Quantum Channel Learning
Abstract
The problem of an optimal mapping between Hilbert spaces and , based on a series of density matrix mapping measurements , , is formulated as an optimization problem maximizing the total fidelity subject to probability preservation constraints on Kraus operators . For in the form that total fidelity can be represented as a quadratic form with superoperator (either exactly or as an approximation) an iterative algorithm is developed. The work introduces two important generalizations of unitary learning: 1. / states are represented as density matrices. 2. The mapping itself is formulated as a mixed unitary quantum channel (no general quantum channel yet). This marks a crucial advancement from the commonly studied unitary mapping of pure states 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 , in this case a quadratic on fidelity can be constructed by considering mapping, and on a quantum channel, where quadratic on 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.
Cite
@article{arxiv.2407.04406,
title = {Quantum Channel Learning},
author = {Mikhail Gennadievich Belov and Victor Victorovich Dubov and Alexey Vladimirovich Filimonov and Vladislav Gennadievich Malyshkin},
journal= {arXiv preprint arXiv:2407.04406},
year = {2025}
}
Comments
The unitary learning from arXiv:2405.10263 is generalized to density matrices and quantum channels. A Schr\"odinger-like equation is derived for the quantum inverse problem, and a few solutions are presented