Plasma models for real-time control of advanced tokamak scenarios

Moreau, D.; Mazon, D.; Walker, M.L.; Ferron, J. R.; Burrell, K.H.; Flanagan, S.; Gohil, P.; Groebner, R. J.; Hyatt, A.W.; Haye, R.J. La; Lohr, J.; Turco, F.; Schuster, Eugenio; Ou, Yongsheng; Xu, Chao; Takase, Y.; Sakamoto, Y.; Ide, S.; Suzuki, Takahiro; experts,

doi:10.1088/0029-5515/51/6/063009

Cited by 42 publications

(67 citation statements)

References 15 publications

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“…The pioneering work in this area is due to Moreau, who in [15] derived empirical models for current profile evolutions using system identification techniques, and then used these models to synthesize a controller for safety factor profile manipulation. This approach, called the data-driven modeling method, does not rely on first principles to derive the model, but rather involves constructing the model by fitting observed data from experiments (e.g., JT-60 in Japan and DIII-D in the USA [16]), where the observed data is generated by input signals covering a sufficiently broad range of frequencies. As an alternative approach, it is also possible to use PDE models derived from first principles for the control and optimization of internal spatial profiles.…”

Section: Magnetohydrodynamic Equilibrmentioning

confidence: 99%

Dynamic optimization of open-loop input signals for ramp-up current profiles in tokamak plasmas

Ren

Lin

et al. 2016

Communications in Nonlinear Science and Numerical Simulation

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Establishing a good current spatial profile in tokamak fusion reactors is crucial to effective steadystate operation. The evolution of the current spatial profile is related to the evolution of the poloidal magnetic flux, which can be modeled in the normalized cylindrical coordinates using a parabolic partial differential equation (PDE) called the magnetic diffusion equation. In this paper, we consider the dynamic optimization problem of attaining the best possible current spatial profile during the rampup phase of the tokamak. We first use the Galerkin method to obtain a finite-dimensional ordinary differential equation (ODE) model based on the original magnetic diffusion PDE. Then, we combine the control parameterization method with a novel time-scaling transformation to obtain an approximate optimal parameter selection problem, which can be solved using gradient-based optimization techniques such as sequential quadratic programming (SQP). This control parameterization approach involves approximating the tokamak input signals by piecewise-linear functions whose slopes and break-points are decision variables to be optimized. We show that the gradient of the objective function with respect to the decision variables can be computed by solving an auxiliary dynamic system governing the state sensitivity matrix. Finally, we conclude the paper with simulation results for an example problem based on experimental data from the DIII-D tokamak in San Diego, California.

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Section: Magnetohydrodynamic Equilibrmentioning

confidence: 99%

Dynamic optimization of open-loop input signals for ramp-up current profiles in tokamak plasmas

Ren

Lin

et al. 2016

Communications in Nonlinear Science and Numerical Simulation

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“…Distributed parameter simulations [44] are the preferred option to simulate current profile evolution during plasma current transients. There are many such distributed parameter models available [45]- [48], some control oriented [49], [50] and some even available in real time [51]. However, for control systems design a lumped parameter formulation is generally preferable [52], [53].…”

Section: Skin Effect Transformer Modelmentioning

confidence: 99%

“…The information from magnetic sensors is combined to obtain the Shafranov parameter Λ and the poloidal using the formulas described in [65]. From these the normalized internal inductance is obtained as (49) which is normalized to the machine major radius r 0. The internal inductance in SI units is The magnetic energy content inside the vacuum vessel walls is then trivially obtained as…”

Section: Real Time Measurements and Observersmentioning

confidence: 99%

Sliding mode control of a tokamak transformer

Romero¹,

Coda

Felici

et al. 2012

2012 IEEE 51st IEEE Conference on Decision and Control (CDC)

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A novel inductive control system for a tokamak transformer is described. The system uses the flux change provided by the transformer primary coil to control either the electric current or the internal inductance of the transformer's secondary plasma circuit load. The internal inductance control is used to regulate the slow flux penetration due to the skin effect, providing first-order control over the shape of the plasma current density profile in the highly conductive plasma. Inferred loop voltages at specific locations inside the plasma are included in a state feedback structure to improve controller performance. Experimental tests have shown that the plasma internal inductance can be controlled inductively for a whole pulse starting just 30ms after the beginning of plasma breakdown. The details of the control system design are presented, including the transformer model, observer algorithms and controller design.

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“…Operations scenarios with reduced intrinsic disruptivity should be found, and control techniques must be developed to both maintain those optimal equilibrium characteristics and to prevent the growth of disruptive MHD. Examples of equilibrium control techniques include control of the strongly shaped plasma boundary [37,38], the global β N [39][40][41], the internal profiles [42][43][44][45], or error fields [46,47]. The vertical position instability [48][49][50][51][52] is controlled [50][51][52] as a matter of routine in all shaped tokamaks.…”

Section: : Introductionmentioning

confidence: 99%