2020-01-22 14:35:47 +00:00
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% vim: ft=tex
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\section{The Stabilizer Formalism}
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The stabilizer formalism was originally introduced by Gottesman\cite{gottesman1997}
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for quantum error correction and is a useful tool to encode quantum information
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such that it is protected against noise. The prominent Shor code \cite{shor1995}
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is an example of a stabilizer code (although it was discovered before the stabilizer
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formalism was discovered), as are the 3-qbit bit-flip and phase-flip codes.
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It was only later that Gottesman and Knill discovered that stabilizer states can
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be simulated in polynomial time on a classical machine \cite{gottesman2008}. This
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performance has since been improved to $n\log(n)$ time on average \cite{andersbriegel2005}.
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\subsection{Stabilizers and Stabilizer States}
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2020-01-27 19:01:34 +00:00
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\subsubsection{Local Pauli Group and Multilocal Pauli Group}
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\begin{definition}
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\begin{equation}
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P := \{\pm 1, \pm i\} \cdot \{I, X, Y, Z\}
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\end{equation}
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Is called the Pauli group.
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\end{definition}
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The group property of $P$ can be verified easily. Note that
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the elements of $P$ either commute or anticommute.
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\begin{definition}
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For $n$ qbits
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\begin{equation}
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P_n := \left\{\bigotimes\limits_{i=0}^{n-1} p_i | p_i \in P\right\}
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\end{equation}
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is called the multilocal Pauli group on $n$ qbits.
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\end{definition}
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The group property of $P_n$ follows directly from its definition
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via the tensor product as do the (anti-)commutator relationships.
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2020-01-28 10:11:37 +00:00
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%Further are $p \in P_n$ hermitian and have the eigenvalues $\pm 1$ for
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%$p \neq \pm I$, $+1$ for $p = I$ and $-1$ for $p = -I$.
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2020-01-27 19:01:34 +00:00
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\subsubsection{Stabilizers}
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\begin{definition}
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\label{def:stabilizer}
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An abelian subgroup $S = \{S^{(0)}, ..., S^{(N)}\}$ of $P_n$ is called a set of stabilizers iff
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\begin{enumerate}
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\item{$\forall i,j = 1, ..., N$ $[S^{(i)}, S^{(j)}] = 0$ $S^{(i)}$ and $S^{(j)}$ commute}
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\item{$-I \notin S$}
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\end{enumerate}
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\end{definition}
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\begin{lemma}
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If $S$ is a set of stabilizers, the following statements are follow
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directly
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\begin{enumerate}
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\item{$\pm iI \notin S$}
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\item{$(S^{(i)})^2 = I$ for all $i$}
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\item{$S^{(i)}$ are hermitian for all $i$}
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\end{enumerate}
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\end{lemma}
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\begin{proof}
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\begin{enumerate}
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\item{$(iI)^2 = (-iI)^2 = -I$. Which contradicts the definition of $S$.}
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\item{From the definition of $S$ ($G_n$ respectively) follows that any
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$S^{(i)} \in S$ has the form $\pm i^l (\bigotimes\limits_{j=0}^{n-1} \tilde{p}_j)$ where
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$\tilde{p}_j \in \{X, Y, Z, I\}$ and $l \in \{0, 1\}$. As $(\bigotimes\limits_{j=0}^{n-1} \tilde{p}_j)$
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is hermitian $(S^{(i)})^2$ is either $+I$ or $-I$. As $-I \notin S$ $(S^{(i)})^2 = I$ follows directly.
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}
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\item{Following the argumentation above $(S^{(i)})^2 = -I \Leftrightarrow l=1$
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therefore $(S^{(i)})^2 = -I \Leftrightarrow (S^{(i)})^\dagger \neq (S^{(i)})$.}
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\end{enumerate}
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\end{proof}
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As considering all elements of a group can be unpractical for some calculations
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the generators of a group are introduced. It is usually enough to discuss the generator's
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properties to understand the properties of the group.
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\begin{definition}
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For a finite group $G$ and some $m \in \mathbb{N}$ one denotes the generators
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of G
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$$ \langle g_1, ..., g_m \rangle \equiv \langle g_i \rangle_{i=1,...,m}$$
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where $g_i \in G$, every element in $G$ can be written as a product of the $g_i$
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and $m$ is the smallest integer for which these statements hold.
