Parameter estimation by learning quantum correlations in continuous photon-counting data using neural networks

Authors :: Rinaldi, Enrico
Lastre, Manuel González
Herreros, Sergio García
Ahmed, Shahnawaz
Khanahmadi, Maryam
Nori, Franco
Muñoz, Carlos Sánchez
Publication Year :: 2023
Abstract: We present an inference method utilizing artificial neural networks for parameter estimation of a quantum probe monitored through a single continuous measurement. Unlike existing approaches focusing on the diffusive signals generated by continuous weak measurements, our method harnesses quantum correlations in discrete photon-counting data characterized by quantum jumps. We benchmark the precision of this method against Bayesian inference, which is optimal in the sense of information retrieval. By using numerical experiments on a two-level quantum system, we demonstrate that our approach can achieve a similar optimal performance as Bayesian inference, while drastically reducing computational costs. Additionally, the method exhibits robustness against the presence of imperfections in both measurement and training data. This approach offers a promising and computationally efficient tool for quantum parameter estimation with photon-counting data, relevant for applications such as quantum sensing or quantum imaging, as well as robust calibration tasks in laboratory-based settings.<br />Comment: 15 pages, 8 figures, code is available at http://github.com/CarlosSMWolff/ParamEst-NN

Subjects :: Quantum Physics
Physics - Data Analysis, Statistics and Probability

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