Backstepping Control of the Plasma Current Profile in the DIII-D Tokamak
M.D. Boyer, J. Barton, E. Schuster, T.C. Luce, J.R. Ferron, M.L. Walker, D.A. Humphreys, B.G. Penaflor and R.D. Johnson
American Control Conference
Montreal, Canada, June 27-29, 2012
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Abstract
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Control of the spatial profile of plasma current in tokamak plasmas
has been demonstrated to be a key condition for achieving advanced
scenarios with improved confinement and possible steady-state
operation. The dynamics of the current profile are nonlinear and
coupled with several other plasma parameters, motivating the design of
model-based controllers that can account for these complexities. In
this work, we consider a control-oriented model of the current profile
evolution in DIII-D and the problem of regulating the current profile
around a desired feed-forward trajectory. In open-loop, the response
of the system to disturbances and perturbed initial conditions may be
undesirable. To improve the performance of the system, the PDE model
is discretized in space using a finite difference method and a
backstepping design is applied to obtain a discrete transformation
from the original system into an asymptotically stable target system
with desirable properties. Through a nonlinear transformation, the
resulting boundary control law utilizes the total plasma current,
total power, and line averaged density as actuators. A Simserver
simulation study is done to test the controller’s performance and its
implementation in the DIII-D plasma control system. Finally,
experimental results showing the ability of the controller to reject
input disturbances and perturbations in initial conditions are
presented.