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\end{definition}
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2020-01-29 10:19:13 +00:00
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In the following discussions $\langle S^{(i)} \rangle_{i=0, ..., n-1}$ will be used as
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2020-01-27 19:01:34 +00:00
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the properties of a set of stabilizers that are used in the discussions can be studied using only its
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generators.
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\subsubsection{Stabilizer States}
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One important basic property of quantum mechanics is that hermitian operators have real eigenvalues
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and eigenspaces associated with these eigenvalues. Finding these eigenvalues and eigenvectors
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is what one calls solving a quantum mechanical system. One of the most fundamental insights of
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quantum mechanics is that operators that commute have a common set of eigenvectors, i.e. they
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can be diagonalized simultaneously. This motivates and justifies the following definition
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\begin{definition}
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For a set of stabilizers $S$ the vector space
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\begin{equation}
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V_S := \{\ket{\psi} | S^{(i)}\ket{\psi} = +1\ket{\psi} \forall S^{(i)} \in S\}
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\end{equation}
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is called the space of stabilizer states associated with $S$ and one says
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$\ket{\psi}$ is stabilized by $S$.
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\end{definition}
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It is clear that it is sufficient to show the stabilization property for the generators of
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$S$, as all the generators forming an element in $S$ can be absorbed into $\ket{\psi}$.
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2020-01-29 10:19:13 +00:00
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The dimension of $V_S$ is not immediately clear. One can however show that
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for a set of stabilizers $\langle S^{(i)} \rangle_{i=1, ..., n-m}$ the dimension
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$dim V_S = 2^m$ \cite[Chapter 10.5]{nielsen_chuang_2010}. This yields the following important
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result:
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\begin{theorem}
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\label{thm:unique_s_state}
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For a $n$ qbit system and a set $S = \langle S^{(i)} \rangle_{i=1, ..., n}$ the stabilizer
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space $V_S$ has $dim V_S = 1$, in particular there exists an up to a trivial phase unique
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state $\ket{\psi}$ that is stabilized by $S$.
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Without proof.
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\end{theorem}
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In the following discussions for $n$ qbits a set $S = \langle S^{(i)} \rangle_{i=1,...,n}$
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of $n$ independent stabilizers will be assumed.
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\subsubsection{Dynamics of Stabilizer States}
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Consider a $n$ qbit state $\ket{\psi}$ that is the $+1$ eigenstate of $S = \langle S^{(i)} \rangle_{i=1,...,n}$
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and a unitary transformation $U$ that describes the dynamics of the system, i.e.
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\begin{equation}
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\ket{\psi'} = U \ket{\psi}
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\end{equation}
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It is clear that in general $\ket{\psi'}$ will not be stabilized by $S$ anymore. There are
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however some statements that can still be made:
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\begin{equation}
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\begin{aligned}
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\ket{\psi'} &= U \ket{\psi} \\
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&= U S^{(i)} \ket{\psi} \\
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&= U S^{(i)} U^\dagger U\ket{\psi} \\
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&= U S^{(i)} U^\dagger \ket{\psi'} \\
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&= S^{\prime(i)} \ket{\psi'} \\
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\end{aligned}
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\end{equation}
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Note that in \ref{def:stabilizer} it has been demanded that stabilizers are a
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subgroup of the multilocal Pauli operators. This does not hold true for an arbitrary
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$U$ but there exists a group for which $S'$ will be a set of stabilizers.
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\begin{definition}
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For $n$ qbits
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\begin{equation}
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C_n := \left\{U \in SU(n) | UpU^\dagger \in P_n \forall p \in P_n\right\}
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\end{equation}
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is called the Clifford group. $C_1 =: C_L$ is called the local Clifford group.
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\end{definition}
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\begin{theorem}
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\label{thm:clifford_group_approx}
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\begin{enumerate}
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\item{$C_L$ can be generated using only $H$ and $S$.}
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\item{$C_L$ can be generated from $\sqrt{iZ} = \exp(\frac{i\pi}{4}) S^\dagger$
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and $\sqrt{-iX} = \frac{1}{\sqrt{2}} \left(\begin{array}{cc} 1 & -i \\ -i & 1 \end{array}\right)$.
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Also $C_L$ is generated by a product of at most $5$ matrices $\sqrt{iZ}$, $\sqrt{-iX}$.
