Neural network quantum state tomography in a two-qubit experiment
- URL: http://arxiv.org/abs/2007.16185v3
- Date: Fri, 9 Oct 2020 14:53:24 GMT
- Title: Neural network quantum state tomography in a two-qubit experiment
- Authors: Marcel Neugebauer, Laurin Fischer, Alexander J\"ager, Stefanie
Czischek, Selim Jochim, Matthias Weidem\"uller, Martin G\"arttner
- Abstract summary: Machine learning inspired variational methods provide a promising route towards scalable state characterization for quantum simulators.
We benchmark and compare several such approaches by applying them to measured data from an experiment producing two-qubit entangled states.
We find that in the presence of experimental imperfections and noise, confining the variational manifold to physical states greatly improves the quality of the reconstructed states.
- Score: 52.77024349608834
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: We study the performance of efficient quantum state tomography methods based
on neural network quantum states using measured data from a two-photon
experiment. Machine learning inspired variational methods provide a promising
route towards scalable state characterization for quantum simulators. While the
power of these methods has been demonstrated on synthetic data, applications to
real experimental data remain scarce. We benchmark and compare several such
approaches by applying them to measured data from an experiment producing
two-qubit entangled states. We find that in the presence of experimental
imperfections and noise, confining the variational manifold to physical states,
i.e. to positive semi-definite density matrices, greatly improves the quality
of the reconstructed states but renders the learning procedure more demanding.
Including additional, possibly unjustified, constraints, such as assuming pure
states, facilitates learning, but also biases the estimator.
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