Magnetic control of tokamak plasmas through deep reinforcement learning

Degrave, Jonas; Felici, F.; Buchli, Jonas; Neunert, Michael; Tracey, Brendan; Carpanese, F.; Ewalds, Timo; Hafner, Roland; Abdolmaleki, Abbas; Casas, Diego de Las; Donner, Craig; Fritz, Leslie; Galperti, C.; Huber, Andrea; Keeling, James; Tsimpoukelli, Maria; Kay, Jackie; Merle, A.; Moret, J.M.; Noury, Seb; Pesamosca, Federico; Pfau, David; Sauter, O.; Sommariva, C.; Coda, S.; Duval, B.P.; Fasoli, A.; Kohli, Pushmeet; Kavukcuoglu, Koray; Hassabis, Demis; Riedmiller, Martin

doi:10.1038/s41586-021-04301-9

articleNatureFeb 16, 2022HYBRID OA

Magnetic control of tokamak plasmas through deep reinforcement learning

JDJonas Degrave FFF. Felici JBJonas Buchli MNMichael Neunert BTBrendan Tracey

Google DeepMind (United Kingdom) · École Polytechnique Fédérale de Lausanne

PubMed

Indexed incrossrefpubmed

Abstract

Abstract Nuclear fusion using magnetic confinement, in particular in the tokamak configuration, is a promising path towards sustainable energy. A core challenge is to shape and maintain a high-temperature plasma within the tokamak vessel. This requires high-dimensional, high-frequency, closed-loop control using magnetic actuator coils, further complicated by the diverse requirements across a wide range of plasma configurations. In this work, we introduce a previously undescribed architecture for tokamak magnetic controller design that autonomously learns to command the full set of control coils. This architecture meets control objectives specified at a high level, at the same time satisfying physical and…

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692

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FWCI: 80.38
Percentile: 100%
References: 51

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Authors

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Topics & keywords

Topics

Magnetic confinement fusion research100%

Keywords

Tokamak
Computer science
Reinforcement learning
Plasma
Controller (irrigation)
Flexibility (engineering)
Spherical tokamak
Fusion power

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