Torus
Encyclopedia : T : TO : TOR : Torus
Geometry
In geometry, a torus (pl. tori) is a doughnut-shaped surface of revolution generated by revolving a circle about an axis coplanar with the circle. The sphere is a special case of the torus obtained when the axis of rotation is a diameter of the circle. If the axis of rotation does not intersect the circle, the torus has a hole in the middle and resembles a ring doughnut, a hula hoop or an inflated tire. The other case, when the axis of rotation is a chord of the circle, produces a sort of squashed sphere resembling a round cushion. Torus was the Latin word for a cushion of this shape.A torus can be defined parametrically by:
- [x(u, v) = (R + r\cos) \cos \, ]
- [y(u, v) = (R + r \cos) \sin \, ]
- [z(u, v) = r \sin \, ]
- u, v ∈ [0, 2π),
- R is the distance from the center of the tube to the center of the torus,
- r is the radius of the tube.
- [\left(R - \sqrt\right)^2 + z^2 = r^2]
- [A = 4\pi^2 Rr = \left( 2\pi r \right) \left( 2 \pi R \right) \,]
- [V = 2\pi^2R r^2 = \left( \pi r^2 \right) \left( 2\pi R \right). \,]
Topology
Topologically, a torus is a closed surface defined as product of two circles: S1 × S1. The surface described above, given the relative topology from R3, is homeomorphic to a topological torus as long as it does not intersect its own axis.
The torus can also be described as a quotient of the Cartesian plane under the identifications
- (x,y) ~ (x+1,y) ~ (x,y+1)
The fundamental group of the torus is just the direct product of the fundamental group of the circle with itself:
- [\pi_1(\mathbb^2) = \pi_1(S^1) \times \pi_1(S^1) \cong \mathbb \times \mathbb]
The first homology group of the torus is isomorphic to the fundamental group (since the fundamental group is abelian).
The n-torus
One can easily generalize the torus to arbitrary dimensions. An n-torus is defined as a product of n circles:
- [\mathbb^n = S^1 \times S^1 \times \cdots \times S^1]
An n-torus is an example of an n-dimensional compact manifold. It is also an example of a compact abelian Lie group. This follows from the fact that the unit circle is a compact abelian Lie group (when identified with the unit complex numbers with multiplication). Group multiplication on the torus is then defined by coordinate-wise multiplication.
Toroidal groups play an important part in the theory of compact Lie groups. This is due in part to the fact that in any compact Lie group one can always find a maximal torus; that is, a closed subgroup which is a torus of the largest possible dimension.
The fundamental group of an n-torus is a free abelian group of rank n. The k-th homology group of an n-torus is a free abelian group of rank n choose k. It follows that the Euler characteristic of the n-torus is 0 for all n. The cohomology ring H•(Tn,Z) can be identified with the exterior algebra over the Z-module Zn whose generators are the duals of the n nontrivial cycles.
Colouring a torus
If a torus is divided into regions, then it is always possible to colour the regions with at most seven colours so that neighbouring regions have different colours. (Contrast with four color theorem.) In the following example, the torus has been divided into seven regions, every one of which touches every other, illustrating why seven is the minimum possible for a torus:
See also
- Surface
- Toroid
- Torus (nuclear physics)
- Torus mandibularis
- Torus palatinus
- Villarceau circles
External links
- [Creation of a torus] at cut-the-knot
- [More Torus Images] (from [Math is Fun])
- Eric W. Weisstein. "Torus." From MathWorld--A Wolfram Web Resource. http://mathworld.wolfram.com/Torus.html
- [Images and movies of bubble rings] from David Whiteis' [BubbleRings.com]
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