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}
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\item{$C_n$ can be generated using $C_L$ and $CZ$ or $CX$.}
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\end{enumerate}
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\end{theorem}
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\begin{proof}
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\begin{enumerate}
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\item{See \cite[Theorem 10.6]{nielsen_chuang_2010}}
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\item{
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One can easily verify that $\sqrt{iZ} \in C_L$ and $\sqrt{-iX} \in C_L$.
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Further one can show easily that (up to a global phase)
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$H = \sqrt{iZ} \sqrt{-iX}^3 \sqrt{iZ}$ and $S = \sqrt{iZ}^3$.
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The length of the product can be seen when explicitly calculating
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$C_L$.
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}
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\item{See \cite[Theorem 10.6]{nielsen_chuang_2010}}
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\end{enumerate}
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\end{proof}
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This is quite an important result: As under a transformation $U \in C_n$ $S'$ is a set of
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$n$ independent stabilizers and $\ket{\psi'}$ is stabilized by $S'$ one can consider
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the dynamics of the stabilizers instead of the actual state. This is considerably more
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efficient as only $n$ stabilizers have to be modified, each being just the tensor
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product of $n$ Pauli matrices. This has led to the simulation using stabilizer tableaux
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\cite{gottesman_aaronson2008}.
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Interestingly also measurements are dynamics covered by the stabilizers.
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2020-01-29 16:13:16 +00:00
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When an observable $g_a \in \{\pm X_a, \pm Y_a \pm Z_a\}$ acting on qbit $a$ is measured
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one has to consider the projector
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\begin{equation}
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P_{g_a,s} = \frac{I + (-1)^s g_a}{2}
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\end{equation}
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If now $g_a$ commutes with all $S^{(i)}$ a result of $s=0$ is measured with probability $1$
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and the stabilizers are left unchanged:
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\begin{equation}
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\begin{aligned}
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\ket{\psi'} &= \frac{I + g_a}{2}\ket{\psi} \\
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&= \frac{I + g_a}{2}S^{(i)} \ket{\psi} \\
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&= S^{(i)} \frac{I + g_a}{2}\ket{\psi} \\
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&= S^{(i)}\ket{\psi'} \\
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\end{aligned}
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\end{equation}
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As the state that is stabilized by $S$ is unique $\ket{\psi'} = \ket{\psi}$.
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If $g_a$ does not commute with all stabilizers the following lemma gives
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the result of the measurement.
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\begin{lemma}
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\label{lemma:stab_measurement}
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Let $J := \{ S^{(i)} | [g_a, S^{(i)}] \neq 0\} \neq \{\}$. When measuring
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$\frac{I + (-1)^s g_a}{2} $
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$1$ and $0$ are obtained with probability $\frac{1}{2}$ and after choosing
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a $j \in J$ the new state $\ket{\psi'}$ is stabilized by
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\begin{equation}
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\langle \{(-1)^s g_a\} \cup \{S^{(i)} S^{(j)} | S^{(i)} \in J \setminus \{S^{(j)}\} \} \cup J^c\rangle
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\end{equation}
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\end{lemma}
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\begin{proof}
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As $g_a$ is a Pauli operator and $S^{(i)} \in J$ are multi-local Pauli operators,
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$S^{(i)}$ and $g_a$ anticommute. Choose a $S^{(j)} \in J$. Then
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\begin{equation}
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\begin{aligned}
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P(s=+1) &= \hbox{Tr}\left(\frac{I + g_a}{2}\ket{\psi}\bra{\psi}\right) \\
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&= \hbox{Tr}\left(\frac{I + g_a}{2}S^{(j)} \ket{\psi}\bra{\psi}\right)\\
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&= \hbox{Tr}\left(S^{(j)}\frac{I - g_a}{2}\ket{\psi}\bra{\psi}\right)\\
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&= \hbox{Tr}\left(\frac{I - g_a}{2}\ket{\psi}\bra{\psi}S^{(j)}\right)\\
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&= \hbox{Tr}\left(\frac{I - g_a}{2}\ket{\psi}\bra{\psi}\right)\\
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&= P(s=-1)
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\end{aligned}
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\notag
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\end{equation}
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With $P(s=+1) + P(s=-1) = 1$ follows $P(s=+1) = \frac{1}{2} = P(s=-1)$.
