Physics-model-based nonlinear actuator trajectory optimization and safety factor profile feedback control for advanced scenario development in DⅢ-D

摘要

DⅢ-D experimental results are reported to demonstrate the potential of physics-model-based safety factor profile control for robust and reproducible sustainment of advanced scenarios. In the absence of feedback control, variability in wall conditions and plasma impurities, as well as drifts due to external disturbances, can limit the reproducibility of discharges with simple preprogrammed scenario trajectories. The control architecture utilized is a feedforward + feedback scheme where the feedforward commands are computed off-line and the feedback commands are computed on-line. In this work, a first-principles-driven (FPD), physics-based model of the q profile and normalized beta (β_N) dynamics is first embedded into a numerical optimization algorithm to design feedforward actuator trajectories that steer the plasma through the tokamak operating space to reach a desired stationary target state that is characterized by the achieved q profile and β_N. Good agreement between experimental results and simulations demonstrates the accuracy of the models employed for physics-model-based control design. Second, a feedback algorithm for q profile control is designed following an FPD approach, and the ability of the controller to achieve and maintain a target q profile evolution is tested in DⅢ-D high confinement (H-mode) experiments. The controller is shown to be able to effectively control the q profile when β_N is relatively close to the target, indicating the need for integrated q profile and β_N control to further enhance the ability to achieve robust scenario execution. The ability of an integrated q profile + β_N feedback controller to track a desired target is demonstrated through simulation.