% vim: ft=tex \chapter{Conclusion and Outlook} As seen in \ref{ref:performance} simulation using stabilizers is exponentially faster than simulating with dense state vectors. The graphical representation for stabilizer states is on average more efficiently than the stabilizer tableaux. In particular one can simulate more qbits while only applying Clifford gates. This is considerably useful when working on quantum error correcting strategies as they often include many qbits; the smallest quantum error correcting stabilizer code requires $5$ qbits to encode one logical qbit \cite{nielsen_chuang_2010}. Several layers of data encoding increase the number of required qbits exponentially. Simulating in the stabilizer formalism is uninteresting from a physical point of view as basically no physically interesting simulations can be performed: As shown in \ref{ref:meas_stab} probability amplitudes have to be $0, \frac{1}{2}, 1$; this leaves very few points in time that could be simulated by applying a transfer matrix. Algorithms like the quantum fourier transform also require non-Clifford gates for qbit counts $n \neq 2, 4$. The basic idea of not simulating a state but (after imposing some conditions on the Hilbert space) other objects that describe the state is interesting for physics as often the exponentially large or infinitely large Hilbert spaces cannot be mapped to a classical (super) computer. One key idea to take from the stabilizer formalism is to simulate the Hamiltonian instead of the state: \begin{equation} H := -\sum\limits_{S^{(i)}} S^{(i)} \end{equation} The stabilizer state $\ket{\psi}$ as defined in \ref{ref:stab_states} is the ground state of this Hamiltonian. While trying to extend the stabilizer formalism one inevitably hits the question:\\ \textit{Why is there a constraint on the $R_\phi$ angle? Why is it $\frac{\pi}{2}$?}\\ The answer to this question can be found by taking a look at the Clifford group. Recalling Definition \ref{def:clifford_group} the Clifford group is not defined to be generated by $H, S, CZ$, but by its property of normalizing the multilocal Pauli group. Storing and manipulating the multilocal Pauli group is only so efficient (or possible) because it is the tensor product of Pauli matrices. A general unitary on $n$ qbits would be a $2^{n} \times 2^{n}$ matrix which requires more space than a dense state vector. The Clifford group is a group preserving this tensor product property. %{{{ %When lifting the constraint that $\ket{\varphi}$ is stabilized by the multilocal Pauli %group but using $n$ arbitrary commuting hermitians $\langle h_1, ..., h_n %\rangle$ that are the tensor product of $2\times 2$ hermitians one quickly %realizes that one could apply any single-qbit gate to the $h_i$ and preserve %the tensor product property. Applying the $CX$ gate however will break this %property in general. % %Writing $h_j = \bigotimes\limits_{i=1}^{n} h_{j,i}$, %$A := \left(\bigotimes\limits_{li} I\right)$ this can be seen easily %by transforming a general $h_k$ with $CX_{i,j}$, $i = j+1$: % % %\begin{equation} %\begin{aligned} % CX_{i,j} h_k CX_{i,j}^\dagger &= \left( A\otimes |1\rangle\langle 1| \otimes X \otimes B % + A \otimes |0\rangle\langle 0| \otimes I \otimes B\right)\\ % &h_k\\ % &\left(A \otimes |1\rangle\langle 1| \otimes X \otimes B % + A \otimes |0\rangle\langle 0| \otimes I \otimes B\right) \\ % &= h_{k,A} \otimes h_{k,j,11} |1\rangle\langle 1| \otimes Xh_{k,i}X \otimes h_{k,B}\\ % &+ h_{k,A} \otimes h_{k,j,00}|0\rangle\langle 0| \otimes Ih_{k,i}I \otimes h_{k,B}\\ % &+ h_{k,A} \otimes h_{k,j,01}|0\rangle\langle 1| \otimes Ih_{k,i}X\otimes h_{k,B}\\ % &+ h_{k,A} \otimes h_{k,j,10}|1\rangle\langle 0| \otimes Xh_{k,i}I\otimes h_{k,B}\\ %\end{aligned} %\end{equation} % %Searching for hermitians $h_1, h_2$ that fulfill % %\begin{equation} %CX_{1,2} (h_1 \otimes h_2) CX_{1,2} = h_1' \otimes h_2' %\end{equation} % %and % %\begin{equation} %CX_{2,1} (h_1 \otimes h_2) CX_{2,1} = h_1'' \otimes h_2'' %\end{equation} % %might be a good step to find new classes of states that can be simulated %efficiently using this method. This property has to be fulfilled by all %elements of a group generated by such hermitian matrices. How computations and %measurements would work using this method is not clear at the moment as many %basic properties of the stabilizers are lost. One important property is that the %stabilization: The simulated state is the $+1$ eigenstate of the stabilizers. %This is another property that will have to be fulfilled by the hermitians as it %is a key property used in \ref{ref:dynamics_stabilizer}. To ensure that the %state is well defined one will have to demand that the eigenvalues fulfill %$\lambda_1 = 1$ and $\lambda_2 < 1$. % %One should also note that the sabilizer states do not form a Hilbert (sub)space. %Linear combinations of stabilizer states are (in general) no stabilizer states. %The superposition principle is quite essential to many quantum algorithms and %quantum physics which limits the use of the stabilizer formalism drastically. %}}} The stabilizer formalism as introduced in \ref{ref:stab_states} has since been generalized to normalizers of a finite Abelian group over the Hilbert space \cite{bermejovega_lin_vdnest2015}\cite{bermejovega_vdnest2018}\cite{vandennest2019}\cite{vandennest2018}. This allows to simulate more classes of circuits efficiently on classical computers including the Quantum Fourier Transforms which is often believed to be responsible for exponential speedups. One must note that in the definition of the QFTs as in \cite{vandennest2018} the QFT depends on the Abelian group it acts on. In particular the QFT on the group that decomposes the Hilbert space as seen in this paper ($Z_2^n$) is just the tensor product of the $H$ gates. The QFT as used in \ref{ref:quantum_algorithms} for the phase estimation however normalizes the group $Z_{2^n}$ \cite{vandennest2018}. This yields two interesting results: It is not the tensor product property of the multilocal Pauli group that makes computations efficient but the normalization property of the Clifford group \cite{vandennest2018}. The exponential speedup of quantum computing is often attributed to entanglement, superposition and interference effects \cite{uwaterloo}\cite{21732}\cite{vandennest2018}. Stabilizer states show entanglement, superposition and interference effects; as do computations using general normalizers \cite{vandennest2018}.