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The | In mathematics, the '''Schur orthogonality relations''' express a central fact about [[group representation|representations]] of finite [[group (mathematics)|groups]]. | ||
They admit a generalization to the case of [[compact group]]s in general, and in particular [[compact group|compact Lie groups]], such as the | |||
[[Rotation group SO(3)|rotation group ''SO''(3)]]. | |||
==Finite groups== | |||
===Intrinsic statement=== | |||
The space of complex-valued [[class function]]s of a finite group G has a natural [[inner product space|inner product]]: | |||
:<math>\left \langle \alpha, \beta\right \rangle := \frac{1}{ \left | G \right | }\sum_{g \in G} \alpha(g) \overline{\beta(g)}</math> | |||
where <math>\overline{\beta(g)}</math> means the complex conjugate of the value of <math>\beta</math> on ''g''. With respect to this inner product, the irreducible [[character theory|characters]] form an orthonormal basis | |||
for the space of class functions, and this yields the orthogonality relation for the rows of the character | |||
table: | |||
:<math>\left \langle \chi_i, \chi_j \right \rangle = \begin{cases} 0 & \mbox{ if } i \ne j, \\ 1 & \mbox{ if } i = j. \end{cases}</math> | |||
For <math>g, h \in G</math> the orthogonality relation for columns is as follows: | |||
:<math>\sum_{\chi_i} \chi_i(g) \overline{\chi_i(h)} = \begin{cases} \left | C_G(g) \right |, & \mbox{ if } g, h \mbox{ are conjugate } \\ 0 & \mbox{ otherwise.}\end{cases}</math> | |||
where the sum is over all of the irreducible characters <math>\chi_i</math> of ''G'' and the symbol <math>\left | C_G(g) \right |</math> denotes the order of the [[centralizer]] of <math>g</math>. | |||
The orthogonality relations can aid many computations including: | |||
* decomposing an unknown character as a linear combination of irreducible characters; | |||
* constructing the complete character table when only some of the irreducible characters are known; | |||
* finding the orders of the centralizers of representatives of the conjugacy classes of a group; and | |||
* finding the order of the group. | |||
===Coordinates statement=== | |||
Let <math>\Gamma^{(\lambda)} (R)_{mn}</math> be a [[Matrix (mathematics)|matrix]] element of an [[irreducible representation|irreducible]] [[Group representation|matrix representation]] | |||
<math>\Gamma^{(\lambda)}</math> of a finite group <math>G=\{R\}</math> of order |''G''|, i.e., ''G'' has |''G''| elements. Since it can be proven that any matrix representation of any finite group is equivalent to a [[unitary representation]], we assume <math>\Gamma^{(\lambda)}</math> is unitary: | |||
:<math> | |||
\sum_{n=1}^{l_\lambda} \; \Gamma^{(\lambda)} (R)_{nm}^*\;\Gamma^{(\lambda)} (R)_{nk} = \delta_{mk} \quad \hbox{for all}\quad R \in G, | |||
</math> | |||
where <math>l_\lambda</math> is the (finite) dimension of the irreducible representation <math>\Gamma^{(\lambda)}</math>.<ref>The finiteness of <math>l_\lambda</math> follows from the fact that any irreducible representation of a finite group ''G'' is contained in the [[regular representation]].</ref> | |||
The '''orthogonality relations''', only valid for matrix elements of ''irreducible'' representations, are: | |||
:<math> | |||
\sum_{R\in G}^{|G|} \; \Gamma^{(\lambda)} (R)_{nm}^*\;\Gamma^{(\mu)} (R)_{n'm'} = | |||
\delta_{\lambda\mu} \delta_{nn'}\delta_{mm'} \frac{|G|}{l_\lambda}. | |||
</math> | |||
Here <math>\Gamma^{(\lambda)} (R)_{nm}^*</math> is the complex conjugate of <math>\Gamma^{(\lambda)} (R)_{nm}\,</math> and the sum is over all elements of ''G''. | |||
The [[Kronecker delta]] <math>\delta_{\lambda\mu}</math> is unity if the matrices are in the same irreducible representation <math>\Gamma^{(\lambda)}= \Gamma^{(\mu)}</math>. If <math>\Gamma^{(\lambda)}</math> and <math>\Gamma^{(\mu)}</math> are non-equivalent | |||
