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Archimedean Solid


The 13 Archimedean solids are the convex polyhedra that have a similar arrangement of nonintersecting regular convex polygons of two or more different types arranged in the same way about each vertex with all sides the same length (Cromwell 1997, pp. 91-92).

The Archimedean solids are distinguished by having very high symmetry, thus excluding solids belonging to a dihedral group of symmetries (e.g., the two infinite families of regular prisms and antiprisms), as well as the elongated square gyrobicupola (because that surface's symmetry-breaking twist allows vertices "near the equator" and those "in the polar regions" to be distinguished; Cromwell 1997, p. 92). The Archimedean solids are sometimes also referred to as the semiregular polyhedra.

ArchimedeanSolids

The Archimedean solids are illustrated above.

ArchimedeanSolidNets

Nets of the Archimedean solids are illustrated above.

The following table lists the uniform, Schläfli, Wythoff, and Cundy and Rollett symbols for the Archimedean solids (Wenninger 1989, p. 9).

The following table gives the number of vertices v, edges e, and faces f, together with the number of n-gonal faces f_n for the Archimedean solids. The sorted numbers of edges are 18, 24, 36, 36, 48, 60, 60, 72, 90, 90, 120, 150, 180 (OEIS A092536), numbers of faces are 8, 14, 14, 14, 26, 26, 32, 32, 32, 38, 62, 62, 92 (OEIS A092537), and numbers of vertices are 12, 12, 24, 24, 24, 24, 30, 48, 60, 60, 60, 60, 120 (OEIS A092538).

TruncationCubeTruncationIcosahedronTruncationTetrahedron

Seven of the 13 Archimedean solids (the cuboctahedron, icosidodecahedron, truncated cube, truncated dodecahedron, truncated octahedron, truncated icosahedron, and truncated tetrahedron) can be obtained by truncation of a Platonic solid. The three truncation series producing these seven Archimedean solids are illustrated above.

Two additional solids (the small rhombicosidodecahedron and small rhombicuboctahedron) can be obtained by expansion of a Platonic solid, and two further solids (the great rhombicosidodecahedron and great rhombicuboctahedron) can be obtained by expansion of one of the previous 9 Archimedean solids (Stott 1910; Ball and Coxeter 1987, pp. 139-140). It is sometimes stated (e.g., Wells 1991, p. 8) that these four solids can be obtained by truncation of other solids. The confusion originated with Kepler himself, who used the terms "truncated icosidodecahedron" and "truncated cuboctahedron" for the great rhombicosidodecahedron and great rhombicuboctahedron, respectively. However, truncation alone is not capable of producing these solids, but must be combined with distorting to turn the resulting rectangles into squares (Ball and Coxeter 1987, pp. 137-138; Cromwell 1997, p. 81).

The remaining two solids, the snub cube and snub dodecahedron, can be obtained by moving the faces of a cube and dodecahedron outward while giving each face a twist. The resulting spaces are then filled with ribbons of equilateral triangles (Wells 1991, p. 8).

Pugh (1976, p. 25) points out the Archimedean solids are all capable of being circumscribed by a regular tetrahedron so that four of their faces lie on the faces of that tetrahedron.

The Archimedean solids satisfy

 (2pi-sigma)V=4pi,
(1)

where sigma is the sum of face-angles at a vertex and V is the number of vertices (Steinitz and Rademacher 1934, Ball and Coxeter 1987).

Let the cyclic sequence S=(p_1,p_2,...,p_q) represent the degrees of the faces surrounding a vertex (i.e., S is a list of the number of sides of all polygons surrounding any vertex). Then the definition of an Archimedean solid requires that the sequence must be the same for each vertex to within rotation and reflection. Walsh (1972) demonstrates that S represents the degrees of the faces surrounding each vertex of a semiregular convex polyhedron or tessellation of the plane iff

1. q>=3 and every member of S is at least 3,

2. sum_(i=1)^(q)1/(p_i)>=1/2q-1, with equality in the case of a plane tessellation, and

3. for every odd number p in S, S contains a subsequence (b, p, b).

Condition (1) simply says that the figure consists of two or more polygons, each having at least three sides. Condition (2) requires that the sum of interior angles at a vertex must be equal to a full rotation for the figure to lie in the plane, and less than a full rotation for a solid figure to be convex.

The usual way of enumerating the semiregular polyhedra is to eliminate solutions of conditions (1) and (2) using several classes of arguments and then prove that the solutions left are, in fact, semiregular (Kepler 1864, pp. 116-126; Catalan 1865, pp. 25-32; Coxeter 1940, p. 394; Coxeter et al. 1954; Lines 1965, pp. 202-203; Walsh 1972). The following table gives all possible regular and semiregular polyhedra and tessellations. In the table, 'P' denotes Platonic solid, 'M' denotes a prism or antiprism, 'A' denotes an Archimedean solid, and 'T' a plane tessellation.

