Synthesis and modeling of the \(H_\infty\)-system of magnetic control of the plasma in the tokamak-reactor. (English. Russian original) Zbl 1143.93316
Autom. Remote Control 68, No. 8, 1410-1428 (2007); translation from Avtom. Telemekh. 2007, No. 8, 126-145 (2007).
Summary: The article deals with the development of a two-contour system of magnetic control of the position, current, and shape of the plasma in the tokamak-reactor. The \(H _{\infty }\)-theory of control is used for the synthesis of a scalar and a multidimensional feedback controller. The controllers are synthesized on the basis of the multidimensional linear model DINA-L of an object (plasma in the tokamak). The linear model DINA-L is obtained from the nonlinear model implemented by the plasmophysical DINA code for conditions of the International Thermonuclear Experimental Reactor (ITER). The numerical modeling of a closed control system is carried out on the linear DINA-L model and the nonlinear DINA model of an object at disturbances of the type of small disruptions. The modeling results for both of the cases were superimposed on each other, which showed their good coincidence at the acceptable quality of control of the synthesized system.
MSC:
| 93B50 | Synthesis problems |
| 93A30 | Mathematical modelling of systems (MSC2010) |
| 93C95 | Application models in control theory |
| 93B35 | Sensitivity (robustness) |
Keywords:
synthesis of scalar and multidimensional feedback controller; controllable thermonuclear synthesisReferences:
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