Transfer Learning to Model Inertial Confinement Fusion Experiments

Inertial confinement fusion (ICF) experiments are designed using computer simulations that are approximations of reality and therefore must be calibrated to accurately predict experimental observations. In this article, we propose a novel technique for calibrating from simulations to experiments, or...

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Bibliographic Details
Published in:IEEE transactions on plasma science 2020-01, Vol.48 (1), p.61-70
Main Authors: Humbird, K. D., Peterson, J. L., Spears, B. K., McClarren, R. G.
Format: Article
Language:English
Subjects:
Accuracy
Artificial neural networks
Calibration
Computational modeling
Computer simulation
Data models
Experiments
Inertial confinement
Inertial confinement fusion
Laser modes
Machine learning
Neural networks
Physics
Predictive models
Simulation
Task analysis
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Summary:Inertial confinement fusion (ICF) experiments are designed using computer simulations that are approximations of reality and therefore must be calibrated to accurately predict experimental observations. In this article, we propose a novel technique for calibrating from simulations to experiments, or from low fidelity simulations to high fidelity simulations, via "transfer learning" (TL). TL is a commonly used technique in the machine learning community, in which models trained on one task are partially retrained to solve a separate, but related task, for which there is a limited quantity of data. We introduce the idea of hierarchical TL, in which neural networks trained on low fidelity models are calibrated to high fidelity models, then to experimental data. This technique essentially bootstraps the calibration process, enabling the creation of models which predict high fidelity simulations or experiments with minimal computational cost. We apply this technique to a database of ICF simulations and experiments carried out at the Omega laser facility. TL with deep neural networks enables the creation of models that are more predictive of Omega experiments than simulations alone. The calibrated models accurately predict future Omega experiments, and are used to search for new, optimal implosion designs.
ISSN:0093-3813
1939-9375
DOI:10.1109/TPS.2019.2955098