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In mathematics, the unitary group of degree n, denoted U(n), is the group of Template:Nowrap unitary matrices, with the group operation of matrix multiplication. The unitary group is a subgroup of the general linear group Template:Nowrap, and it has as a subgroup the special unitary group, consisting of those unitary matrices with determinant 1.
In the simple case Template:Nowrap, the group U(1) corresponds to the circle group, isomorphic to the set of all complex numbers that have absolute value 1, under multiplication. All the unitary groups contain copies of this group.
The unitary group U(n) is a real Lie group of dimension n2. The Lie algebra of U(n) consists of Template:Nowrap skew-Hermitian matrices, with the Lie bracket given by the commutator.
The general unitary group, also called the group of unitary similitudes, consists of all matrices A such that A∗A is a nonzero multiple of the identity matrix, and is just the product of the unitary group with the group of all positive multiples of the identity matrix.
Unitary groups may also be defined over fields other than the complex numbers. The hyperorthogonal group is an archaic name for the unitary group, especially over finite fields.
PropertiesEdit
Since the determinant of a unitary matrix is a complex number with norm 1, the determinant gives a group homomorphism
- <math>\det \colon \operatorname{U}(n) \to \operatorname{U}(1).</math>
The kernel of this homomorphism is the set of unitary matrices with determinant 1. This subgroup is called the special unitary group, denoted SU(n). We then have a short exact sequence of Lie groups:
- <math>1 \to \operatorname{SU}(n) \to \operatorname{U}(n) \to \operatorname{U}(1) \to 1.</math>
The above map U(n) to U(1) has a section: we can view U(1) as the subgroup of U(n) that are diagonal with eiθ in the upper left corner and 1 on the rest of the diagonal. Therefore U(n) is a semidirect product of U(1) with SU(n).
The unitary group U(n) is not abelian for Template:Nowrap. The center of U(n) is the set of scalar matrices λI with Template:Nowrap; this follows from Schur's lemma. The center is then isomorphic to U(1). Since the center of U(n) is a 1-dimensional abelian normal subgroup of U(n), the unitary group is not semisimple, but it is reductive.
TopologyEdit
The unitary group U(n) is endowed with the relative topology as a subset of Template:Nowrap, the set of all Template:Nowrap complex matrices, which is itself homeomorphic to a 2n2-dimensional Euclidean space.
As a topological space, U(n) is both compact and connected. To show that U(n) is connected, recall that any unitary matrix A can be diagonalized by another unitary matrix S. Any diagonal unitary matrix must have complex numbers of absolute value 1 on the main diagonal. We can therefore write
- <math>A = S\,\operatorname{diag}\left(e^{i\theta_1}, \dots, e^{i\theta_n}\right)\,S^{-1}.</math>
A path in U(n) from the identity to A is then given by
- <math>t \mapsto S \, \operatorname{diag}\left(e^{it\theta_1}, \dots, e^{it\theta_n}\right)\,S^{-1} .</math>
The unitary group is not simply connected; the fundamental group of U(n) is infinite cyclic for all n:<ref>Template:Harvnb Proposition 13.11</ref>
- <math>\pi_1(\operatorname{U}(n)) \cong \mathbf{Z} .</math>
To see this, note that the above splitting of U(n) as a semidirect product of SU(n) and U(1) induces a topological product structure on U(n), so that
- <math>\pi_1(\operatorname{U}(n)) \cong \pi_1(\operatorname{SU}(n)) \times \pi_1(\operatorname{U}(1)).</math>
Now the first unitary group U(1) is topologically a circle, which is well known to have a fundamental group isomorphic to Z, whereas SU(n) is simply connected.<ref>Template:Harvnb Proposition 13.11</ref>
The determinant map Template:Nowrap induces an isomorphism of fundamental groups, with the splitting Template:Nowrap inducing the inverse.
