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PYRAMID (GEOMETRY)

Set of pyramids
Square Pyramid
Facesn triangles,
1 n-gon
Edges2n
Verticesn+1
Symmetry group''C''''nv''
Dual polyhedronSelf-duals
Propertiesconvex

:''This article is about the polyhedron pyramid (a 3-dimensional shape); for other versions including architectural Pyramids, see Pyramid (disambiguation).''
An ''n''-sided 'pyramid' is a polyhedron formed by connecting an ''n''-sided polygonal base and a point, called the apex, by ''n'' triangular faces (''n'' ≥ 3). In other words, it is a conic solid with polygonal base.
When unspecified, the base is usually assumed to be square. For a triangular pyramid each face can serve as base, with the opposite vertex as apex. The regular tetrahedron, one of the Platonic solids, is a triangular pyramid. The square and pentagonal pyramids can also be constructed with all faces regular, and are therefore Johnson solids. All pyramids are self-dual.
Pyramids are a subclass of the prismatoids. The 1-skeleton of pyramid is a wheel graph.

Contents
Volume
Surface Area
Pyramids with regular polygon faces
Symmetry
See also
External links

Volume


The volume of a pyramid is V = rac{1}{3} Ah where ''A'' is the area of the base and ''h'' the height from the base to the apex. This works for any location of the apex, provided that ''h'' is measured as the perpendicular distance from the plane which contains the base.
This can be proven using calculus:
:It can be proved using similarity that the dimensions of a cross section parallel to the base increase linearly from the apex to the base. Then, the cross section at any height ''y'' is the base scaled by a factor of rac{h-y}{h}, where ''h'' is the height from the base to the apex. Since the area of any shape is multiplied by the square of the shape's scaling factor, the area of a cross section at height ''y'' is rac{A}{h^2}(h-y)^2.
:The volume is given by the integral rac{A}{h^2} int_0^h (h-y)^2 , dy = rac{-A}{3h^2} (h-y)^3 igg|_0^h = rac{1}{3}Ah

Surface Area


The surface area of a regular pyramid is A = A_b + rac{ps}{2} where A_b is the area of the base, ''p'' is the perimeter of the base, and ''s'' is the slant height along the bisector of a face (ie the length from the midpoint of any edge of the base to the apex).

Pyramids with regular polygon faces


If all faces are regular polygons, the pyramid base can be a regular polygon of 3-, 4- or 5-sided:
NameTetrahedronSquare pyramidPentagonal pyramid
ClassPlatonic solidJohnson solid (J1)Johnson solid (J2)
Baseequilaterial triangleSquareregular pentagon
Symmetry
group		TdC4vC5v

If this were attempted with a regular hexagonal base, the equilateral triangles would have to lay flat in order to meet on the center axis, giving the pyramid zero height and zero volume (a degenerate case). With a regular polygon with more than six sides, they would not meet even then.
The geometric center of a square-based pyramid is located on the symmetry axis, one quarter of the way from the base to the apex.
Symmetry

If the base is regular and the apex is above the center, the symmetry group of the ''n''-sided pyramid is ''Cnv'' of order 2''n'', except in the case of a regular tetrahedron, which has the larger symmetry group 'Td' of order 24, which has four versions of ''C3v'' as subgroups.
The rotation group is ''Cn'' of order ''n'', except in the case of a regular tetrahedron, which has the larger rotation group 'T' of order 12, which has four versions of ''C3'' as subgroups.

See also



Bipyramid

Cone (geometry)

Trigonal pyramid (chemistry)

External links







The Uniform Polyhedra

Virtual Reality Polyhedra The Encyclopedia of Polyhedra


VRML models (George Hart) <3> <4> <5>

Paper models of pyramids

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