Unitary representation

A unitary representation of a group consists of elements that are unitary matrices.

Every representation of a group can be described in terms of unitary matrices. Specifically, matrices of a representation of a group can be expressed as unitary matrices via a common similarity transformation without any loss of generality. The proof is as follows:

Consider a group $G=\{A_1,A_2,\cdots,A_{\vert G\vert}\}$ , where each element is an $n\times n$ matrix. Let’s construct a new matrix $H$ out of the elements of $G$ , where $H=\sum_{\alpha=1}^{\vert G\vert}A_{\alpha}A_{\alpha}^{\dagger}$ .

Question

Proof the matrix identity $(AB)^{\dagger}=B^{\dagger}A^{\dagger}$ .

Answer

$(AB)_{ij}^{\dagger}=(A^*B^*)_{ij}^{T}=(A^*B^*)_{ji}=\sum_kA_{jk}^*B_{ki}^*\\=\sum_k(B^{*T})_{ik}(A^{*T})_{kj}=(B^{\dagger}A^{\dagger})_{ij}$

Using the identity mentioned above,

$H^{\dagger}=\sum_{\alpha=1}^{\vert G\vert}(A_{\alpha}A_{\alpha}^{\dagger})^{\dagger}=\sum_{\alpha=1}^{\vert G\vert}A_{\alpha}A_{\alpha}^{\dagger}=H$

Therefore, $H$ is a Hermitian matrix, which can be diagonalised by a unitary matrix $U$ , i.e. $D=U^{-1}HU=U^{\dagger}HU$ . Using $U^{\dagger}U=UU^{\dagger}=I$ and the above identity again, we have,

$D=U^{\dagger}HU=\sum_{\alpha=1}^{\vert G\vert}U^{\dagger}A_{\alpha}A_{\alpha}^{\dagger}U=\sum_{\alpha=1}^{\vert G\vert}(U^{\dagger}A_{\alpha}U)(U^{\dagger}A_{\alpha}^{\dagger}U)=\sum_{\alpha=1}^{\vert G\vert}(U^{\dagger}A_{\alpha}U)(U^{\dagger}A_{\alpha}U)^{\dagger}$

$D=\sum_{\alpha=1}^{\vert G\vert}\tilde A_{\alpha}\tilde A_{\alpha}^{\dagger}\;\;\;\;\;\;\;\;1$

where $\tilde A_{\alpha}=U^{\dagger} A_{\alpha}U$ .

The diagonal elements of $\tilde A_{\alpha}\tilde A_{\alpha}^{\dagger}$ are $\sum_{j=1}^{n}(\tilde A_{\alpha})_{kj}(\tilde A_{\alpha}^{\dagger})_{jk}=\sum_{j=1}^{n}(\tilde A_{\alpha})_{kj}(\tilde A_{\alpha})^*_{kj}=\sum_{j=1}^{n}\vert(\tilde A_{\alpha})_{kj}\vert^2\geq 0$ and hence, the diagonal elements of $D$ are $D_{kk}=\sum_{\alpha=1}^{\vert G\vert}\sum_{j=1}^n\vert(\tilde A_{\alpha})_{kj}\vert^2$ . Moreover, one of the elements $A_{\alpha}$ of $G$ is the identity matrix, with $\tilde A_{\alpha}=U^{\dagger}A_{\alpha}U=U^{\dagger}IU=U^{\dagger}U=I$ and $\tilde A_{\alpha}\tilde A_{\alpha}^{\dagger}=II=I$ . So, $D_{kk}=\sum_{j=1}^n\vert(\tilde A_{1})_{kj}\vert^2+\sum_{j=1}^n\vert(\tilde A_{2})_{kj}\vert^2+\cdots+1+\cdots+\sum_{j=1}^n\vert(\tilde A_{\vert G\vert})_{kj}\vert^2> 0$ .

Question

Why is $(\tilde A_{\alpha})_{kj}(\tilde A_{\alpha})^*_{kj}=\vert(\tilde A_{\alpha})_{kj}\vert^2$ ?

Answer

$(\tilde A_{\alpha})_{kj}(\tilde A_{\alpha})^*_{kj}=\vert(\tilde A_{\alpha})_{kj}\vert^2$ implies that $(\tilde A_{\alpha})_{kj}$ is a complex number. The modulus of a complex number $(\tilde A_{\alpha})_{kj}=a+ib$ is $\vert(\tilde A_{\alpha})_{kj}\vert=\sqrt{a^2+b^2}\implies \vert(\tilde A_{\alpha})_{kj}\vert^2=a^2+b^2$ . Hence, $(\tilde A_{\alpha})_{kj}(\tilde A_{\alpha})^*_{kj}=(a+ib)(a-ib)=a^2+b^2=\vert(\tilde A_{\alpha})_{kj} \vert^2$ .