it is zero. The other two Kronecker delta's state that | |||
the row and column indices must be equal (<math>n=n'</math> and <math>m=m'</math>) in order to obtain a non-vanishing result. This theorem is also known as the Great (or Grand) Orthogonality Theorem. | |||
Every group has an identity representation (all group elements mapped onto the real number 1). | |||
This is an irreducible representation. The great orthogonality relations immediately imply that | |||
:<math> | |||
\sum_{R\in G}^{|G|} \; \Gamma^{(\mu)} (R)_{nm} = 0 | |||
</math> | |||
for <math>n,m=1,\ldots,l_\mu</math> and any irreducible representation <math>\Gamma^{(\mu)}\,</math> not equal to the identity representation. | |||
===Example of the permutation group on 3 objects=== | |||
The 3! permutations of three objects form a group of order 6, commonly denoted by <math>S_3</math> ([[symmetric group]]). This group is isomorphic to the [[Point groups in three dimensions#The seven infinite series|point group]] <math>C_{3v}</math>, consisting of a threefold rotation axis and three vertical mirror planes. The groups have a 2-dimensional irreducible representation (''l'' = 2). In the case of <math>S_3</math> one usually labels this representation | |||
by the [[Young tableau]] <math> \lambda = [2,1]</math> and in the case of <math>C_{3v}</math> | |||
one usually writes <math> \lambda = E</math>. In both cases the representation consists of the following six real matrices, each representing a single group element:<ref>This choice is not unique, any orthogonal similarity transformation | |||
applied to the matrices gives a valid irreducible representation.</ref> | |||
:<math> | |||
\begin{pmatrix} | |||
1 & 0 \\ | |||
0 & 1 \\ | |||
\end{pmatrix} | |||
\quad | |||
\begin{pmatrix} | |||
1 & 0 \\ | |||
0 & -1 \\ | |||
\end{pmatrix} | |||
\quad | |||
\begin{pmatrix} | |||
-\frac{1}{2} & \frac{\sqrt{3}}{2} \\ | |||
\frac{\sqrt{3}}{2}& \frac{1}{2} \\ | |||
\end{pmatrix} | |||
\quad | |||
\begin{pmatrix} | |||
-\frac{1}{2} & -\frac{\sqrt{3}}{2} \\ | |||
-\frac{\sqrt{3}}{2}& \frac{1}{2} \\ | |||
\end{pmatrix} | |||
\quad | |||
\begin{pmatrix} | |||
-\frac{1}{2} & \frac{\sqrt{3}}{2} \\ | |||
-\frac{\sqrt{3}}{2}& -\frac{1}{2} \\ | |||
\end{pmatrix} | |||
\quad | |||
\begin{pmatrix} | |||
-\frac{1}{2} & -\frac{\sqrt{3}}{2} \\ | |||
\frac{\sqrt{3}}{2}& -\frac{1}{2} \\ | |||
\end{pmatrix} | |||
</math> | |||
The normalization of the (1,1) element: | |||
:<math> \sum_{R\in G}^{6} \; \Gamma(R)_{11}^*\;\Gamma(R)_{11} = 1^2+1^2+\left(-\tfrac{1}{2}\right)^2+\left(-\tfrac{1}{2}\right)^2 +\left(-\tfrac{1}{2}\right)^2 +\left(-\tfrac{1}{2}\right)^2 | |||
= 3 . | |||
</math> | |||
In the same manner one can show the normalization of the other matrix elements: (2,2), (1,2), and (2,1). | |||
The orthogonality of the (1,1) and (2,2) elements: | |||
:<math> \sum_{R\in G}^{6} \; \Gamma(R)_{11}^*\;\Gamma(R)_{22} = 1^2+(1)(-1)+\left(-\tfrac{1}{2}\right)\left(\tfrac{1}{2}\right) | |||
+\left(-\tfrac{1}{2}\right)\left(\tfrac{1}{2}\right) | |||
+\left(-\tfrac{1}{2}\right)^2 +\left(-\tfrac{1}{2}\right)^2 | |||
= 0 . | |||
</math> | |||
Similar relations hold for the orthogonality of the elements (1,1) and (1,2), etc. | |||
One verifies easily in the example that all sums of corresponding matrix elements vanish because of | |||
the orthogonality of the given irreducible representation to the identity representation. | |||
===Direct implications=== | |||
The [[trace (linear algebra)|trace]] of a matrix is a sum of diagonal matrix elements, | |||
:<math>\operatorname{Tr}\big(\Gamma(R)\big) = \sum_{m=1}^{l} \Gamma(R)_{mm}.</math> | |||
