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A dodecahedron
In mathematics, a polyhedron (from Greek πολυεδρον, from
poly-, stem of πολυς, "many," + -edron, form of εδρον,
"base", "seat", or "face") is a three-dimensional shape that is made up of a finite number of polygonal faces, which are
parts of planes, the faces meet in edges
which are straight-line segments, and the edges meet in points called
vertices. Cubes, prisms and pyramids are examples of polyhedra. The polyhedron surrounds a bounded volume in three-dimensional space;
sometimes this interior volume is considered to be part of the polyhedron. A polyhedron is a three-dimensional analog of a
polygon. The general term for polygons, polyhedra and even higher dimensional analogs
is polytope.
A polyhedron is
- convex if the line segment joining any two points of the
polyhedron is contained in the polyhedron's interior
- vertex-uniform if all vertices are the same, in the sense that for any two vertices there exists a symmetry of the polyhedron mapping the first onto the second
- edge-uniform if all edges are the same, in the sense that for any two edges there exists a symmetry of the
polyhedron mapping the first onto the second
- face-uniform if all faces are the same, in the sense that for any two faces there exists a symmetry of the
polyhedron mapping the first onto the second
- regular if it is vertex-uniform, edge-uniform and face-uniform
Euler's formula relates the number of edges E, vertices
V, and faces F of a simply connected polyhedron: F - E + V = 2.
There are only five regular convex polyhedra. These have been known since ancient times, and are called the Platonic solids (see pictures there):
Interestingly, there are also more convex figures made entirely out of equilateral triangles known as deltahedra. The
reason only three are mentioned above is that the number of faces that meet at each vertex varies.
The regular polyhedra come in natural pairs: the dodecahedron with the icosahedron, the cube with the octahedron, and the
tetrahedron with itself. These are called duals, and can be obtained by connecting the midpoints of each other's
faces, among other interesting things. There are also five regular polyhedral compounds.
If you allow the polyhedra to be non-convex, there are four more, called the Kepler-Poinsot solids.
Polyhedra which are vertex- and edge-uniform, but not necessarily face-uniform, are called quasi-regular and
include two more convex forms (the cuboctahedron and icosidodecahedron, as well as a few non-convex forms. The duals of these
are the edge- and face-uniform polyhedra: the rhombic
dodecahedron, rhombic triacontahedron, plus
whatever the non-convex ones are. No other convex edge-uniform polyhedra exist.
Any polyhedron which is vertex-uniform can be deformed slightly to form a vertex-uniform polyhedron with regular polygons as faces. These are called semi-regular
polyhedra. Convex forms include two infinite series, one of prisms and one of antiprisms, as well as the thirteen
Archimedean solids. The duals of these are of course the
face-uniform polyhedra, with the two infinite convex series becoming the bipyramids and trapezohedra. These don't have regular
faces, but do have regular vertices.
Another thing to consider is what kind of polyhedra, of any symmetry, can be made of regular polygons. There are an infinite
number of non-convex forms, but surprisingly only a finite number of convex shapes other than the prisms and antiprisms. These
include the Platonic solids, Archimedean solids, and 92 extra shapes called Johnson solids.
Given two polyhedra of equal volume, one may ask whether it is then always possible to cut the first into polyhedral pieces
which can be reassembled to yield the second polyhedron. This is a version of Hilbert's third problem; the answer is "no", as was shown by Dehn in 1900.
See also
External links
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