Let $D^{1/2}$ and $D^{-1/2}$ be

$D^{\frac{1}{2}}=\begin{pmatrix}D_{11}^{1/2}&0&\cdots&0\\0&D_{22}^{1/2}&\cdots&0\\\vdots&\vdots&\ddots&\vdots\\0&0&\cdots&D_{nn}^{1/2}\end{pmatrix}\;\;\;\;D^{-\frac{1}{2}}=\begin{pmatrix}D_{11}^{-1/2}&0&\cdots&0\\0&D_{22}^{-1/2}&\cdots&0\\\vdots&\vdots&\ddots&\vdots\\0&0&\cdots&D_{nn}^{-1/2}\end{pmatrix}$

where $D^{1/2}_{kk},D_{kk}^{-1/2} > 0$ , $D=D^{1/2}D^{1/2}$ and $D^{1/2}D^{-1/2}=D^{-1/2}D^{1/2}=I$ .

Consider a new set of matrices $B_{\alpha}$ , where $B_{\alpha}=D^{-1/2}\tilde A_{\alpha}D^{1/2}$ . Since $D^{\pm 1/2}$ is diagonal and $D_{kk}^{\pm 1/2}$ is real and positive, we have $(D^{\pm 1/2})^{\dagger}=D^{\pm 1/2}$ . Therefore, $B_{\alpha}^{\dagger}=(D^{-1/2}\tilde A_{\alpha}D^{1/2})^{\dagger}=D^{1/2}\tilde A_{\alpha}^{\dagger}D^{-1/2}$ and

$B_{\alpha}B_{\alpha}^{\dagger}=(D^{-1/2}\tilde A_{\alpha}D^{1/2})(D^{1/2}\tilde A_{\alpha}^{\dagger}D^{-1/2})=D^{-1/2}\tilde A_{\alpha}D\tilde A_{\alpha}^{\dagger}D^{-1/2}$

Substitute eq1 in the above equation and changing the dummy index from $\alpha$ to $\beta$ ,

$B_{\alpha}B_{\alpha}^{\dagger}=D^{-1/2}\sum_{\beta=1}^{\vert G\vert}\tilde A_{\alpha}\tilde A_{\beta}\tilde A_{\beta}^{\dagger}\tilde A_{\alpha}^{\dagger}D^{-1/2}=D^{-1/2}\sum_{\beta=1}^{\vert G\vert}\tilde A_{\alpha}\tilde A_{\beta}(\tilde A_{\alpha}\tilde A_{\beta})^{\dagger}D^{-1/2}\;\;\;\;\;\;\;\;2$

Question

Show that the set $\tilde A_{\alpha}$ is also a representation of $G$ .

Answer

If the set $\tilde A_{\alpha}$ is also a representation of $G$ , its elements must multiply according to the multiplication table of $G=\{A_1,A_2,\cdots,A_{\vert G\vert}\}$ . Since, $\tilde A_{\alpha}=U^{\dagger} A_{\alpha}U$ , we have $\tilde A_{i}\tilde A_{j}=(U^{\dagger} A_{i}U)(U^{\dagger} A_{j}U)=U^{\dagger}A_iA_jU=U^{\dagger}A_kU=\tilde A_k$ . The third equality ensures that the closure property of $G$ is satisfied for the set $A_{\alpha}$ and hence the set $\tilde A_{\alpha}$ . In other words, the elements of $G=\{\tilde A_1,\tilde A_2,\cdots,\tilde A_{\vert G\vert}\}$ multiply according to the multiplication table of $G=\{A_1,A_2,\cdots,A_{\vert G\vert}\}$ .

If $A_j=E$ , then $\tilde A_i \tilde A_j=(U^{\dagger}A_iU)(U^{\dagger}EU)=U^{\dagger}A_iU$ . Since, $\tilde A_{\alpha}=U^{\dagger}A_{\alpha}U$ , the only possibility is that $\tilde A_j=E$ for $\tilde A_i\tilde A_j=U^{\dagger}A_iU$ . Therefore, the set $\tilde A_{\alpha}$ has the identity element.