The collection of traces is the ''character'' <math>\chi \equiv \{\operatorname{Tr}\big(\Gamma(R)\big)\;|\; R \in G\}</math> of a representation. Often one writes for | |||
the trace of a matrix in an irreducible representation with character <math>\chi^{(\lambda)}</math> | |||
:<math>\chi^{(\lambda)} (R)\equiv \operatorname{Tr}\left(\Gamma^{(\lambda)}(R)\right).</math> | |||
In this notation we can write several character formulas: | |||
:<math>\sum_{R\in G}^{|G|} \chi^{(\lambda)}(R)^* \, \chi^{(\mu)}(R)= \delta_{\lambda\mu} |G|,</math> | |||
which allows us to check whether or not a representation is irreducible. (The formula means that the lines in any character table have to be orthogonal vectors.) | |||
And | |||
:<math>\sum_{R\in G}^{|G|} \chi^{(\lambda)}(R)^* \, \chi(R) = n^{(\lambda)} |G|,</math> | |||
which helps us to determine how often the irreducible representation <math>\Gamma^{(\lambda)}</math> is contained within the reducible representation <math>\Gamma \,</math> with character <math>\chi(R)</math>. | |||
For instance, if | |||
:<math>n^{(\lambda)}\, |G| = 96</math> | |||
and the order of the group is | |||
:<math>|G| = 24\,</math> | |||
then the number of times that <math>\Gamma^{(\lambda)}\,</math> is contained within the given | |||
''reducible'' representation <math>\Gamma \,</math> is | |||
:<math>n^{(\lambda)} = 4\, .</math> | |||
''See [[Character theory]] for more about group characters.'' | |||
<!--- | |||
I don't understand the meaning of the following lines [P.wormer] | |||
or | |||
:<math>n_j = 1^2 1^2 1^2 1^2. \,</math> | |||
And lastly, | |||
:<math>\sum_{\hat R}^N {\begin{vmatrix}{\Chi_i(\hat R)} \end{vmatrix}}^2 = h \sum_{j}^N n_j^2</math> | |||
--> | |||
==Compact Groups== | |||
The generalization of the orthogonality relations from finite groups to compact groups (which include compact Lie groups such as SO(3)) is basically simple: ''Replace the summation over the group by an integration over the group.''. | |||
Every compact group <math>G</math> has unique bi-invariant [[Haar measure]], so that the volume of the group is 1. Denote this measure by <math>dg</math>. Let <math>( \pi^\alpha )</math> be a complete set of irreducible representations of <math>G</math>, and let <math>\phi^\alpha_{v,w}(g)=\langle v,\pi^\alpha(g)w\rangle </math> be a [[matrix coefficient]] of the representation <math>\pi^\alpha</math>. The orthogonality relations can the be stated in two parts: | |||
1) If <math>\pi^\alpha \ncong \pi^\beta </math> then | |||
:<math> | |||
\int_G \phi^\alpha_{v,w}(g)\phi^\beta_{v',w'}(g)dg=0 | |||
</math> | |||
2) If <math>\{e_i\}</math> is an [[orthonormal basis]] of the representation space <math>\pi^\alpha</math> then | |||
:<math> | |||
d^\alpha\int_G \phi^\alpha_{e_i,e_j}(g)\overline{\phi^\alpha_{e_m,e_n}(g)}dg=\delta_{i,m}\delta_{j,n} | |||
</math> | |||
where <math>d^\alpha</math> is the dimension of <math>\pi^\alpha</math>. These orthogonality relations and the fact that all of the representations have finite dimensions are consequences of the [[Peter-Weyl theorem]] | |||
===An Example SO(3)=== | |||
An example of an r = 3 parameter group is the matrix group SO(3) consisting of all 3 x 3 orthogonal matrices with unit determinant. A possible parametrization of this group is in terms of Euler angles: <math>\mathbf{x} = (\alpha, \beta, \gamma)</math> (see e.g., this article for the explicit form of an element of SO(3) in terms of Euler angles). The bounds are <math>0 \le\alpha, \gamma \le 2\pi</math> and <math>0 \le \beta \le\pi</math>. | |||
Not only the recipe for the computation of the volume element <math> \omega(\mathbf{x})\, dx_1 dx_2\cdots dx_r </math> depends on the chosen parameters, but also the final result, i.e., the analytic form of the weight function (measure) <math>\omega(\mathbf{x})</math>. | |||