Sfg.solidSchläfli symbol
(3, 3, 3)Ptetrahedron{3,3}
(3, 4, 4)Mtriangular prismt{2,3}
(3, 6, 6)Atruncated tetrahedront{3,3}
(3, 8, 8)Atruncated cubet{4,3}
(3, 10, 10)Atruncated dodecahedront{5,3}
(3, 12, 12)Ttessellationt{6,3}
(4, 4, n)Mn-gonal prismt{2,n}
(4, 4, 4)Pcube{4,3}
(4, 6, 6)Atruncated octahedront{3,4}
(4, 6, 8)Agreat rhombicuboctahedront{3; 4}
(4, 6, 10)Agreat rhombicosidodecahedront{3; 5}
(4, 6, 12)Ttessellationt{3; 6}
(4, 8, 8)Ttessellationt{4,4}
(5, 5, 5)Pdodecahedron{5,3}
(5, 6, 6)Atruncated icosahedront{3,5}
(6, 6, 6)Ttessellation{6,3}
(3, 3, 3, n)Mn-gonal antiprisms{2; n}
(3, 3, 3, 3)Poctahedron{3,4}
(3, 4, 3, 4)Acuboctahedron{3; 4}
(3, 5, 3, 5)Aicosidodecahedron{3; 5}
(3, 6, 3, 6)Ttessellation{3; 6}
(3, 4, 4, 4)Asmall rhombicuboctahedronr{3; 4}
(3, 4, 5, 4)Asmall rhombicosidodecahedronr{3; 5}
(3, 4, 6, 4)Ttessellationr{3; 6}
(4, 4, 4, 4)Ttessellation{4,4}
(3, 3, 3, 3, 3)Picosahedron{3,5}
(3, 3, 3, 3, 4)Asnub cubes{3; 4}
(3, 3, 3, 3, 5)Asnub dodecahedrons{3; 5}
(3, 3, 3, 3, 6)Ttessellations{3; 6}
(3, 3, 3, 4, 4)Ttessellation--
(3, 3, 4, 3, 4)Ttessellations{4; 4}
(3, 3, 3, 3, 3, 3)Ttessellation{3,6}

As shown in the above table, there are exactly 13 Archimedean solids (Walsh 1972, Ball and Coxeter 1987). They are called the cuboctahedron, great rhombicosidodecahedron, great rhombicuboctahedron, icosidodecahedron, small rhombicosidodecahedron, small rhombicuboctahedron, snub cube, snub dodecahedron, truncated cube, truncated dodecahedron, truncated icosahedron (soccer ball), truncated octahedron, and truncated tetrahedron.

Let r_d be the inradius of the dual polyhedron (corresponding to the insphere, which touches the faces of the dual solid), rho=rho_d 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 Archimedean 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
(2)

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

R=1/2(r_d+sqrt(r_d^2+a^2))
(3)
=sqrt(rho^2+1/4a^2)
(4)
r_d=(rho^2)/(sqrt(rho^2+1/4a^2))
(5)
=(R^2-1/4a^2)/R
(6)
rho=1/2sqrt(2)sqrt(r_d^2+r_dsqrt(r_d^2+a^2))
(7)
=sqrt(R^2-1/4a^2).
(8)

The following tables give the analytic and numerical values of r, rho, and R for the Archimedean solids with polyhedron edges of unit length (Coxeter et al. 1954; Cundy and Rollett 1989, Table II following p. 144). Hume (1986) gives approximate expressions for the dihedral angles of the Archimedean solid (and exact expressions for their duals).

*The complicated analytic expressions for the circumradii of these solids are given in the entries for the snub cube and snub dodecahedron.

nsolidrrhoR
1cuboctahedron0.750.866031
2great rhombicosidodecahedron3.736653.769383.80239
3great rhombicuboctahedron2.209742.263032.31761
4icosidodecahedron1.463531.538841.61803
5small rhombicosidodecahedron2.120992.176252.23295
6small rhombicuboctahedron1.220261.306561.39897
7snub cube1.157631.247191.34371
8snub dodecahedron2.039692.096882.15583
9truncated cube1.638281.707111.77882
10truncated dodecahedron2.885262.927052.96945
11truncated icosahedron2.377132.427052.47802
12truncated octahedron1.423021.51.58114
13truncated tetrahedron0.959401.060661.17260

The Archimedean solids and their duals are all canonical polyhedra. Since the Archimedean solids are convex, the convex hull of each Archimedean solid is the solid itself.


See also

Archimedean Dual, Archimedean Solid Stellations, Catalan Solid, Deltahedron, Isohedron, Johnson Solid, Kepler-Poinsot Polyhedron, Platonic Solid, Quasiregular Polyhedron, Semiregular Polyhedron, Uniform Polyhedron, Uniform Tessellation

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References

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Archimedean Solid

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

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