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Hypersphere
The 
-hypersphere (often simply called the 
-sphere) is a generalization
of the circle (called by geometers the 2-sphere) and usual
sphere (called by geometers the 3-sphere) to dimensions
. The 
-sphere is therefore
defined (again, to a geometer; see below) as the set of 
-tuples of points
(
, 
, ..., 
) such that
 |
(1)
|
where 
is the radius
of the hypersphere.
Unfortunately, geometers and topologists adopt incompatible conventions for the meaning of "
-sphere," with geometers referring
to the number of coordinates in the underlying space ("thus a two-dimensional
sphere is a circle," Coxeter 1973, p. 125) and topologists referring to
the dimension of the surface itself ("the 
-dimensional sphere
is defined to be the set of all points 
in 
satisfying 
,"
Hocking and Young 1988, p. 17; "the 
-sphere 
is 
,"
Maunder 1997, p. 21). A geometer would therefore regard the object described
by
 |
(2)
|
as a 2-sphere, while a topologist would consider it a 1-sphere and denote it 
. Similarly, a geometer would regard the object
described by
 |
(3)
|
as a 3-sphere, while a topologist would call it a 2-sphere and denote it 
. Extreme caution
is therefore advised when consulting the literature. Following the literature, both
conventions are used in this work, depending on context, which is stated explicitly
wherever it might be ambiguous.
Let 
denote the content
(i.e., 
-dimensional volume)
of an 
-hypersphere (in the geometer's sense)
of radius 
is given by
 |
(4)
|
where 
is the hyper-surface
area of an 
-sphere of unit radius. A unit hypersphere
must satisfy
 |  |  |
(5)
|
 |  |  |
(6)
|
But the gamma function can be defined by
 |
(7)
|
so
![1/2S_nGamma(1/2n)=[Gamma(1/2)]^n=(pi^(1/2))^n](/web/20140329092736im_/http://mathworld.wolfram.com/images/equations/Hypersphere/NumberedEquation6.gif) |
(8)
|
 |
(9)
|
Special forms of 
for 
an integer allow
the above expression to be written as
 |
(10)
|
where 
is a factorial
and 
is a double factorial
(Sloane's A072478 and A072479).
Strangely enough, for the unit hypersphere, the hyper-surface area reaches a maximum and then decreases towards
0 as 
increases. The point of maximal
hyper-surface area satisfies
![(dS_n)/(dn)=(pi^(n/2)[lnpi-psi_0(1/2n)])/(Gamma(1/2n))=0,](/web/20140329092736im_/http://mathworld.wolfram.com/images/equations/Hypersphere/NumberedEquation9.gif) |
(11)
|
where 
is the digamma
function. This cannot be solved analytically for 
, but the numerical
solution is 
(Sloane's A074457;
Wells 1986, p. 67). As a result, the seven-dimensional unit hypersphere has
maximum hyper-surface area
(Le Lionnais 1983; Wells 1986, p. 60).
In four dimensions, the generalization of spherical coordinates is given by
 |  |  |
(12)
|
 |  |  |
(13)
|
 |  |  |
(14)
|
 |  |  |
(15)
|
The equation for the 3-sphere 
is therefore
 |
(16)
|
and the line element is
![ds^2=R^2[dpsi^2+sin^2psi(dphi^2+sin^2phidtheta^2)].](/web/20140329092736im_/http://mathworld.wolfram.com/images/equations/Hypersphere/NumberedEquation11.gif) |
(17)
|
By defining 
, the line
element can be rewritten
 |
(18)
|
The hyper-surface area is therefore given by
 |  |  |
(19)
|
 |  |  |
(20)
|
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hypersphere
