Your search keyword '"Doelman N."' showing total 2 results

1. Robust sawtooth period control based on adaptive online optimization.

Author

Bolder, J. J., Witvoet, G., De Baar, M. R., Van De Wouw, N., Haring, M. A. M., Westerhof, E., Doelman, N. J., and Steinbuch, M.

Subjects

SAWTOOTH generators, PLASMA stability, ADAPTIVE control systems, COST functions, TIME-varying systems, FUSION reactors

Abstract

The systematic design of a robust adaptive control strategy for the sawtooth period using electron cyclotron current drive (ECCD) is presented. Recent developments in extremum seeking control (ESC) are employed to derive an optimized controller structure and offer practical tuning guidelines for its parameters. In this technique a cost function in terms of the desired sawtooth period is optimized online by changing the ECCD deposition location based on online estimations of the gradient of the cost function. The controller design does not require a detailed model of the sawtooth instability. Therefore, the proposed ESC is widely applicable to any sawtoothing plasma or plasma simulation and is inherently robust against uncertainties or plasma variations. Moreover, it can handle a broad class of disturbances. This is demonstrated by time-domain simulations, which show successful tracking of time-varying sawtooth period references throughout the whole operating space, even in the presence of variations in plasma parameters, disturbances and slow launcher mirror dynamics. Due to its simplicity and robustness the proposed ESC is a valuable sawtooth control candidate for any experimental tokamak plasma, and may even be applicable to other fusion-related control problems. [ABSTRACT FROM AUTHOR]

Published

2012

2. Sawtooth period control strategies and designs for improved performance.

Author

Witvoet, G., Steinbuch, M., De Baar, M. R., Doelman, N. J., and Westerhof, E.

Subjects

SAWTOOTH generators, PLASMA confinement, PLASMA stability, HELIUM, PERFORMANCE evaluation, PUBLISHING

Abstract

The sawtooth instability is associated with the triggering of neo-classical tearing modes, core fuelling, α-confinement and the exhaust of thermal helium. Sawtooth control is therefore important for optimal reactor performance in ELMy H-modes. Control schemes for the sawtooth period have been published in the literature, but the systematic design of high-performance controllers (yielding accurate and fast convergent responses) has not been addressed. In this work, three control strategies for high-performance sawtooth control are presented using electron cyclotron current drive (ECCD). Both degrees of freedom of the ECCD actuator will be explored and combined with advanced controller designs. First, the ECCD deposition location is used as a control variable, for which a gain-scheduled feedback controller and static feedforward control is derived. Second, the use of the driven current as a control variable is explored, and a simple controller is designed based on the identified dynamics. In the third approach both control variables are joined in an overall controller design, which enables the combination of high-performance control of the sawtooth period and control of the gyrotron power. Time-domain simulations with a combined Kadomtsev-Porcelli sawtooth model show that each strategy obtains a better closed-loop performance than standard linear feedback techniques on merely the deposition location. [ABSTRACT FROM AUTHOR]

Published

2012