To show that each $\tilde A_{\alpha}$ has an inverse, we have

$\tilde A_{\alpha}\tilde A_{\alpha}^{-1}=(U^{\dagger} A_{\alpha}U)(U^{\dagger} A_{\alpha}U)^{-1}=(U^{\dagger} A_{\alpha}U)(U^{-1} A_{\alpha}U)^{-1}\\=U^{\dagger}A_{\alpha}UU^{-1}A_{\alpha}^{-1}U=U^{\dagger}A_{\alpha}A_{\alpha}^{-1}U=U^{\dagger}U=I$

Finally, the associativity property of the group is evident, due to the fact that the set $\tilde A_{\alpha}$ consists of matrices, which are associative.

Since the set $\tilde A_{\alpha}$ is also a representation of $G$ , we can express eq2 as:

$B_{\alpha}B_{\alpha}^{\dagger}=D^{-1/2}\sum_{\beta=1}^{\vert G\vert}\tilde A_{\alpha}\tilde A_{\beta}(\tilde A_{\alpha}\tilde A_{\beta})^{\dagger}D^{-1/2}=D^{-1/2}\sum_{\gamma=1}^{\vert G\vert}\tilde A_{\gamma}\tilde A_{\gamma}^{\dagger}D^{-1/2}\\=D^{-1/2}DD^{-1/2}=D^{-1/2}D^{1/2}D^{1/2}D^{-1/2}=I$

Question

Explain why the 2nd equality in the above equation is valid.

Answer

$\sum_{\beta=1}^{\vert G\vert}\tilde A_{\alpha}\tilde A_{\beta}(\tilde A_{\alpha}\tilde A_{\beta})^{\dagger}=\tilde A_{\alpha}(\tilde A_1+\tilde A_2+\cdots+\tilde A_{\vert G\vert})\[\tilde A_{\alpha}(\tilde A_1+\tilde A_2+\cdots+\tilde A_{\vert G\vert})\]^{\dagger}\\=(\tilde A_{\alpha}\tilde A_1+\tilde A_{\alpha}\tilde A_2+\cdots+\tilde A_{\alpha}\tilde A_{\vert G\vert})(\tilde A_{\alpha}\tilde A_1+\tilde A_{\alpha}\tilde A_2+\cdots+\tilde A_{\alpha}\tilde A_{\vert G\vert})^{\dagger}$

According to the rearrangement theorem, each summand in $\tilde A_{\alpha}\tilde A_1+\tilde A_{\alpha}\tilde A_2+\cdots+\tilde A_{\alpha}\tilde A_{\vert G\vert}$ is a unique element of $G$ , which is denoted by $\tilde A_{\gamma}$ . Therefore, the 2nd equality in the equation before the Q&A holds.

Repeating the steps from eq2 for $B_{\alpha}^{\dagger}B_{\alpha}$ , we have $B_{\alpha}^{\dagger}B_{\alpha}=I$ . Therefore, $B_{\alpha}$ is a unitary matrix.

Since $B_{\alpha}=D^{-1/2}\tilde A_{\alpha}D^{1/2}$ , $\tilde A_{\alpha}=U^{\dagger} A_{\alpha}U$ and $D^{-1/2}D^{1/2}=I$ , we have

$B_{\alpha}=D^{-1/2}U^{\dagger} A_{\alpha}UD^{1/2}=D^{-1/2}U^{-1} A_{\alpha}UD^{1/2}=(UD^{1/2})^{-1}A_{\alpha}(UD^{1/2})$

In other words, every element $A_{\alpha}$ of a representation of $G$ can undergo a similarity transformation that results in $B_{\alpha}$ , which is unitary. This is necessary in proving Schur’s first lemma and Schur’s second lemma.

Question

Show that the set $B_{\alpha}$ is also a representation of $G$ .

Answer

If the set $B_{\alpha}$ is also a representation of $G$ , its elements must multiply according to the multiplication table of $G=\{A_1,A_2,\cdots,A_{\vert G\vert}\}$ . Since $B_{\alpha}=P^{-1}A_{\alpha}P$ , we have

$B_iB_j=(P^{-1}A_iP)(P^{-1}A_jP)=P^{-1}A_iA_jP=P^{-1}A_kP=B_k$

The third equality ensures that the closure property of $G$ is satisfied for the set $A_{\alpha}$ and hence the set $B_{\alpha}$ . In other words, the elements of $G=\{B_1,B_2,\cdots,B_{\vert G\vert}\}$ multiply according to the multiplication table of $G=\{A_1,A_2,\cdots,A_{\vert G\vert}\}$ .

Unitary representation

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