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2. n-sphere - Wikipedia

   en.wikipedia.org/wiki/N-sphere

   In mathematics, an n-sphere or hypersphere is an ⁠ ⁠-dimensional generalization of the ⁠ ⁠-dimensional circle and ⁠ ⁠-dimensional sphere to any non-negative integer ⁠ ⁠. The circle is considered 1-dimensional, and the sphere 2-dimensional, because the surfaces themselves are 1- and 2-dimensional respectively, not because they ...

3. Kissing number - Wikipedia

   en.wikipedia.org/wiki/Kissing_number

   Finding the kissing number when centers of spheres are confined to a line (the one-dimensional case) or a plane (two-dimensional case) is trivial. Proving a solution to the three-dimensional case, despite being easy to conceptualise and model in the physical world, eluded mathematicians until the mid-20th century.

4. Homotopy groups of spheres - Wikipedia

   en.wikipedia.org/wiki/Homotopy_groups_of_spheres

   n = 1 produces the n-sphere as a geometric object in (n + 1)-dimensional space. For example, the 1-sphere S 1 is a circle. [2] Disk with collapsed rim: written in topology as D 2 /S 1; This construction moves from geometry to pure topology. The disk D 2 is the region contained by a circle, described by the inequality x 2 0 + x 2

5. Sphere - Wikipedia

   en.wikipedia.org/wiki/Spheres

   S ‍ 3: a 3-sphere is a sphere in 4-dimensional Euclidean space. Spheres for n > 2 are sometimes called hyperspheres. The n-sphere of unit radius centered at the origin is denoted S ‍ n and is often referred to as "the" n-sphere. The ordinary sphere is a 2-sphere, because it is a 2-dimensional surface which is embedded in 3-dimensional space.

6. Unit sphere - Wikipedia

   en.wikipedia.org/wiki/Unit_sphere

   Some 1-spheres: ‖x‖ 2 is the norm for Euclidean space. In mathematics, a unit sphere is a sphere of unit radius: the set of points at Euclidean distance 1 from some center point in three-dimensional space.

7. Lie sphere geometry - Wikipedia

   en.wikipedia.org/wiki/Lie_sphere_geometry

   The Lie quadric Q n is again defined as the set of [x] ∈ RP n+2 = P(R n+1,2) with x · x = 0. The quadric parameterizes oriented (n – 1)-spheres in n-dimensional space, including hyperplanes and point spheres as limiting cases. Note that Q n is an (n + 1)-dimensional manifold (spheres are parameterized by their center and radius).

8. Alexander's trick - Wikipedia

   en.wikipedia.org/wiki/Alexander's_trick

   Some authors use the term Alexander trick for the statement that every homeomorphism of can be extended to a homeomorphism of the entire ball .. However, this is much easier to prove than the result discussed above: it is called radial extension (or coning) and is also true piecewise-linearly, but not smoothly.

9. Complex projective space - Wikipedia

   en.wikipedia.org/wiki/Complex_projective_space

   Formally, a complex projective space is the space of complex lines through the origin of an (n+1)-dimensional complex vector space. The space is denoted variously as P(C n+1), P n (C) or CP n. When n = 1, the complex projective space CP 1 is the Riemann sphere, and when n = 2, CP 2 is the complex projective plane (see there for a more ...