Neural networks are a promising tool for characterizing intermediate-scale quantum devices from limited amounts of measurement data. A challenging problem in this area is to learn the action of an unknown quantum process on an ensemble of physically relevant input states. To tackle this problem, we introduce a neural network that emulates the unknown process by constructing an internal representation of the input ensemble and by mimicking the action of the process at the state representation level. After being trained with measurement data from a few pairs of input/output quantum states, the network becomes able to predict the measurement statistics for all inputs in the ensemble of interest. We show that our model exhibits high accuracy in applications to quantum computing, quantum photonics, and quantum many-body physics.
@article{arxiv.2308.08815,
title = {Quantum Process Learning Through Neural Emulation},
author = {Yan Zhu and Ya-Dong Wu and Qiushi Liu and Yuexuan Wang and Giulio Chiribella},
journal= {arXiv preprint arXiv:2308.08815},
year = {2023}
}