The cube is the three-dimensional
hypercube, a family of
polytopes also including the two-dimensional square and four-dimensional
tesseract. A cube with
unit side length is the canonical unit of
volume in three-dimensional space, relative to which other solid objects are measured.
The cube can be represented in many ways, one of which is the graph known as the cubical graph. It can be constructed by using the
Cartesian product of graphs. The cube was discovered in antiquity. It was associated with the nature of
earth by
Plato, the founder of Platonic solid. It was used as the part of the
Solar System, proposed by
Johannes Kepler. It can be derived differently to create more polyhedrons, and it has applications to construct a new
polyhedron by attaching others.
Properties
A cube is a special case of
rectangular cuboid in which the edges are equal in length.[1] Like other cuboids, every face of a cube has four vertices, each of which connects with three congruent lines. These edges form square faces, making the
dihedral angle of a cube between every two adjacent squares being the
interior angle of a square, 90°. Hence, the cube has six faces, twelve edges, and eight vertices. [2] Because of such properties, it is categorized as one of the five
Platonic solids, a
polyhedron in which all the
regular polygons are
congruent and the same number of faces meet at each vertex.[3]
Measurement and other metric properties
A face diagonal in red and space diagonal in blue.
Given a cube with edge length . The
face diagonal of a cube is the
diagonal of a square , and the
space diagonal of a cube is a line connecting two vertices that is not in the same face, formulated as . Both formulas can be determined by using
Pythagorean theorem. The surface area of a cube is six times the area of a square:[4]
The volume of a cuboid is the product of its length, width, and height. Because all the edges of a cube are equal in length, it is:[4]
One special case is the
unit cube, so-named for measuring a single
unit of length along each edge. It follows that each face is a
unit square and that the entire figure has a volume of 1 cubic unit.[5][6]Prince Rupert's cube, named after
Prince Rupert of the Rhine, is the largest cube that can pass through a hole cut into the unit cube, despite having sides approximately 6% longer.[7] A polyhedron that can pass through a copy of itself of the same size or smaller is said to have the
Rupert property.[8]
A geometric problem of
doubling the cube—alternatively known as the Delian problem—requires the construction of a cube with a volume twice the original by using a
compass and straightedge solely. Ancient mathematicians could not solve this old problem until French mathematician
Pierre Wantzel in 1837 proved it was impossible.[9]
Relation to the spheres
With edge length , the
inscribed sphere of a cube is the sphere tangent to the faces of a cube at their centroids, with radius . The
midsphere of a cube is the sphere tangent to the edges of a cube, with radius . The
circumscribed sphere of a cube is the sphere tangent to the vertices of a cube, with radius .[10]
For a cube whose circumscribed sphere has radius , and for a given point in its three-dimensional space with distances from the cube's eight vertices, it is:[11]
Symmetry
The cube has
octahedral symmetry. It is composed of
reflection symmetry, a symmetry by cutting into two halves by a plane. There are nine reflection symmetries: the five are cut the cube from the midpoints of its edges, and the four are cut diagonally. It is also composed of
rotational symmetry, a symmetry by rotating it around the axis, from which the appearance is interchangeable. It has octahedral rotation symmetry : three axes pass through the cube's opposite faces centroid, six through the cube's opposite edges midpoints, and four through the cube's opposite vertices; each of these axes is respectively four-fold rotational symmetry (0°, 90°, 180°, and 270°), two-fold rotational symmetry (0° and 180°), and three-fold rotational symmetry (0°, 120°, and 240°).[12][13][14]
The
dual polyhedron can be obtained from each of the polyhedron's vertices tangent to a plane by the process known as
polar reciprocation.[15] One property of dual polyhedrons generally is that the polyhedron and its dual share their
three-dimensional symmetry point group. In this case, the dual polyhedron of a cube is the
regular octahedron, and both of these polyhedron has the same symmetry, the octahedral symmetry.[16]
The cube is
