Quantum Channel Learning

Abstract

The problem of an optimal mapping between Hilbert spaces IN and OUT, based on a series of density matrix mapping measurements (l) (l), l=1… M, is formulated as an optimization problem maximizing the total fidelity F=Σl=1M ω(l) F((l),Σs Bs (l) Bs) subject to probability preservation constraints on Kraus operators Bs. For F(,σ) in the form that total fidelity can be represented as a quadratic form with superoperator F=Σs Bs|S| Bs (either exactly or as an approximation) an iterative algorithm is developed. The work introduces two important generalizations of unitary learning: 1. IN/OUT states are represented as density matrices. 2. The mapping itself is formulated as a mixed unitary quantum channel AOUT=Σs |ws|2 Us AIN Us (no general quantum channel yet). This marks a crucial advancement from the commonly studied unitary mapping of pure states φl=U l to a quantum channel, what allows us to distinguish probabilistic mixture of states and their superposition. An application of the approach is demonstrated on unitary learning of density matrix mapping (l)=U (l) U, in this case a quadratic on U fidelity can be constructed by considering (l) (l) mapping, and on a quantum channel, where quadratic on Bs fidelity is an approximation -- a quantum channel is then obtained as a hierarchy of unitary mappings, a mixed unitary channel. The approach can be applied to studying quantum inverse problems, variational quantum algorithms, quantum tomography, and more.

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