For instance, the Euler angle parametrization of SO(3) gives the weight <math>\omega(\alpha,\beta,\gamma) = \sin\! \beta \,,</math> while the n, ψ parametrization gives the weight <math>\omega(\psi,\theta,\phi) = 2(1-\cos\psi)\sin\!\theta\, </math> | |||
with <math>0\le \psi \le \pi, \;\; 0 \le\phi\le 2\pi,\;\; 0 \le \theta \le \pi.</math> | |||
It can be shown that the irreducible matrix representations of compact Lie groups are finite-dimensional and can be chosen to be unitary: | |||
:<math> | |||
\Gamma^{(\lambda)}(R^{-1}) =\Gamma^{(\lambda)}(R)^{-1}=\Gamma^{(\lambda)}(R)^\dagger\quad \hbox{with}\quad \Gamma^{(\lambda)}(R)^\dagger_{mn} \equiv \Gamma^{(\lambda)}(R)^*_{nm}. | |||
</math> | |||
With the shorthand notation | |||
:<math> | |||
\Gamma^{(\lambda)}(\mathbf{x})= \Gamma^{(\lambda)}\Big(R(\mathbf{x})\Big) | |||
</math> | |||
the orthogonality relations take the form | |||
:<math> | |||
\int_{x_1^0}^{x_1^1} \cdots \int_{x_r^0}^{x_r^1}\; \Gamma^{(\lambda)}(\mathbf{x})^*_{nm} \Gamma^{(\mu)}(\mathbf{x})_{n'm'}\; \omega(\mathbf{x}) dx_1\cdots dx_r \; = \delta_{\lambda \mu} \delta_{n n'} \delta_{m m'} \frac{|G|}{l_\lambda}, | |||
</math> | |||
with the volume of the group: | |||
:<math> | |||
|G| = \int_{x_1^0}^{x_1^1} \cdots \int_{x_r^0}^{x_r^1} \omega(\mathbf{x}) dx_1\cdots dx_r . | |||
</math> | |||
As an example we note that the irreducible representations of SO(3) are Wigner D-matrices <math>D^\ell(\alpha \beta \gamma)</math>, which are of dimension <math>2\ell+1 </math>. Since | |||
:<math> | |||
|SO(3)| = \int_{0}^{2\pi} d\alpha \int_{0}^{\pi} \sin\!\beta\, d\beta \int_{0}^{2\pi} d\gamma = 8\pi^2, | |||
</math> | |||
they satisfy | |||
:<math> | |||
\int_{0}^{2\pi} \int_{0}^{\pi} \int_{0}^{2\pi} D^{\ell}(\alpha \beta\gamma)^*_{nm} \; D^{\ell'}(\alpha \beta\gamma)_{n'm'}\; \sin\!\beta\, d\alpha\, d\beta\, d\gamma = \delta_{\ell\ell'}\delta_{nn'}\delta_{mm'} \frac{8\pi^2}{2\ell+1}. | |||
</math> | |||
==Notes== | |||
{{reflist}} | |||
==References == | |||
Any physically or chemically oriented book on group theory mentions the orthogonality relations. The following more advanced books give the proofs: | |||
* M. Hamermesh, ''Group Theory and its Applications to Physical Problems'', Addison-Wesley, Reading (1962). (Reprinted by Dover). | |||
* W. Miller, Jr., ''Symmetry Groups and their Applications'', Academic Press, New York (1972). | |||
* J. F. Cornwell, ''Group Theory in Physics,'' (Three volumes), Volume 1, Academic Press, New York (1997). | |||
[[Category:Representation theory of groups]] |
Revision as of 00:52, 27 February 2013
In mathematics, the Schur orthogonality relations express a central fact about representations of finite groups. They admit a generalization to the case of compact groups in general, and in particular compact Lie groups, such as the rotation group SO(3).
Finite groups
Intrinsic statement
The space of complex-valued class functions of a finite group G has a natural inner product:
where means the complex conjugate of the value of on g. With respect to this inner product, the irreducible characters form an orthonormal basis for the space of class functions, and this yields the orthogonality relation for the rows of the character table:
For the orthogonality relation for columns is as follows:
where the sum is over all of the irreducible characters of G and the symbol denotes the order of the centralizer of .
The orthogonality relations can aid many computations including:
- decomposing an unknown character as a linear combination of irreducible characters;
- constructing the complete character table when only some of the irreducible characters are known;
- finding the orders of the centralizers of representatives of the conjugacy classes of a group; and
- finding the order of the group.
