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Application of interpretable machine learning for cross-diagnostic inference on the ST40 spherical tokamak

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arxiv 2407.18741 v1 pith:Q7SUYOF6 submitted 2024-07-26 physics.plasm-ph physics.app-phphysics.ins-det

Application of interpretable machine learning for cross-diagnostic inference on the ST40 spherical tokamak

classification physics.plasm-ph physics.app-phphysics.ins-det
keywords learningmachinemodelsblack-boxmodelpredictionsapplicationapproach
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Machine learning models are exceptionally effective in capturing complex non-linear relationships of high-dimensional datasets and making accurate predictions. However, their intrinsic ``black-box'' nature makes it difficult to interpret them or guarantee ``safe behavior'' when deployed in high-risk applications such as feedback control, healthcare and finance. This drawback acts as a significant barrier to their wider application across many scientific and industrial domains where the interpretability of the model predictions is as important as accuracy. Leveraging the latest developments in interpretable machine learning, we develop a method to parameterise ``black-box'' models, effectively transforming them into ``grey-box'' models. We apply this approach to plasma diagnostics by creating a parameterised synthetic Soft X-Ray imaging $-$ Thomson Scattering diagnostic, which predicts high temporal resolution electron temperature and density profiles from the measured soft X-ray emission. The ``grey-box'' model predictions are benchmarked against the trained ``black-box'' models as well as a diverse range of plasma conditions. Our model-agnostic approach can be applied to various machine learning architectures, enabling direct comparisons of model interpretations.

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