Spherical polyhedron

In mathematics, a spherical polyhedron or spherical tiling is a tiling of the sphere in which the surface is divided or partitioned by great arcs into bounded regions called spherical polygons. Much of the theory of symmetrical polyhedra is most conveniently derived in this way.

The most familiar spherical polyhedron is the soccer ball, thought of as a spherical truncated icosahedron.
This beach ball shows a hosohedron with six lune faces, if the white circles on the ends are removed.

The most familiar spherical polyhedron is the soccer ball (outside the United States, Canada, and Australia, a football), thought of as a spherical truncated icosahedron. The next most popular spherical polyhedron is the beach ball, thought of as a hosohedron.

Some "improper" polyhedra, such as the hosohedra and their duals the dihedra, exist as spherical polyhedra but have no flat-faced analogue. In the examples below, {2, 6} is a hosohedron and {6, 2} is the dual dihedron.

History

The first known man-made polyhedra are spherical polyhedra carved in stone. Many have been found in Scotland, and appear to date from the neolithic period (the New Stone Age).

During the 10th Century, the Islamic scholar Abū al-Wafā' Būzjānī (Abu'l Wafa) wrote the first serious study of spherical polyhedra.

Two hundred years ago, at the start of the 19th Century, Poinsot used spherical polyhedra to discover the four regular star polyhedra.

In the middle of the 20th Century, Coxeter used them to enumerate all but one of the uniform polyhedra, through the construction of kaleidoscopes (Wythoff construction).

Examples

All the regular, semiregular polyhedra and their duals can be projected onto the sphere as tilings. Given by their Schläfli symbol {p, q} or vertex figure a.b.c. ...:

Schläfli symbol {p,q} t{p,q} r{p,q} t{q,p} {q,p} rr{p,q} tr{p,q} sr{p,q}
Vertex figure pq q.2p.2p p.q.p.q p. 2q.2q qp q.4.p. 4 4.2q.2p 3.3.q.3.p
Tetrahedral
(3 3 2)

33

3.6.6

3.3.3.3

3.6.6

33

3.4.3.4

4.6.6

3.3.3.3.3

V3.6.6

V3.3.3.3

V3.6.6

V3.4.3.4

V4.6.6

V3.3.3.3.3
Octahedral
(4 3 2)

43

3.8.8

3.4.3.4

4.6.6

34

3.4.4.4

4.6.8

3.3.3.3.4

V3.8.8

V3.4.3.4

V4.6.6

V3.4.4.4

V4.6.8

V3.3.3.3.4
Icosahedral
(5 3 2)

53

3.10.10

3.5.3.5

5.6.6

35

3.4.5.4

4.6.10

3.3.3.3.5

V3.10.10

V3.5.3.5

V5.6.6

V3.4.5.4

V4.6.10

V3.3.3.3.5
Dihedral
example p=6
(2 2 6)

62

2.12.12

2.6.2.6

6.4.4

26

4.6.4

4.4.12

3.3.3.6
A tiling of the sphere by triangles (this is an icosahedron with some of the triangles distorted).
Class 2 3 4 5 6 7 8 10
Prism
(2 2 p)
Bipyramid
(2 2 p)
Antiprism
Trapezohedron

Improper cases

Spherical tilings allow cases that polyhedra do not, namely the hosohedra, regular figures as {2,n}, and dihedra, regular figures as {n,2}.

Family of regular hosohedra
Image
Schläfli {2,1} {2,2} {2,3} {2,4} {2,5} {2,6} {2,7} {2,8}...
Coxeter
Faces and
edges
12345678
Vertices 2
Regular dihedra: (spherical tilings)
Image
Schläfli h{2,2}={1,2} {2,2} {3,2} {4,2} {5,2} {6,2}...
Coxeter
Faces 2 {1}2 {2}2 {3}2 {4}2 {5}2 {6}
Edges and
vertices
123456

Relation to tilings of the projective plane

Spherical polyhedra having at least one inversive symmetry are related to projective polyhedra[1] (tessellations of the real projective plane) – just as the sphere has a 2-to-1 covering map of the projective plane, projective polyhedra correspond under 2-fold cover to spherical polyhedra that are symmetric under reflection through the origin.

The best-known examples of projective polyhedra are the regular projective polyhedra, the quotients of the centrally symmetric Platonic solids, as well as two infinite classes of even dihedra and hosohedra:[2]

gollark: https://osmarks.tk/eternal-suffering
gollark: Theoretically I have an account I can't access until I'm 18 or something, but I have no idea how much is in there.
gollark: Yes, I am now richer than all you uncool people.
gollark: I have £1.90 in my bank account.
gollark: > I guess it's time to make a turret.It's been done.

See also

References

  1. McMullen, Peter; Schulte, Egon (2002). "6C. Projective Regular Polytopes". Abstract Regular Polytopes. Cambridge University Press. pp. 162–5. ISBN 0-521-81496-0.
  2. Coxeter, H.S.M. (1969). "§21.3 Regular maps'". Introduction to Geometry (2nd ed.). Wiley. pp. 386–8. ISBN 978-0-471-50458-0. MR 0123930.

Further reading

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