Coordinates statement
Let be a matrix element of an irreducible matrix representation of a finite group of order |G|, i.e., G has |G| elements. Since it can be proven that any matrix representation of any finite group is equivalent to a unitary representation, we assume is unitary:
where is the (finite) dimension of the irreducible representation .[1]
The orthogonality relations, only valid for matrix elements of irreducible representations, are:
Here is the complex conjugate of and the sum is over all elements of G. The Kronecker delta is unity if the matrices are in the same irreducible representation . If and are non-equivalent it is zero. The other two Kronecker delta's state that the row and column indices must be equal ( and ) in order to obtain a non-vanishing result. This theorem is also known as the Great (or Grand) Orthogonality Theorem.
Every group has an identity representation (all group elements mapped onto the real number 1). This is an irreducible representation. The great orthogonality relations immediately imply that
for and any irreducible representation not equal to the identity representation.
Example of the permutation group on 3 objects
The 3! permutations of three objects form a group of order 6, commonly denoted by (symmetric group). This group is isomorphic to the point group , consisting of a threefold rotation axis and three vertical mirror planes. The groups have a 2-dimensional irreducible representation (l = 2). In the case of one usually labels this representation by the Young tableau and in the case of one usually writes . In both cases the representation consists of the following six real matrices, each representing a single group element:[2]
The normalization of the (1,1) element:
In the same manner one can show the normalization of the other matrix elements: (2,2), (1,2), and (2,1). The orthogonality of the (1,1) and (2,2) elements:
Similar relations hold for the orthogonality of the elements (1,1) and (1,2), etc. One verifies easily in the example that all sums of corresponding matrix elements vanish because of the orthogonality of the given irreducible representation to the identity representation.
Direct implications
The trace of a matrix is a sum of diagonal matrix elements,
The collection of traces is the character of a representation. Often one writes for the trace of a matrix in an irreducible representation with character
In this notation we can write several character formulas:
which allows us to check whether or not a representation is irreducible. (The formula means that the lines in any character table have to be orthogonal vectors.) And
which helps us to determine how often the irreducible representation is contained within the reducible representation with character .
For instance, if
and the order of the group is
then the number of times that is contained within the given reducible representation is
See Character theory for more about group characters.
Compact Groups
The generalization of the orthogonality relations from finite groups to compact groups (which include compact Lie groups such as SO(3)) is basically simple: Replace the summation over the group by an integration over the group..
Every compact group has unique bi-invariant Haar measure, so that the volume of the group is 1. Denote this measure by . Let be a complete set of irreducible representations of , and let be a matrix coefficient of the representation . The orthogonality relations can the be stated in two parts:
2) If is an orthonormal basis of the representation space then
where is the dimension of . These orthogonality relations and the fact that all of the representations have finite dimensions are consequences of the Peter-Weyl theorem
An Example SO(3)
An example of an r = 3 parameter group is the matrix group SO(3) consisting of all 3 x 3 orthogonal matrices with unit determinant. A possible parametrization of this group is in terms of Euler angles: (see e.g., this article for the explicit form of an element of SO(3) in terms of Euler angles). The bounds are and .
Not only the recipe for the computation of the volume element depends on the chosen parameters, but also the final result, i.e., the analytic form of the weight function (measure) .
For instance, the Euler angle parametrization of SO(3) gives the weight while the n, ψ parametrization gives the weight with
It can be shown that the irreducible matrix representations of compact Lie groups are finite-dimensional and can be chosen to be unitary:
With the shorthand notation
the orthogonality relations take the form
with the volume of the group:
As an example we note that the irreducible representations of SO(3) are Wigner D-matrices , which are of dimension . Since
they satisfy
Notes
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References
Any physically or chemically oriented book on group theory mentions the orthogonality relations. The following more advanced books give the proofs:
- M. Hamermesh, Group Theory and its Applications to Physical Problems, Addison-Wesley, Reading (1962). (Reprinted by Dover).
- W. Miller, Jr., Symmetry Groups and their Applications, Academic Press, New York (1972).
- J. F. Cornwell, Group Theory in Physics, (Three volumes), Volume 1, Academic Press, New York (1997).
- ↑ The finiteness of follows from the fact that any irreducible representation of a finite group G is contained in the regular representation.
- ↑ This choice is not unique, any orthogonal similarity transformation applied to the matrices gives a valid irreducible representation.