face-transitive, meaning its two squares are alike and can be mapped by rotation and reflection.[17] It is
vertex-transitive, meaning all of its vertices are equivalent and can be mapped
isometrically under its symmetry.[18] It is also
edge-transitive, meaning the same kind of faces surround each of its vertices in the same or reverse order, all two adjacent faces have the same
dihedral angle. Therefore, the cube is
regular polyhedron because it requires those properties.[19]
Classifications
The cube is a special case among every
cuboids. As mentioned above, the cube can be represented as the
rectangular cuboid with edges equal in length and all of its faces are all squares.[1] The cube may be considered as the
parallelepiped in which all of its edges are equal edges.[20]
The cube is a
plesiohedron, a special kind of space-filling polyhedron that can be defined as the
Voronoi cell of a symmetric
Delone set.[21] The plesiohedra include the
parallelohedrons, which can be
translated without rotating to fill a space—called
honeycomb—in which each face of any of its copies is attached to a like face of another copy. There are five kinds of parallelohedra, one of which is the cuboid.[22] Every three-dimensional parallelohedron is
zonohedron, a
centrally symmetric polyhedron whose faces are
centrally symmetric polygons,[23]
Construction
An elementary way to construct a cube is using its
net, an arrangement of edge-joining polygons constructing a polyhedron by connecting along the edges of those polygons. Eleven nets for the cube are shown here.[24]
In
analytic geometry, a cube may be constructed using the
Cartesian coordinate systems. For a cube centered at the origin, with edges parallel to the axes and with an edge length of 2, the
Cartesian coordinates of the vertices are .[25] Its interior consists of all points with for all . A cube's surface with center and edge length of is the
locus of all points such that
The cube is
Hanner polytope, because it can be constructed by using
Cartesian product of three line segments. Its dual polyhedron, the regular octahedron, is constructed by
direct sum of three line segments.[26]
According to
Steinitz's theorem, the
graph can be represented as the
skeleton of a polyhedron; roughly speaking, a framework of a polyhedron. Such a graph has two properties. It is
planar, meaning the edges of a graph are connected to every vertex without crossing other edges. It is also a
3-connected graph, meaning that, whenever a graph with more than three vertices, and two of the vertices are removed, the edges remain connected.[27][28] The skeleton of a cube can be represented as the graph, and it is called the cubical graph, a
Platonic graph. It has the same number of vertices and edges as the cube, twelve vertices and eight edges.[29]
The cubical graph is a special case of
hypercube graph or -cube—denoted as —because it can be constructed by using the operation known as the
Cartesian product of graphs. To put it in a plain, its construction involves two graphs connecting the pair of vertices with an edge to form a new graph.[30] In the case of the cubical graph, it is the product of two ; roughly speaking, it is a graph resembling a square. In other words, the cubical graph is constructed by connecting each vertex of two squares with an edge. Notationally, the cubical graph can be denoted as .[31] As a part of the hypercube graph, it is also an example of a
unit distance graph.[32]
Like other graphs of cuboids, the cubical graph is also classified as a
prism graph.[33]
In orthogonal projection
An object illuminated by parallel rays of light casts a shadow on a plane perpendicular to those rays, called an
orthogonal projection. A polyhedron is considered equiprojective if, for some position of the light, its orthogonal projection is a regular polygon. The cube is equiprojective because, if the light is parallel to one of the four lines joining a vertex to the opposite vertex, its projection is a
regular hexagon. Conventionally, the cube is 6-equiprojective.[34]
As a configuration matrix
The cube can be represented as
configuration matrix. A configuration matrix is a
matrix in which the rows and columns correspond to the elements of a polyhedron as in the vertices, edges, and faces. The
diagonal of a matrix denotes the number of each element that appears in a polyhedron, whereas the non-diagonal of a matrix denotes the number of the column's elements that occur in or at the row's element. As mentioned above, the cube has eight vertices, twelve edges, and six faces; each element in a matrix's diagonal is denoted as 8, 12, and 6. The first column of the middle row indicates that there are two vertices in (i.e., at the extremes of) each edge, denoted as 2; the middle column of the first row indicates that three edges meet at each vertex, denoted as 3. The following matrix is:[35]
