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Paper detail

High-dimensional reinforcement learning for optimization and control of ultracold quantum gases

Machine-learning techniques are emerging as a valuable tool in experimental physics, and among them, reinforcement learning offers the potential to control high-dimensional, multistage processes in the presence of fluctuating environments. In this experimental work, we apply reinforcement learning to the preparation of an ultracold quantum gas to realize a consistent and large number of atoms at microkelvin temperatures. This reinforcement learning agent determines an optimal set of thirty control parameters in a dynamically changing environment that is characterized by thirty sensed parameters. By comparing this method to that of training supervised-learning regression models, as well as to human-driven control schemes, we find that both machine learning approaches accurately predict the number of cooled atoms and both result in occasional superhuman control schemes. However, only the reinforcement learning method achieves consistent outcomes, even in the presence of a dynamic environment.

preprint2023arXivOpen access
Nicholas MilsonArina TashchilinaTian OoiAnna CzarneckaZaheen F. AhmadLindsay J. LeBlanc
physics.atom-phcond-mat.quant-gas
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Nicholas MilsonArina TashchilinaTian OoiAnna CzarneckaZaheen F. AhmadLindsay J. LeBlanc

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