The Weyl group of U(n) is the symmetric group Sn, acting on the diagonal torus by permuting the entries:
- <math>\operatorname{diag}\left(e^{i\theta_1}, \dots, e^{i\theta_n}\right) \mapsto \operatorname{diag}\left(e^{i\theta_{\sigma(1)}}, \dots, e^{i\theta_{\sigma(n)}}\right)</math>
Related groupsEdit
2-out-of-3 propertyEdit
The unitary group is the 3-fold intersection of the orthogonal, complex, and symplectic groups:
- <math>\operatorname{U}(n) = \operatorname{O}(2n) \cap \operatorname{GL}(n, \mathbf{C}) \cap \operatorname{Sp}(2n, \mathbf{R}) .</math>
Thus a unitary structure can be seen as an orthogonal structure, a complex structure, and a symplectic structure, which are required to be compatible (meaning that one uses the same J in the complex structure and the symplectic form, and that this J is orthogonal; writing all the groups as matrix groups fixes a J (which is orthogonal) and ensures compatibility).
In fact, it is the intersection of any two of these three; thus a compatible orthogonal and complex structure induce a symplectic structure, and so forth.<ref>Template:Cite book</ref><ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>
At the level of equations, this can be seen as follows:
- <math>\begin{array}{r|r}
\text{Symplectic} &
A^\mathsf{T}JA = J \\
\hline
\text{Complex} &
A^{-1}JA = J \\
\hline
\text{Orthogonal} &
A^\mathsf{T} = A^{-1}
\end{array}</math>
Any two of these equations implies the third.
At the level of forms, this can be seen by decomposing a Hermitian form into its real and imaginary parts: the real part is symmetric (orthogonal), and the imaginary part is skew-symmetric (symplectic)—and these are related by the complex structure (which is the compatibility). On an almost Kähler manifold, one can write this decomposition as Template:Nowrap, where h is the Hermitian form, g is the Riemannian metric, i is the almost complex structure, and ω is the almost symplectic structure.
From the point of view of Lie groups, this can partly be explained as follows: O(2n) is the maximal compact subgroup of Template:Nowrap, and U(n) is the maximal compact subgroup of both Template:Nowrap and Sp(2n). Thus the intersection Template:Nowrap or Template:Nowrap is the maximal compact subgroup of both of these, so U(n). From this perspective, what is unexpected is the intersection Template:Nowrap.
Special unitary and projective unitary groupsEdit
Just as the orthogonal group O(n) has the special orthogonal group SO(n) as subgroup and the projective orthogonal group PO(n) as quotient, and the projective special orthogonal group PSO(n) as subquotient, the unitary group U(n) has associated to it the special unitary group SU(n), the projective unitary group PU(n), and the projective special unitary group PSU(n). These are related as by the commutative diagram at right; notably, both projective groups are equal: Template:Nowrap.
The above is for the classical unitary group (over the complex numbers) – for unitary groups over finite fields, one similarly obtains special unitary and projective unitary groups, but in general Template:Nowrap.
G-structure: almost HermitianEdit
In the language of G-structures, a manifold with a U(n)-structure is an almost Hermitian manifold.
GeneralizationsEdit
From the point of view of Lie theory, the classical unitary group is a real form of the Steinberg group 2An, which is an algebraic group that arises from the combination of the diagram automorphism of the general linear group (reversing the Dynkin diagram An, which corresponds to transpose inverse) and the field automorphism of the extension C/R (namely complex conjugation). Both these automorphisms are automorphisms of the algebraic group, have order 2, and commute, and the unitary group is the fixed points of the product automorphism, as an algebraic group. The classical unitary group is a real form of this group, corresponding to the standard Hermitian form Ψ, which is positive definite.
This can be generalized in a number of ways:
- generalizing to other Hermitian forms yields indefinite unitary groups Template:Nowrap;
- the field extension can be replaced by any degree 2 separable algebra, most notably a degree 2 extension of a finite field;
- generalizing to other diagrams yields other groups of Lie type, namely the other Steinberg groups 2Dn, 2E6, 3D4, (in addition to 2An) and Suzuki–Ree groups
- <math>{}^2\!B_2\left(2^{2n+1}\right), {}^2\!F_4\left(2^{2n+1}\right), {}^2\!G_2\left(3^{2n+1}\right);</math>
- considering a generalized unitary group as an algebraic group, one can take its points over various algebras.