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Further for $S^{(i)},S^{(j)} \in J$
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\begin{equation}
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\begin{aligned}
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\frac{I + (-1)^sg_a}{2}\ket{\psi} &= \frac{I + (-1)^sg_a}{2}S^{(j)}S^{(i)} \ket{\psi} \\
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&= S^{(j)}\frac{I + (-1)^{s + 1}g_a}{2}S^{(i)} \ket{\psi} \\
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&= S^{(j)}S^{(i)}\frac{I + (-1)^{s + 2}g_a}{2}\ket{\psi} \\
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&= S^{(j)}S^{(i)}\frac{I + (-1)^sg_a}{2}\ket{\psi}
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\end{aligned}
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\notag
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\end{equation}
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the state after measurement is stabilized by $S^{(j)}S^{(i)}$ $i,j \in J$, and by
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$S^{(i)} \in J^c$. $(-1)^sg_a$ trivially stabilizes $\ket{\psi'}$.
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\end{proof}
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\subsection{The VOP-free Graph States}
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\subsubsection{VOP-free Graph States}
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This section will discuss the vertex operator(VOP)-free graph states. Why they are called
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vertex operator-free will be clear in the following section about graph states.
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\begin{definition}
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\label{def:graph}
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The tuple $(V, E)$ is called a graph iff $V$ is a set of vertices with $|V| = n \in \mathbb{N}$.
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In the following $V = \{0, ..., n-1\}$ will be used.
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$E$ is the set of edges $E = \left\{\{i, j\} | i,i \in V, i \neq j\right\}$.
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For a vertex $i$ $n_i := \left\{j \in V | \{i, j\} \in E\right\}$ is called the neighbourhood
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of $i$.
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\end{definition}
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This definition of a graph is way less general than the definition of a mathematical graph.
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Using this definition will however allow to avoid an extensive list of constraints on the
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mathematical graph that are implied in this definition.
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\begin{definition}
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For a graph $G = (V = \{0, ..., n-1\}, E)$ the associated stabilizers are
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\begin{equation}
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K_G^{(i)} := X_i \prod\limits_{\{i,j\} \in E} Z_i
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\end{equation}
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for all $i \in V$. The vertex operator free graph state $\ket{\bar{G}}$ is the state stabilized by
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$\langle K_G^{(i)} \rangle_{i = 0, ..., n-1}$.
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\end{definition}
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2020-02-01 09:27:51 +00:00
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It is clear that the $K_G^{(i)}$ multilocal Pauli operators. That they commute
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follows from the fact that $\{i,j\} \in E \Leftrightarrow \{j,i\} \in E$ so for two
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operators $K_G^{(i)}$ and $K_G^{(j)}$ either $\{i, j\} \notin E$ so they commute trivially
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if $\{i,j\} \in E$ $X_i$, $Z_j$ and $X_j$, $Z_i$ anticommute which yields that the
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operators commute.
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This definition of a graph state might not seem to be quite straight forward
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but recalling theorem \ref{thm:unique_s_state} it is clear that $\ket{\bar{G}}$
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is unique. The following lemma will provide a way to construct this state
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from the graph.
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\begin{lemma}
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For a graph $G = (V, E)$ the associated state $\ket{\bar{G}}$ is
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constructed using
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\begin{equation}
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\begin{aligned}
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\ket{\bar{G}} &= \left(\prod\limits_{\{i,j\} \in E} CZ_{i,j}\right)\left(\prod\limits_{i \in V} H_i\right) \ket{0} \\
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&= \left(\prod\limits_{\{i,j\} \in E} CZ_{i,j}\right) \ket{+} \\
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\end{aligned}
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\end{equation}
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\end{lemma}
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\begin{proof}
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Let $\ket{+} := \left(\prod\limits_{l \in V} H_l\right) \ket{0}$ as before. Note that for any $X_i$ $X_i \ket{+} = +1 \ket{+}$.
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Set $\ket{\tilde{G}} := \left(\prod\limits_{\{i,j\} \in E} CZ_{i,j} \right)\ket{+}$.