The
Platonic solid is a set of polyhedrons known since antiquity. It was named after
Plato in his
Timaeus dialogue, who attributed these solids with nature. One of them, the cube, represented the
classical element of
earth because of its stability.[36]Euclid's
Elements defined the Platonic solids, including the cube, and using these solids with the problem involving to find the ratio of the circumscribed sphere's diameter to the edge length.[37]
The cube can appear in the construction of a polyhedron, and some of its types can be derived differently in the following:
When
faceting a cube, meaning removing part of the polygonal faces without creating new vertices of a cube, the resulting polyhedron is the
stellated octahedron.[39]
The cube is
non-composite polyhedron, meaning it is a convex polyhedron that cannot be separated into two or more regular polyhedrons. The cube can be applied to construct a new convex polyhedron by attaching another.[40] Attaching a
square pyramid to each square face of a cube produces its
Kleetope, a polyhedron known as the
tetrakis hexahedron.[41] Suppose one and two equilateral square pyramids are attached to their square faces. In that case, they are the construction of an
elongated square pyramid and
elongated square bipyramid respectively, the
Johnson solid's examples.[42]
Each of the cube's vertices can be
truncated, and the resulting polyhedron is the
Archimedean solid, the
truncated cube.[43] When its edges are truncated, it is a
rhombicuboctahedron.[44] Relatedly, the rhombicuboctahedron can also be constructed by separating the cube's faces and then spreading away, after which adding other triangular and square faces between them; this is known as the "expanded cube". It also can be constructed similarly by the cube's dual, the regular octahedron.[45]
The corner region of a cube can also be truncated by a plane (e.g., spanned by the three neighboring vertices), resulting in a
trirectangular tetrahedron.
The
snub cube is an Archimedean solid that can be constructed by separating away the cube square's face, and filling their gaps with twisted angle equilateral triangles;a process known as
snub.[46]
Polycube is a polyhedron in which the faces of many cubes are attached. Analogously, it can be interpreted as the
polyominoes in three-dimensional space.[49] When four cubes are stacked vertically, and the other four are attached to the second-from-top cube of the stack, the resulting polycube is
Dali cross, after
Salvador Dali. The Dali cross is a tile space polyhedron,[50][51] which can be represented as the net of a
tesseract. A tesseract is a cube analogous'
four-dimensional space bounded by twenty-four squares, and it is bounded by the eight cubes known as its
cells.[52]
^Sriraman, Bharath (2009). "Mathematics and literature (the sequel): imagination as a pathway to advanced mathematical ideas and philosophy". In Sriraman, Bharath; Freiman, Viktor; Lirette-Pitre, Nicole (eds.). Interdisciplinarity, Creativity, and Learning: Mathematics With Literature, Paradoxes, History, Technology, and Modeling. The Montana Mathematics Enthusiast: Monograph Series in Mathematics Education. Vol. 7. Information Age Publishing, Inc. pp. 41–54.
ISBN9781607521013.
^Coxeter (1973) Table I(i), pp. 292–293. See the columns labeled , , and , Coxeter's notation for the circumradius, midradius, and inradius, respectively, also noting that Coxeter uses as the edge length (see p. 2).
^In higher dimensions, however, there exist parallelopes that are not zonotopes. See e.g. Shephard, G. C. (1974). "Space-filling zonotopes". Mathematika. 21 (2): 261–269.
doi:
10.1112/S0025579300008652.
MR0365332.
^Jeon, Kyungsoon (2009). "Mathematics Hiding in the Nets for a CUBE". Teaching Children Mathematics. 15 (7): 394–399.
doi:
10.5951/TCM.15.7.0394.
JSTOR41199313.
^Viana, Vera; Xavier, João Pedro; Aires, Ana Paula; Campos, Helena (2019). "Interactive Expansion of Achiral Polyhedra". In Cocchiarella, Luigi (ed.). ICGG 2018 - Proceedings of the 18th International Conference on Geometry and Graphics 40th Anniversary - Milan, Italy, August 3-7, 2018. Advances in Intelligent Systems and Computing. Vol. 809. Springer. p. 1123.
doi:
10.1007/978-3-319-95588-9.
ISBN978-3-319-95587-2. See Fig. 6.