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Platonic Solid

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The Platonic solids, also called the regular solids or regular polyhedra, are convex polyhedra with equivalent faces composed of congruent convex regular polygons. There are exactly five such solids (Steinhaus 1999, pp. 252-256): the cube, dodecahedron, icosahedron, octahedron, and tetrahedron, as was proved by Euclid in the last proposition of the Elements. The Platonic solids are sometimes also called "cosmic figures" (Cromwell 1997), although this term is sometimes used to refer collectively to both the Platonic solids and Kepler-Poinsot polyhedra (Coxeter 1973).

The Platonic solids were known to the ancient Greeks, and were described by Plato in his Timaeus ca. 350 BC. In this work, Plato equated the tetrahedron with the "element" fire, the cube with earth, the icosahedron with water, the octahedron with air, and the dodecahedron with the stuff of which the constellations and heavens were made (Cromwell 1997). Predating Plato, the neolithic people of Scotland developed the five solids a thousand years earlier. The stone models are kept in the Ashmolean Museum in Oxford (Atiyah and Sutcliffe 2003).

Schläfli (1852) proved that there are exactly six regular bodies with Platonic properties (i.e., regular polytopes) in four dimensions, three in five dimensions, and three in all higher dimensions. However, his work (which contained no illustrations) remained practically unknown until it was partially published in English by Cayley (Schläfli 1858, 1860). Other mathematicians such as Stringham subsequently discovered similar results independently in 1880 and Schläfli's work was published posthumously in its entirety in 1901.

If P is a polyhedron with congruent (convex) regular polygonal faces, then Cromwell (1997, pp. 77-78) shows that the following statements are equivalent.

1. The vertices of P all lie on a sphere.

2. All the dihedral angles are equal.

3. All the vertex figures are regular polygons.

4. All the solid angles are equivalent.

5. All the vertices are surrounded by the same number of faces.

Let v (sometimes denoted N_0) be the number of polyhedron vertices, e (or N_1) the number of graph edges, and f (or N_2) the number of faces. The following table gives the Schläfli symbol, Wythoff symbol, and C&R symbol, the number of vertices v, edges e, and faces f, and the point groups for the Platonic solids (Wenninger 1989). The ordered number of faces for the Platonic solids are 4, 6, 8, 12, 20 (OEIS A053016; in the order tetrahedron, cube, octahedron, dodecahedron, icosahedron), which is also the ordered number of vertices (in the order tetrahedron, octahedron, cube, icosahedron, dodecahedron). The ordered number of edges are 6, 12, 12, 30, 30 (OEIS A063722; in the order tetrahedron, octahedron = cube, dodecahedron = icosahedron).

solidSchläfli symbolWythoff symbolC&R symbolvefgroup
cube{4,3}3 | 2 44^38126O_h
dodecahedron{5,3}3 | 2 55^3203012I_h
icosahedron{3,5}5 | 2 33^5123020I_h
octahedron{3,4}4 | 2 33^46128O_h
tetrahedron{3,3}3 | 2 33^3464T_d

The duals of Platonic solids are other Platonic solids and, in fact, the dual of the tetrahedron is another tetrahedron. Let r_d be the inradius of the dual polyhedron (corresponding to the insphere, which touches the faces of the dual solid), rho be the midradius of both the polyhedron and its dual (corresponding to the midsphere, which touches the edges of both the polyhedron and its duals), R the circumradius (corresponding to the circumsphere of the solid which touches the vertices of the solid) of the Platonic solid, and a the edge length of the solid. Since the circumsphere and insphere are dual to each other, they obey the relationship

Rr_d=rho^2
(1)

(Cundy and Rollett 1989, Table II following p. 144). In addition,

R=1/2(r_d+sqrt(r_d^2+a^2))
(2)
=sqrt(rho^2+1/4a^2)
(3)
r_d=(rho^2)/(sqrt(rho^2+1/4a^2))
(4)
=(R^2-1/4a^2)/R
(5)
rho=1/2sqrt(2)sqrt(r_d^2+r_dsqrt(r_d^2+a^2))
(6)
=sqrt(R^2-1/4a^2).
(7)

The following two tables give the analytic and numerical values of these distances for Platonic solids with unit side length.

solidrrhoR
cube1/21/2sqrt(2)1/2sqrt(3)
dodecahedron1/(20)sqrt(250+110sqrt(5))1/4(3+sqrt(5))1/4(sqrt(15)+sqrt(3))
icosahedron1/(12)(3sqrt(3)+sqrt(15))1/4(1+sqrt(5))1/4sqrt(10+2sqrt(5))
octahedron1/6sqrt(6)1/21/2sqrt(2)
tetrahedron1/(12)sqrt(6)1/4sqrt(2)1/4sqrt(6)
solidrrhoR
cube0.50.707110.86603
dodecahedron1.113521.309021.40126
icosahedron0.755760.809020.95106
octahedron0.408250.50.70711
tetrahedron0.204120.353550.61237

Finally, let A be the area of a single face, V be the volume of the solid, and the polyhedron edges be of unit length on a side. The following table summarizes these quantities for the Platonic solids.

solidAV
cube11
dodecahedron1/4sqrt(25+10sqrt(5))1/4(15+7sqrt(5))
icosahedron1/4sqrt(3)5/(12)(3+sqrt(5))
octahedron1/4sqrt(3)1/3sqrt(2)
tetrahedron1/4sqrt(3)1/(12)sqrt(2)

The following table gives the dihedral angles alpha and angles beta subtended by an edge from the center for the Platonic solids (Cundy and Rollett 1989, Table II following p. 144).

solidalpha (rad)alpha ( degrees)betabeta ( degrees)
cube1/2pi90.000cos^(-1)(1/3)70.529
dodecahedroncos^(-1)(-1/5sqrt(5))116.565cos^(-1)(1/3sqrt(5))41.810
icosahedroncos^(-1)(-1/3sqrt(5))138.190cos^(-1)(1/5sqrt(5))63.435
octahedroncos^(-1)(-1/3)109.4711/2pi90.000
tetrahedroncos^(-1)(1/3)70.529cos^(-1)(-1/3)109.471

The number of polyhedron edges meeting at a polyhedron vertex is 2e/v. The Schläfli symbol can be used to specify a Platonic solid. For the solid whose faces are p-gons (denoted {p}), with q touching at each polyhedron vertex, the symbol is {p,q}. Given p and q, the number of polyhedron vertices, polyhedron edges, and faces are given by

N_0=(4p)/(4-(p-2)(q-2))
(8)
N_1=(2pq)/(4-(p-2)(q-2))
(9)
N_2=(4q)/(4-(p-2)(q-2)).
(10)
PlatonicDualsWenninger

The plots above show scaled duals of the Platonic solid embedded in an augmented form of the original solid, where the scaling is chosen so that the dual vertices lie at the incenters of the original faces (Wenninger 1983, pp. 8-9).

Since the Platonic solids are convex, the convex hull of each Platonic solid is the solid itself. Minimal surfaces for Platonic solid frames are illustrated in Isenberg (1992, pp. 82-83).

See also

Archimedean Solid, Catalan Solid, Johnson Solid, Kepler-Poinsot Polyhedron, Quasiregular Polyhedron, Uniform Polyhedron Explore this topic in the MathWorld classroom

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References

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Platonic Solid

Cite this as:

Weisstein, Eric W. "Platonic Solid." From MathWorld--A Wolfram Web Resource. https://mathworld.wolfram.com/PlatonicSolid.html

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