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\begin{equation}
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\begin{aligned}
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K_G^{(i)} \ket{\tilde{G}} & = X_i \left(\prod\limits_{\{i,j\} \in E} Z_j\right)\left(\prod\limits_{\{l,j\} \in E} CZ_{l,j} \right) \ket{+} \\
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& = \left(\prod\limits_{\{i,j\} \in E} Z_j\right)X_i\prod\limits_{\{l,j\} \in E}\left( \ket{0}\bra{0}_j \otimes I_l + \ket{1}\bra{1}_j \otimes Z_l\right) \ket{+} \\
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& = \left(\prod\limits_{\{i,j\} \in E} Z_j\right)\prod\limits_{\{l,j\} \in E}\left( \ket{0}\bra{0}_j \otimes I_l + (-1)^{\delta_{i,l}}\ket{1}\bra{1}_j \otimes Z_l\right) X_i \ket{+} \\
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& = \prod\limits_{\{l,j\} \in E}\left( \ket{0}\bra{0}_j \otimes I_l + (-1)^{2\delta_{i,l}}\ket{1}\bra{1}_j \otimes Z_l\right) \ket{+} \\
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& = \prod\limits_{\{l,j\} \in E}\left( \ket{0}\bra{0}_j \otimes I_l + \ket{1}\bra{1}_j \otimes Z_l\right) \ket{+} \\
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& = +1 \ket{\tilde{G}}
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\end{aligned}
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\end{equation}
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as $X, Z$ anticommute and $Z\ket{1} = -1\ket{1}$.
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\end{proof}
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\subsubsection{Dynamics of the VOP-free Graph States}
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This representation gives an immediate result to how the stabilizers $\langle K_G^{(i)} \rangle_i$ change
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under the $CZ$ gate: When applying $CZ_{i,j}$ on $G = (V, E)$ the edge $\{i,j\}$ is toggled,
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resulting in a multiplication of $Z_j$ to $K_G^{(i)}$ and $Z_i$ to $K_G^{(j)}$. Toggling edges
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is done by using the symmetric set difference:
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\begin{definition}
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For to finite sets $A,B$ the symmetric set difference $\Delta$ is
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defined as
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\begin{equation}
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A \Delta B = (A \cup B) \setminus (A \cap B)
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\end{equation}
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\end{definition}
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Toggling an edge $\{i, j\}$ updates $E' = E \Delta \left\{\{i,j\}\right\}$.
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Another transformation on the VOP-free graph states is for a vertex $a \in V$
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|
\begin{equation}
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M_a := \sqrt{-iX_a} \prod\limits_{j\in n_a} \sqrt{iZ_j}
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\end{equation}
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This transformation toggles the neighbourhood of $a$ which is an operation
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that will be used later.
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\begin{lemma}
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When applying $M_a$ to a state $\ket{\bar{G}}$ the new state
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$\ket{\bar{G}'}$ is again a VOP-free graph state and the
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graph is updated according to
|
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|
\begin{equation}
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|
|
\begin{aligned}
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|
n_a' &= n_a \\
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n_j' &= n_j, \hbox{ if } j \notin n_a\\
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|
n_j' &= n_j \Delta n_a, \hbox{ if } j \in n_a
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|
\end{aligned}
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|
\end{equation}
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|
\end{lemma}
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|
|
\begin{proof}
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|
$\ket{\bar{G}'}$ is stabilized by $\langle M_a K_G^{(i)} M_a^\dagger \rangle_i$, so it is sufficient
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|
to study how the $ K_G^{(i)}$ change under $M_a$.
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At first note that $[K_G^{(a)}, M_a] = 0$ and $\forall i\in V\setminus n_a$ $[K_G^{(i)}, M_a] = 0$,
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so the first two equations follow trivially. For $j \in n_a$ set
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|
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|
\begin{equation}
|
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|
|
\begin{aligned}
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|
S^{(j)} &= M_a K_G^{(j)} M_a^\dagger \\
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|
&= \sqrt{-iX_a} \left(\prod\limits_{l \in n_a \setminus \{j\}} \sqrt{iZ_l}\right)
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|
\sqrt{iZ_j} K_G^{(j)} \sqrt{iZ_j}^\dagger
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|
\left(\prod\limits_{l \in n_a \setminus \{j\}} \sqrt{iZ_l}^\dagger\right)
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|
\sqrt{-iX_a}^\dagger \\
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&= \sqrt{-iX_a} \left(\prod\limits_{l \in n_a \setminus \{j\}} \sqrt{iZ_l}\right)\sqrt{iZ_j}
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|
|
X_j \left(\prod\limits_{m \in n_j \setminus \{a\}} Z_m\right) Z_a
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|
|
\sqrt{iZ_j}^\dagger
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|
|
\left(\prod\limits_{l \in n_a \setminus \{j\}} \sqrt{iZ_l}^\dagger\right)
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|
|
\sqrt{-iX_a}^\dagger \\
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|
|
&= \sqrt{iZ_j} X_j\sqrt{iZ_j}^\dagger\left(\prod\limits_{m \in n_j \setminus \{a\}} Z_m\right)
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|
|
\sqrt{-iX_a} Z_a \sqrt{-iX_a}^\dagger \\
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|
|
&= (-1)^2 Y_j Y_a \left(\prod\limits_{m \in n_j \setminus \{a\}} Z_m\right)\\
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|
|
&= (-1)i^2 Z_j X_a X_j Z_a \left(\prod\limits_{m \in n_j \setminus \{a\}} Z_m\right)
|
|
|
|
\end{aligned}
|
|
|
|
\end{equation}
|
|
|
|
|
|
|
|
One can now construct a new set of $K_{G'}^{(i)}$ s.t. $M_a \ket{\bar{G}}$ is the $+1$ eigenvalue
|
|
|
|
of the new $K_{G'}^{(i)}$. It is clear that $\forall j \notin n_a$ $K_{G'}^{(j)} = K_G^{(j)}$.
