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Autori principali: Crosta, T., Rebón, L., Vilariño, F., Matera, J. M., Bilkis, M.
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2404.10726
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author Crosta, T.
Rebón, L.
Vilariño, F.
Matera, J. M.
Bilkis, M.
author_facet Crosta, T.
Rebón, L.
Vilariño, F.
Matera, J. M.
Bilkis, M.
contents During their operation, due to shifts in environmental conditions, devices undergo various forms of detuning from their optimal settings. Typically, this is addressed through control loops, which monitor variables and the device performance, to maintain settings at their optimal values. Quantum devices are particularly challenging since their functionality relies on precisely tuning their parameters. At the same time, the detailed modeling of the environmental behavior is often computationally unaffordable, while a direct measure of the parameters defining the system state is costly and introduces extra noise in the mechanism. In this study, we investigate the application of reinforcement learning techniques to develop a model-free control loop for continuous recalibration of quantum device parameters. Furthermore, we explore the advantages of incorporating minimal environmental noise models. As an example, the application to numerical simulations of a Kennedy receiver-based long-distance quantum communication protocol is presented.
format Preprint
id arxiv_https___arxiv_org_abs_2404_10726
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Automatic re-calibration of quantum devices by reinforcement learning
Crosta, T.
Rebón, L.
Vilariño, F.
Matera, J. M.
Bilkis, M.
Quantum Physics
Machine Learning
During their operation, due to shifts in environmental conditions, devices undergo various forms of detuning from their optimal settings. Typically, this is addressed through control loops, which monitor variables and the device performance, to maintain settings at their optimal values. Quantum devices are particularly challenging since their functionality relies on precisely tuning their parameters. At the same time, the detailed modeling of the environmental behavior is often computationally unaffordable, while a direct measure of the parameters defining the system state is costly and introduces extra noise in the mechanism. In this study, we investigate the application of reinforcement learning techniques to develop a model-free control loop for continuous recalibration of quantum device parameters. Furthermore, we explore the advantages of incorporating minimal environmental noise models. As an example, the application to numerical simulations of a Kennedy receiver-based long-distance quantum communication protocol is presented.
title Automatic re-calibration of quantum devices by reinforcement learning
topic Quantum Physics
Machine Learning
url https://arxiv.org/abs/2404.10726