Indefinite formsEdit
Analogous to the indefinite orthogonal groups, one can define an indefinite unitary group, by considering the transforms that preserve a given Hermitian form, not necessarily positive definite (but generally taken to be non-degenerate). Here one is working with a vector space over the complex numbers.
Given a Hermitian form Ψ on a complex vector space V, the unitary group U(Ψ) is the group of transforms that preserve the form: the transform M such that Template:Nowrap for all Template:Nowrap. In terms of matrices, representing the form by a matrix denoted Φ, this says that Template:Nowrap.
Just as for symmetric forms over the reals, Hermitian forms are determined by signature, and are all unitarily congruent to a diagonal form with p entries of 1 on the diagonal and q entries of −1. The non-degenerate assumption is equivalent to Template:Nowrap. In a standard basis, this is represented as a quadratic form as:
- <math>\lVert z \rVert_\Psi^2 = \lVert z_1 \rVert^2 + \dots + \lVert z_p \rVert^2 - \lVert z_{p+1} \rVert^2 - \dots - \lVert z_n \rVert^2</math>
and as a symmetric form as:
- <math>\Psi(w, z) = \bar w_1 z_1 + \cdots + \bar w_p z_p - \bar w_{p+1}z_{p+1} - \cdots - \bar w_n z_n.</math>
The resulting group is denoted Template:Nowrap.
Finite fieldsEdit
Over the finite field with Template:Nowrap elements, Fq, there is a unique quadratic extension field, Fq2, with order 2 automorphism <math>\alpha\colon x \mapsto x^q</math> (the rth power of the Frobenius automorphism). This allows one to define a Hermitian form on an Fq2 vector space V, as an Fq-bilinear map <math>\Psi\colon V \times V \to K</math> such that <math>\Psi(w, v) = \alpha \left(\Psi(v, w)\right)</math> and <math>\Psi(w, cv) = c\Psi(w, v)</math> for Template:Nowrap.Template:Clarify Further, all non-degenerate Hermitian forms on a vector space over a finite field are unitarily congruent to the standard one, represented by the identity matrix; that is, any Hermitian form is unitarily equivalent to
- <math>\Psi(w, v) = w^\alpha \cdot v = \sum_{i=1}^n w_i^q v_i</math>
where <math>w_i,v_i</math> represent the coordinates of Template:Nowrap in some particular Fq2-basis of the n-dimensional space V Template:Harv.
Thus one can define a (unique) unitary group of dimension n for the extension Fq2/Fq, denoted either as Template:Nowrap or Template:Nowrap depending on the author. The subgroup of the unitary group consisting of matrices of determinant 1 is called the special unitary group and denoted Template:Nowrap or Template:Nowrap. For convenience, this article will use the Template:Nowrap convention. The center of Template:Nowrap has order Template:Nowrap and consists of the scalar matrices that are unitary, that is those matrices cIV with <math>c^{q+1} = 1</math>. The center of the special unitary group has order Template:Nowrap and consists of those unitary scalars which also have order dividing n. The quotient of the unitary group by its center is called the projective unitary group, Template:Nowrap, and the quotient of the special unitary group by its center is the projective special unitary group Template:Nowrap. In most cases (Template:Nowrap and Template:Nowrap), Template:Nowrap is a perfect group and Template:Nowrap is a finite simple group, Template:Harv.
Degree-2 separable algebrasEdit
More generally, given a field k and a degree-2 separable k-algebra K (which may be a field extension but need not be), one can define unitary groups with respect to this extension.
First, there is a unique k-automorphism of K <math>a \mapsto \bar a</math> which is an involution and fixes exactly k (<math>a = \bar{a}</math> if and only if Template:Nowrap).<ref>Milne, Algebraic Groups and Arithmetic Groups, p. 103</ref> This generalizes complex conjugation and the conjugation of degree 2 finite field extensions, and allows one to define Hermitian forms and unitary groups as above.
