Related papers: A method to determine which quantum operations can be realized with linear optics with a constructive implementation recipe

A method to determine which quantum operations can be realized with linear optics with a constructive implementation recipe

URL: http://arxiv.org/abs/1901.06178v3
Date: Fri, 29 Sep 2023 13:59:07 GMT
Title: A method to determine which quantum operations can be realized with linear optics with a constructive implementation recipe
Authors: Juan Carlos Garcia-Escartin, Vicent Gimeno, Julio Jos\'e Moyano-Fern\'andez
Abstract summary: We present a method to decide whether a given unitary evolution $U$ for $n$ photons in $m$ modes can be achieved with linear optics. Together with previous results, the method can be used to find a simple optical system which implements any quantum operation within the reach of linear optics.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: The evolution of quantum light through linear optical devices can be described by the scattering matrix $S$ of the system. For linear optical systems with $m$ possible modes, the evolution of $n$ input photons is given by a unitary matrix $U=\varphi_{m,M}(S)$ given by a known homomorphism, $\varphi_{m,M}$, which depends on the size of the resulting Hilbert space of the possible photon states, $M$. We present a method to decide whether a given unitary evolution $U$ for $n$ photons in $m$ modes can be achieved with linear optics or not and the inverse transformation $\varphi_{m,M}^{-1}$ when the transformation can be implemented. Together with previous results, the method can be used to find a simple optical system which implements any quantum operation within the reach of linear optics. The results come from studying the adjoint map bewtween the Lie algebras corresponding to the Lie groups of the relevant unitary matrices.

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