Circle group

Encyclopedia : C : CI : CIR : Circle group

In mathematics, the circle group, denoted by T (or in blackboard bold by [\mathbb T]), is the multiplicative group of all complex numbers with absolute value 1. The name comes from the fact that these numbers lie on the unit circle in the complex plane.

[\mathbb T = \.]

The circle group forms a subgroup of C^×, the multiplicative group of all nonzero complex numbers. Since C^× is abelian, it follows that T is as well.

The notation T for the circle group stems from the fact that Tⁿ (the direct product of T with itself n times) is geometrically an n-torus. The circle group is then a 1-torus.

Contents

1 Elementary introduction
2 Topological and analytic structure
3 Isomorphisms
4 Algebraic structure
5 See also

Elementary introduction

One way to think about the circle group is that it describes how to add angles, where only angles between 0° and 360° are permitted. For example, the diagram illustrates how to add 150° to 270°. The answer should be 150° + 270° = 420°, but when thinking in terms of the circle group, we need to "forget" the fact that we have wrapped once around the circle. Therefore we adjust our answer by 360° which gives 420° − 360° = 60°.

Another description is in terms of ordinary addition, where only numbers between 0 and 1 are allowed. To achieve this, we might need to throw away digits occurring before the decimal point. For example, when we work out 0.784 + 0.925 + 0.446, the answer should be 2.155, but we throw away the leading 2, so the answer (in the circle group) is just 0.155.

Topological and analytic structure

The circle group is more than just an abstract algebraic group. It has a natural topology when regarded as a subspace of the complex plane. Since multiplication and inversion are continuous functions on C^×, the circle group has the structure of a topological group. Moreover, since the unit circle is a closed subset of the complex plane, the circle group is a closed subgroup of C^× (itself regarded as a topological group).

One can say even more. The circle is a 1-dimensional manifold and multiplication and inversion are real-analytic maps on the circle. This gives the circle group the structure of a 1-dimensional Lie group. In fact, up to isomorphism, it is the unique 1-dimensional compact, connected Lie group. Moreover, every n-dimensional compact, connected, abelian Lie group is isomorphic to Tⁿ.

Any compact Lie group G of dimension > 0 has a subgroup isomorphic to the circle group. That means that, thinking in terms of symmetry, a compact symmetry group acting continuously can be expected to have one-parameter circle subgroups acting; the consequences in physical systems are seen for example at rotational invariance, and spontaneous symmetry breaking.

The circle group has many subgroups, but its only proper closed subgroups consist of roots of unity: there is one such, that is cyclic of order n, for each integer n > 0.

Isomorphisms

The circle group shows up in a huge variety of forms in mathematics. We list some of the more common forms here. Specifically, we show that

[\mathbb T \cong \mbox(1) \cong \mbox(2) \cong \mathbb R/\mathbb Z.\,]

The set of all 1×1 unitary matrices clearly coincides with the circle group; the unitary condition is equivalent to the condition that its element have absolute value 1. Therefore, the circle group is canonically isomorphic to U(1), the first unitary group.

The exponential function gives rise to a group homomorphism exp : R → T from the additive real numbers R to the circle group T via the map

[\theta \mapsto e^ = \cos\theta + i\sin\theta.]

The last equality is Euler's formula. The real number [\theta] corresponds to the angle on the unit circle as measured from the positive x-axis. That this map is a homomorphism follows from the fact the multiplication of unit complex numbers corresponds to addition of angles:

[e^e^ = e^.\,]

This exponential map is clearly a surjective function from R to T. It is not, however, injective. The kernel of this map is the set of all integer multiples of [2\pi]. By the first isomorphism theorem we then have that

[\mathbb T \cong \mathbb R/2\pi\mathbb Z.\,]

After rescaling we can also say that T is isomorphic to R/Z.

If complex numbers are realized as 2×2 real matrices (see complex number), the unit complex numbers correspond to 2×2 orthogonal matrices with unit determinant. Specifically, we have

[ e^ \leftrightarrow \begin\cos \theta & -\sin \theta \\\sin \theta & \cos \theta \\\end.]

The circle group is therefore isomorphic to the special orthogonal group SO(2). This has the geometric interpretation that multiplication by a unit complex number is a proper rotation in the complex plane, and every such rotation is of this form.

Algebraic structure

In this section we will forget about the topological structure of the circle group and look only at its algebraic structure.

The circle group T is a divisible group. Its torsion subgroup is given by the set of all nth roots of unity for all n, and is isomorphic to Q/Z. The structure theorem for divisible groups tells us that T is isomorphic to the direct sum of Q/Z with a number of copies of Q. The number of copies of Q must be c (the cardinality of the continuum) in order for the cardinality of the direct sum to be correct. But the direct sum of c copies of Q is isomorphic to R, as R is a vector space of dimension c over Q. Thus

[\mathbb T \cong \mathbb R \oplus (\mathbb Q / \mathbb Z).\,]

The isomorphism

[\mathbb C^\times \cong \mathbb R \oplus (\mathbb Q / \mathbb Z)]

can be proved in the same way, as C^× is also a divisible abelian group whose torsion subgroup is the same as the torsion subgroup of T.

Circle group

Elementary introduction

Topological and analytic structure

Isomorphisms

Algebraic structure

See also