|
|
|
|
To construct the $K_{G'}^{(i)}$ let for some $j \in n_a$ $n_a = \{j\} \cup I$ and $n_j = \{a\} \cup J$.
|
|
|
|
Then
|
|
|
|
|
|
|
|
\begin{equation}
|
|
|
|
\begin{aligned}
|
|
|
|
S^{(j)} &= Z_j X_a X_j Z_a \prod\limits_{l \in J} Z_l\\
|
|
|
|
&= Z_j X_a X_j Z_a \left(\prod\limits_{l \in J} Z_l\right)
|
|
|
|
\left(\prod\limits_{l \in I}Z_l\right)
|
|
|
|
\left(\prod\limits_{l \in I}Z_l\right) \\
|
|
|
|
&= Z_j X_a X_j Z_a \left(\prod\limits_{l \in ((I\cup J) \setminus (I\cap J))} Z_L\right)
|
|
|
|
\left(\prod\limits_{l \in I}Z_l\right) \\
|
|
|
|
&= K_{G'}^{(a)} K_{G'}^{(j)} \\
|
|
|
|
&= K_{G}^{(a)} K_{G'}^{(j)}
|
|
|
|
\end{aligned}
|
|
|
|
\end{equation}
|
|
|
|
|
|
|
|
Using this ine can show that $\ket{\bar{G}'}$ is a $+1$ eigenstate of $K_{G'}^{(j)}$:
|
|
|
|
|
|
|
|
\begin{equation}
|
|
|
|
\ket{\bar{G}'} = S^{(j)}\ket{\bar{G}'} = K_{G}^{(a)} K_{G'}^{(j)}\ket{\bar{G}'}
|
|
|
|
= K_{G'}^{(j)}K_{G}^{(a)}\ket{\bar{G}'} = K_{G'}^{(j)}\ket{\bar{G}'}
|
|
|
|
\end{equation}
|
|
|
|
|
|
|
|
Because $\{K_G^{(i)} | i \notin n_a\} \cup \{S^{(i)} | i\in n_a\}$ and
|
|
|
|
$\{K_G^{(i)} | i \notin n_a\} \cup \{K_{G'}^{(i)} | i\in n_a \}$ are both $n$ commuting
|
|
|
|
multi-local Pauli operators where the $S^{(i)}$ can be generated from the $K_{G'}^{(i)}$
|
|
|
|
and $\ket{\bar{G}'}$ is a $+1$ eigenstate of $K_{G'}^{(j)}$
|
|
|
|
$\langle\{K_G^{(i)} | i \notin n_a\} \cup \{K_{G'}^{(i)} | i\in n_a \}\rangle$
|
|
|
|
are the stabilizers of $\ket{\bar{G}'}$ and the associated graph is changed as given
|
|
|
|
in the third equation.
|
|
|
|
\end{proof}
|
|
|
|
|
|
|
|
\subsection{Graph States}
|
|
|
|
|
|
|
|
The definition of a VOP-free graph state above raises an obvious question:
|
|
|
|
Can any stabilizer state be described using just a graph?
