Enhanced reproducibility of L-mode plasma discharges via physics-model-based q-profile feedback control in DIII-D

Enhanced reproducibility of L-mode plasma discharges via physics-model-based q-profile feedback control in DIII-D

Recent experiments on DIII-D demonstrate the potential of physics-model-based q-profile control to improve reproducibility of plasma discharges. A combined feedforward  +  feedback control scheme is employed to optimize the current ramp-up phase by consistently achieving target q profiles (Target 1:...

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Bibliographic Details
Published in:Nuclear fusion 2017-11, Vol.57 (11), p.116026
Main Authors: Schuster, E., Wehner, W.P., Barton, J.E., Boyer, M.D., Luce, T.C., Ferron, J.R., Holcomb, C.T., Walker, M.L., Humphreys, D.A., Solomon, W.M., Penaflor, B.G., Johnson, R.D.
Format: Article
Language:eng
Subjects:
70 PLASMA PHYSICS AND FUSION TECHNOLOGY
current profile control
enhanced discharge reproducibility
model-based optimization
plasma control
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Summary:Recent experiments on DIII-D demonstrate the potential of physics-model-based q-profile control to improve reproducibility of plasma discharges. A combined feedforward  +  feedback control scheme is employed to optimize the current ramp-up phase by consistently achieving target q profiles (Target 1: qmin=1.3,q95=4.4; Target 2: qmin=1.65,q95=5.0; Target 3: qmin=2.1,q95=6.2) at prescribed times during the plasma formation phase (Target 1: t=1.5 s; Target 2: t=1.3 s; Target 3: t=1.0 s). At the core of the control scheme is a nonlinear, first-principles-driven, physics-based, control-oriented model of the plasma dynamics valid for low confinement (L-mode) scenarios. To prevent undesired L-H transitions, a constraint on the maximum allowable total auxiliary power is imposed in addition to the maximum powers for the individual heating and current-drive sources. Experimental results are presented to demonstrate the effectiveness of the combined feedforward  +  feedback control scheme to consistently achieve the desired target profiles at the predefined times. These results also show how the addition of feedback control significantly improves upon the feedforward-only control solution by reducing the matching error and also how the feedback controller is able to reduce the matching error as the constraint on the maximum allowable total auxiliary power is relaxed while keeping the plasma in L-mode.
ISSN:0029-5515
1741-4326