Towards In-Between-Discharges Model-Based Scenario Planning in NSTX-U Via Fast Nonlinear Optimization
B. Leard, S.-T. Paruchuri, T. Rafiq, E. Schuster
Division of Plasma Physics (DPP) Annual Meeting of the American Physical Society (APS)
Pittsburgh, PA, USA (Remote), November 8-12, 2021
The realization of advanced scenarios in tokamaks is achieved by
carefully selecting the actuator trajectory waveforms, which defines a
feedforward control problem. As an alternative to the usual “trial-and-error”
approach, a more systematic approach to scenario planning via model-based
optimization has been proposed [1]. By parameterizing the actuator trajectories,
the feedforward control inputs are determined by minimizing a cost function
measuring the distance between actual and desired plasma state. This arbitrary
cost function, which can weigh different properties of the desired plasma state,
is minimized subject to plasma-dynamics, actuator, and state constraints
by using Sequential Quadratic Programming. To avoid spending time in
numerically computing the gradients of the cost function with respect
to the to-be-optimized parameters, analytical expressions of these
gradients are pre-calculated in this work. These expressions require
the integration of a plasma transport model for NSTX-U, which is provided
in this case by the Control Oriented Transport SIMulator (COTSIM). This
fast feedforward- control optimizer has the potential of being used
routinely for in- between-discharges scenario planning at NSTX-U.
[1] D. Dang, B. Leard, T. Rafiq, E. Schuster, this conference.
*Supported by the US DOE under DE-SC0021385.