Platonic solid: Difference between revisions

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imported>Peter Schmitt
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* Dodecahedron: 12 regular pentagons, 20 corners in which 3 sides meet
* Dodecahedron: 12 regular pentagons, 20 corners in which 3 sides meet
* Icosahedron: 20 equilateral triangles, 12 corners in which 5 sides meet
* Icosahedron: 20 equilateral triangles, 12 corners in which 5 sides meet
== Enumeration ==
It is easy to see that there are at most five Platonic solids:
The corner of a convex polyhedron is formed by three or more sides,
and the sum of the angles cannot exceed 2π.
* Therefore there are only five possibilities: 3, 4, or 5 triangles (angle &pi;/3), 3 squares (angle &pi;/2), and 3 pentagons (angle 3&pi;/5), corresponding to tetrahedron, octahedron, icosahedron, cube, and dodecahedron, respectively. <br> Of these five possibilities three obviously give polyhedra with the desired properties. For the dodecahedron and the icosahedron, however, additional [[icosahedron|arguments]] are needed.
* 6 triangles, 4 squares, and 3 hexagons (angle 2&pi;/3) are special because in these three cases the sum of the angles is 2&pi;, and they give the regular [[tiling|tilings]] of the plane.
* For ''n''>6, the angle for the regular ''n''-gon is (''n''-2)&pi;/''n'', and the sum of three angles is (3-6/''n'')&pi;  and thus is always greater than 2&pi;. Therefore there are no corresponding solids.
* There are two polyhedra with equilateral triangles as sides, a 3-sided and a 5-sided double-pyramid. But they are not Platonic solids since there meet 4 triangles at the base corners, but 3, respectively 5, triangles at the tops of the pyramids.
== Duality ==
The midpoints of the sides of a Platonic sides
- the corners of the '''dual polyhedron''' -
is also a Platonic solid:
* The cube and the octahedron are dual to each other.
* The dodecahedron and the icosahedron are dual to each other.
* The tetrahedron is dual to itself.
== Table ==


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The dual of a polyhedron is the polyhedron formed by taking the center of each face as the vertex of the dual.  The regular tetrahedron is self-dual - connecting the center of each face results in a smaller tetrahedron.  The cube and regular octahedron are dual to each other, and the regular dodecahedron and icosahedron are dual to each other.


A sphere circumscribed about any of the Platonic solids will touch all the vertices, and a sphere inscribed within any will touch all the faces at the center of the face.
A sphere circumscribed about any of the Platonic solids will touch all the vertices, and a sphere inscribed within any will touch all the faces at the center of the face.
==Proof that there are only 5 Platonic solids==
Proving that there are at most 5 Platonic solids is rather easy:  From the definition, the faces must be regular polygons which can meet three or more at a point with some excess angle, to create a [[solid angle]].  Any regular polygon with 7 or more sides cannot meet three or more to a point without overlapping. The regular hexagon can meet three at a point, but with no excess, thus no solid angle is formed. That leaves the regular pentagon, the square, and the equilateral triangle as the only possible faces for a Platonic solid. The regular pentagon and the square can only meet three at a point and have any excess to allow forming a solid angle.  The Platonic solids thus formed are the dodecahedron and the cube.  The equilateral triangle can meet three, four, or five at a point and form a solid angle; the figures formed are the tetrahedron, octahedron, and icosahedron, respectively.

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The platonic solids (named after the Greek philosopher Plato) are a family of five convex polyhedra which exhibit a particularly high symmetry. They can be characterized by the following two properties: All its sides (faces) are regular polygons and congruent to each other, and the same number of sides meet in all its corners (vertices). However, they also satisfy the following much stronger symmetry condition: Each flag, i.e. each sequence consisting of a corner of an edge of a face, "looks the same". i.e., cannot be distinguished from the others by its position on the polyhedron. Because of this latter property they are called regular polyhedra.

The Greek names of the platonic solids are derived from the number of sides:

  • Tetrahedron: 4 equilateral triangles, 4 corners in which 3 sides meet
  • Hexahedron (or cube): 6 squares, 8 corners in which 3 sides meet
  • Octahedron: 8 equilateral triangles, 6 corners in which 4 sides meet
  • Dodecahedron: 12 regular pentagons, 20 corners in which 3 sides meet
  • Icosahedron: 20 equilateral triangles, 12 corners in which 5 sides meet

Enumeration

It is easy to see that there are at most five Platonic solids:

The corner of a convex polyhedron is formed by three or more sides, and the sum of the angles cannot exceed 2π.

  • Therefore there are only five possibilities: 3, 4, or 5 triangles (angle π/3), 3 squares (angle π/2), and 3 pentagons (angle 3π/5), corresponding to tetrahedron, octahedron, icosahedron, cube, and dodecahedron, respectively.
    Of these five possibilities three obviously give polyhedra with the desired properties. For the dodecahedron and the icosahedron, however, additional arguments are needed.
  • 6 triangles, 4 squares, and 3 hexagons (angle 2π/3) are special because in these three cases the sum of the angles is 2π, and they give the regular tilings of the plane.
  • For n>6, the angle for the regular n-gon is (n-2)π/n, and the sum of three angles is (3-6/n)π and thus is always greater than 2π. Therefore there are no corresponding solids.
  • There are two polyhedra with equilateral triangles as sides, a 3-sided and a 5-sided double-pyramid. But they are not Platonic solids since there meet 4 triangles at the base corners, but 3, respectively 5, triangles at the tops of the pyramids.

Duality

The midpoints of the sides of a Platonic sides - the corners of the dual polyhedron - is also a Platonic solid:

  • The cube and the octahedron are dual to each other.
  • The dodecahedron and the icosahedron are dual to each other.
  • The tetrahedron is dual to itself.

Table

number
of
faces
name type of face volume surface
area
properties image
4 regular tetrahedron
(or regular triangular pyramid)
equilateral triangle 4 vertices, 6 edges, self-dual Tetrahedron.png
6 cube square 8 vertices, 12 edges, dual to octahedron Cube.png
8 regular octahedron equilateral triangle 6 vertices, 12 edges, dual to cube Octahedron.png
12 regular dodecahedron regular pentagon 20 vertices, 30 edges, dual to icosahedron Dodecahedron.png
20 regular icosahedron equilateral triangle 12 vertices, 30 edges, dual to dodecahedron Icosahedron.png

A sphere circumscribed about any of the Platonic solids will touch all the vertices, and a sphere inscribed within any will touch all the faces at the center of the face.