Algebraic groupsEdit
The equations defining a unitary group are polynomial equations over k (but not over K): for the standard form Template:Nowrap, the equations are given in matrices as Template:Nowrap, where <math>A^* = \bar{A}^\mathsf{T}</math> is the conjugate transpose. Given a different form, they are Template:Nowrap. The unitary group is thus an algebraic group, whose points over a k-algebra R are given by:
- <math>\operatorname{U}(n, K/k, \Phi)(R) := \left\{ A \in \operatorname{GL}(n, K \otimes_k R) : A^*\Phi A = \Phi\right\}.</math>
For the field extension C/R and the standard (positive definite) Hermitian form, these yield an algebraic group with real and complex points given by:
- <math>\begin{align}
\operatorname{U}(n, \mathbf{C}/\mathbf{R})(\mathbf{R}) &= \operatorname{U}(n) \\
\operatorname{U}(n, \mathbf{C}/\mathbf{R})(\mathbf{C}) &= \operatorname{GL}(n, \mathbf{C}).
\end{align}</math>
In fact, the unitary group is a linear algebraic group.
Unitary group of a quadratic moduleEdit
The unitary group of a quadratic module is a generalisation of the linear algebraic group U just defined, which incorporates as special cases many different classical algebraic groups. The definition goes back to Anthony Bak's thesis.<ref>Bak, Anthony (1969), "On modules with quadratic forms", Algebraic K-Theory and its Geometric Applications (editors—Moss R. M. F., Thomas C. B.) Lecture Notes in Mathematics, Vol. 108, pp. 55-66, Springer. {{#invoke:doi|main}}</ref>
To define it, one has to define quadratic modules first:
Let R be a ring with anti-automorphism J, <math>\varepsilon \in R^\times</math> such that <math>r^{J^2} = \varepsilon r \varepsilon^{-1}</math> for all r in R and <math>\varepsilon^J = \varepsilon^{-1}</math>. Define
- <math>\begin{align}
\Lambda_\text{min} &:= \left\{r \in R \ : \ r - r^J\varepsilon\right\}, \\
\Lambda_\text{max} &:= \left\{r \in R \ : \ r^J\varepsilon = -r\right\}.
\end{align}</math>
Let Template:Nowrap be an additive subgroup of R, then Λ is called form parameter if <math>\Lambda_\text{min} \subseteq \Lambda \subseteq \Lambda_\text{max}</math> and <math>r^J \Lambda r \subseteq \Lambda</math>. A pair Template:Nowrap such that R is a ring and Λ a form parameter is called form ring.
Let M be an R-module and f a J-sesquilinear form on M (i.e., <math>f(xr, ys) = r^J f(x, y)s</math> for any <math>x, y \in M</math> and <math>r, s \in R</math>). Define <math>h(x, y) := f(x, y) + f(y, x)^J \varepsilon \in R</math> and <math>q(x) := f(x, x) \in R/\Lambda</math>, then f is said to define the Λ-quadratic form Template:Nowrap on M. A quadratic module over Template:Nowrap is a triple Template:Nowrap such that M is an R-module and Template:Nowrap is a Λ-quadratic form.
To any quadratic module Template:Nowrap defined by a J-sesquilinear form f on M over a form ring Template:Nowrap one can associate the unitary group
- <math>U(M) := \{\sigma \in GL(M) \ : \ \forall x, y \in M, h(\sigma x, \sigma y) = h(x, y) \text{ and } q(\sigma x) = q(x) \}.</math>
The special case where Template:Nowrap, with J any non-trivial involution (i.e., <math>J \neq id_R, J^2 = id_R</math> and Template:Nowrap gives back the "classical" unitary group (as an algebraic group).
Polynomial invariantsEdit
The unitary groups are the automorphisms of two polynomials in real non-commutative variables:
- <math>\begin{align}
C_1 &= \left(u^2 + v^2\right) + \left(w^2 + x^2\right) + \left(y^2 + z^2\right) + \ldots \\ C_2 &= \left(uv - vu\right) + \left(wx - xw\right) + \left(yz - zy\right) + \ldots
\end{align}</math>
These are easily seen to be the real and imaginary parts of the complex form <math>Z \overline{Z}</math>. The two invariants separately are invariants of O(2n) and Sp(2n). Combined they make the invariants of U(n) which is a subgroup of both these groups. The variables must be non-commutative in these invariants otherwise the second polynomial is identically zero.
Classifying spaceEdit
The classifying space for U(n) is described in the article Classifying space for U(n).