lattice of an (n-1)-simplex efficiently, since face lattice enumeration algorithms applicable to general polytopes are more computationally expensive.

Regular complex polytopes can be defined in complex Hilbert space called generalized hypercubes, γ^p
_n = _p{4}₂{3}...₂{3}₂, or ... Real solutions exist with p=2, i.e. γ²
_n = γ_n = ₂{4}₂{3}...₂{3}₂ = {4,3,..,3}. For p>2, they exist in ${\displaystyle \mathbb {C} ^{n}}$ . The facets are generalized (n-1)-cube and the vertex figure are regular simplexes.

The regular polygon perimeter seen in these orthogonal projections is called a petrie polygon. The generalized squares (n=2) are shown with edges outlined as red and blue alternating color p-edges, while the higher n-cubes are drawn with black outlined p-edges.

The number of m-face elements in a p-generalized n-cube are: ${\displaystyle p^{n-m}{n \choose m}}$. This is pⁿ vertices and pn facets.[5]

Generalized hypercubes

	p=2		p=3	p=4	p=5	p=6	p=7	p=8
${\displaystyle \mathbb {R} ^{2}}$	γ2 2 = {4} = 4 vertices	${\displaystyle \mathbb {C} ^{2}}$	γ3 2 = 9 vertices	γ4 2 = 16 vertices	γ5 2 = 25 vertices	γ6 2 = 36 vertices	γ7 2 = 49 vertices	γ8 2 = 64 vertices
${\displaystyle \mathbb {R} ^{3}}$	γ2 3 = {4,3} = 8 vertices	${\displaystyle \mathbb {C} ^{3}}$	γ3 3 = 27 vertices	γ4 3 = 64 vertices	γ5 3 = 125 vertices	γ6 3 = 216 vertices	γ7 3 = 343 vertices	γ8 3 = 512 vertices
${\displaystyle \mathbb {R} ^{4}}$	γ2 4 = {4,3,3} = 16 vertices	${\displaystyle \mathbb {C} ^{4}}$	γ3 4 = 81 vertices	γ4 4 = 256 vertices	γ5 4 = 625 vertices	γ6 4 = 1296 vertices	γ7 4 = 2401 vertices	γ8 4 = 4096 vertices
${\displaystyle \mathbb {R} ^{5}}$	γ2 5 = {4,3,3,3} = 32 vertices	${\displaystyle \mathbb {C} ^{5}}$	γ3 5 = 243 vertices	γ4 5 = 1024 vertices	γ5 5 = 3125 vertices	γ6 5 = 7776 vertices	γ7 5 = 16,807 vertices	γ8 5 = 32,768 vertices
${\displaystyle \mathbb {R} ^{6}}$	γ2 6 = {4,3,3,3,3} = 64 vertices	${\displaystyle \mathbb {C} ^{6}}$	γ3 6 = 729 vertices	γ4 6 = 4096 vertices	γ5 6 = 15,625 vertices	γ6 6 = 46,656 vertices	γ7 6 = 117,649 vertices	γ8 6 = 262,144 vertices
${\displaystyle \mathbb {R} ^{7}}$	γ2 7 = {4,3,3,3,3,3} = 128 vertices	${\displaystyle \mathbb {C} ^{7}}$	γ3 7 = 2187 vertices	γ4 7 = 16,384 vertices	γ5 7 = 78,125 vertices	γ6 7 = 279,936 vertices	γ7 7 = 823,543 vertices	γ8 7 = 2,097,152 vertices
${\displaystyle \mathbb {R} ^{8}}$	γ2 8 = {4,3,3,3,3,3,3} = 256 vertices	${\displaystyle \mathbb {C} ^{8}}$	γ3 8 = 6561 vertices	γ4 8 = 65,536 vertices	γ5 8 = 390,625 vertices	γ6 8 = 1,679,616 vertices	γ7 8 = 5,764,801 vertices	γ8 8 = 16,777,216 vertices

• Hypercube interconnection network of computer architecture
• Hyperoctahedral group, the symmetry group of the hypercube
• Hypersphere
• Simplex
• Crucifixion (Corpus Hypercubus) (famous artwork)

• Bowen, J. P. (April 1982). "Hypercube". Practical Computing. 5 (4): 97–99. Archived from the original on 2008-06-30. Retrieved June 30, 2008.
• Coxeter, H. S. M. (1973). Regular Polytopes (3rd ed.). §7.2. see illustration Fig. 7-2C: Dover. pp. 122-123. ISBN 0-486-61480-8.CS1 maint: location (link) CS1 maint: ref=harv (link) p. 296, Table I (iii): Regular Polytopes, three regular polytopes in n dimensions (n ≥ 5)
• Hill, Frederick J.; Gerald R. Peterson (1974). Introduction to Switching Theory and Logical Design: Second Edition. New York: John Wiley & Sons. ISBN 0-471-39882-9. Cf Chapter 7.1 "Cubical Representation of Boolean Functions" wherein the notion of "hypercube" is introduced as a means of demonstrating a distance-1 code (Gray code) as the vertices of a hypercube, and then the hypercube with its vertices so labelled is squashed into two dimensions to form either a Veitch diagram or Karnaugh map.

Wikimedia Commons has media related to Hypercubes.

• Weisstein, Eric W. "Hypercube". MathWorld.
• Weisstein, Eric W. "Hypercube graphs". MathWorld.
• www.4d-screen.de (Rotation of 4D – 7D-Cube)
• Rotating a Hypercube by Enrique Zeleny, Wolfram Demonstrations Project.
• Stereoscopic Animated Hypercube
• Rudy Rucker and Farideh Dormishian's Hypercube Downloads