By combinatorial structure The five types of parallelohedron, and their most symmetric forms, are as follows. • A
parallelepiped is generated from three line segments that are not all parallel to a common plane. Its most symmetric form is the
cube, generated by three perpendicular unit-length line segments. The tiling of space by the cube is the
cubic honeycomb. • A
hexagonal prism is generated from four line segments, three of them parallel to a common plane and the fourth not. Its most symmetric form is the right prism over a regular hexagon. It tiles space to form the
hexagonal prismatic honeycomb. • The
rhombic dodecahedron is generated from four line segments, no two of which are parallel to a common plane. Its most symmetric form is generated by the four long diagonals of a cube. It tiles space to form the
rhombic dodecahedral honeycomb. The
Bilinski dodecahedron, another less-symmetric form of the rhombic dodecahedron, is notable for (like the symmetric rhombic dodecahedron) having all of its faces congruent; its faces are
golden rhombi. • The
elongated dodecahedron is generated from five line segments, with two triples of coplanar segments. • The
truncated octahedron is generated from six line segments with four triples of coplanar segments. It can be embedded in
four-dimensional space as the 4-
permutahedron, whose vertices are all permutations of the counting numbers (1,2,3,4). In three-dimensional space, its most symmetric form is generated from six line segments parallel to the face diagonals of a cube. The tiling of space generated by its translations has been called the
bitruncated cubic honeycomb.
By symmetries and Bravais lattices The lengths of the segments within each zone can be adjusted arbitrarily, independently of the other zones. Doing so extends or shrinks the corresponding edges of the parallelohedron, without changing its combinatorial type or its property of tiling space. As a limiting case, for a parallelohedron with more than three parallel classes of edges, the length of one of these classes can be adjusted to zero, producing a different parallelohedron of a simpler form, with one fewer zone. Beyond the central symmetry common to all zonohedra and all parallelohedra, additional symmetries are possible with an appropriate choice of the generating segments. When further subdivided according to their symmetry groups, there are 22 forms of the parallelohedra. For each form, the centers of its copies in its honeycomb form the points of one of the 14
Bravais lattices. Because there are fewer Bravais lattices than symmetric forms of parallelohedra, certain pairs of parallelohedra map to the same Bravais lattice. By placing one endpoint of each generating line segment of a parallelohedron at the origin of three-dimensional space, the generators may be represented as three-dimensional
vectors, the positions of their opposite endpoints. For this placement of the segments, one vertex of the parallelohedron will itself be at the origin, and the rest will be at positions given by sums of certain subsets of these vectors. A parallelohedron with g vectors can in this way be parameterized by 3g coordinates, three for each vector, but only some of these combinations are valid (because of the requirement that certain triples of segments lie in parallel planes, or equivalently that certain triples of vectors are coplanar) and different combinations may lead to parallelohedra that differ only by a rotation, scaling transformation, or more generally by an
affine transformation. When affine transformations are factored out, the number of free parameters that describe the shape of a parallelohedron is zero for a parallelepiped (all parallelepipeds are equivalent to each other under affine transformations), two for a hexagonal prism, three for a rhombic dodecahedron, four for an elongated dodecahedron, and five for a truncated octahedron. ==History==