|
|
|
|
The answer is quite simple: No. The most simple cases are the single qbit
|
|
|
|
stated $\ket{0},\ket{1}$ and $\ket{+_Y}, \ket{-_Y}$. But there is a simple extension
|
|
|
|
to the VOP-free graph states that allows the representation of an arbitrary
|
|
|
|
stabilizer state. The proof that indeed any state can be represented is
|
|
|
|
just constructive. As seen in theorem \ref{thm:clifford_group_approx} any $c \in C_n$
|
|
|
|
can be constructed from $CZ$ and $C_L$ and in the following discussion it will become
|
|
|
|
clear that both $C_L$ and $CZ$ can be applied to a general graph state.
|
|
|
|
|
2020-02-10 19:11:13 +00:00
|
|
|
\subsubsection{Graph States and Vertex Operators}
|
|
|
|
|
|
|
|
\begin{definition}
|
|
|
|
\label{def:g_state}
|
|
|
|
A tuple $(V, E, O)$ is called the graphical representation of a stabilizer state
|
|
|
|
if $(V, E)$ is a graph as in Definition \ref{def:graph} and $O = \{o_1, ..., o_n\}$ where $o_i \in C_L$.
|
|
|
|
|
|
|
|
The state $\ket{G}$ is defined by the eigenvalue relation
|
|
|
|
|
|
|
|
\begin{equation}
|
|
|
|
+1 \ket{G} = \left(\prod\limits_{j=1}^no_j\right) K_G^{(i)} \left(\prod\limits_{j=1}^no_j\right)^\dagger \ket{G}
|
|
|
|
\end{equation}
|
|
|
|
|
|
|
|
$o_i$ are called the vertex operators of $\ket{G}$.
|
|
|
|
\end{definition}
|
|
|
|
|
|
|
|
Recalling the dynamics of stabilizer states the following relation follows immediately:
|
|
|
|
|
|
|
|
\begin{equation}
|
|
|
|
\ket{G} = \left(\prod\limits_{j=1}^no_j\right) \ket{\bar{G}}
|
|
|
|
\end{equation}
|
|
|
|
|
|
|
|
The great advantage of this representation of a stabilizer state is its space requirement:
|
|
|
|
Instead of storing $n^2$ $P_1$ matrices only some vertices (which often are implicit),
|
|
|
|
the edges and some vertex operators ($n$ matrices) have to be stored. The following theorem
|
|
|
|
will improve this even further: instead of $n$ matrices it is enough to store $n$ integers
|
|
|
|
representing the vertex operators is enough:
|
|
|
|
|
|
|
|
\begin{theorem}
|
|
|
|
$C_L$ has $24$ degrees of freedom.
|
|
|
|
\end{theorem}
|
|
|
|
\begin{proof}
|
|
|
|
It is clear that $\forall a \in C_L$ a is a group isomorphism $P_1 \circlearrowleft$: $apa^\dagger a p' a^\dagger = a pp'a^\dagger$.
|
|
|
|
Therefore $a$ will preserve the (anti-)commutator relations of $P$.
|
|
|
|
Further note that $Y = iXZ$, so one has to consider the anti-commutator relations
|
|
|
|
of $X,Z$ only.
|
|
|
|
|
|
|
|
As the transformations are unitary they preserve eigenvalues, so $X$ can be mapped
|
|
|
|
to $\pm X, \pm Y, \pm Z$ which gives $6$ degrees of freedom, the image of $Z$ has to
|
|
|
|
anti-commute with the image of $X$ so $Z$ has four possible images under the transformation.
|
|
|
|
This gives another $4$ degrees of freedom and a total of $24$.
|
|
|
|
\end{proof}
|
|
|
|
|
|
|
|
From now on $C_L = \langle H, S \rangle$ (disregarding a global phase) will be used,
|
|
|
|
one can show (by construction) that $H, S$ generate a possible choice of $C_L$, as is
|
|
|
|
$C_L = \langle \sqrt{-iX}, \sqrt{-iZ}\rangle$ which will be used in one specific operation on graph states.
|
|
|
|
|
|
|
|
$$ S = \left(\begin{array}{cc} 1 & 0 \\ 0 & i \end{array}\right)$$
|
|
|
|
$$ \sqrt{-iX} = \frac{1}{\sqrt{2}}\left(\begin{array}{cc} 1 & i \\ i & 1 \end{array}\right)$$
|
|
|
|
$$ \sqrt{-iZ} = \exp(-i\frac{\pi}{4})\left(\begin{array}{cc} 1 & 0 \\ 0 & -i \end{array}\right)$$
|
|
|
|
|
2020-02-01 09:27:51 +00:00
|
|
|
|