2015
DOI: 10.1017/s0022377814001251
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Quasi-static free-boundary equilibrium of toroidal plasma with CEDRES++: Computational methods and applications

Abstract: We present a comprehensive survey of the various computational methods in CEDRES++ for finding equilibria of toroidal plasma. Our focus is on free-boundary plasma equilibria, where either poloidal field coil currents or the temporal evolution of voltages in poloidal field circuit systems are given data. Centered around a piecewise linear finite element representation of the poloidal flux map, our approach allows in large parts the use of established numerical schemes. The coupling of a finite element method an… Show more

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Cited by 47 publications
(90 citation statements)
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“…The Grad-Shafranov partial differential equation is solved by using numerical codes [3,50,54,57], and returns the poloidal flux w, and in particular its value in the conductive structures that surrounds the plasma, both passive and active (i.e., the PF coils). This information can be used to compute the parameters of the following nonlinear lumped parameters circuital model, that can be obtained under axisymmetric assumption and describes the behaviour of the plasma and of the currents that flow in the surrounding conductive structures (more details can be found in [4 • y(t) are the outputs to be controlled; other than the plasma current and the current in the active and passive structures, this vector may contain plasma shape and position descriptors, e.g.…”
Section: The Following Remarks Apply To the Nyquist Stability Criterionmentioning
confidence: 99%
“…The Grad-Shafranov partial differential equation is solved by using numerical codes [3,50,54,57], and returns the poloidal flux w, and in particular its value in the conductive structures that surrounds the plasma, both passive and active (i.e., the PF coils). This information can be used to compute the parameters of the following nonlinear lumped parameters circuital model, that can be obtained under axisymmetric assumption and describes the behaviour of the plasma and of the currents that flow in the surrounding conductive structures (more details can be found in [4 • y(t) are the outputs to be controlled; other than the plasma current and the current in the active and passive structures, this vector may contain plasma shape and position descriptors, e.g.…”
Section: The Following Remarks Apply To the Nyquist Stability Criterionmentioning
confidence: 99%
“…Hence, if we want to use a fully adjoint method to compute the gradient of our reduced objective functional we need to have explicit expressions of the derivatives of c pe , c ct , c eq , and I with respect to the control ϕ and state variables q eq , q ct , and q pe . The derivatives B ϕ c eq pϕ, q eq q and B qeq c eq pϕ, q eq q of the equilibrium problem are available both for the continuous as well as for the discretized problem [8]. Also the derivative B qpe c pe pq ct , q pe q was given explicitly in [20].…”
Section: A Problem Adapted Efficient Computation Of the Objective Gramentioning
confidence: 99%
“…We are solving this FBE problem by the numerical methods outlined in [8,17]. The poloidal flux is approximated by a finite dimensional function that is piecewise linear with respect to an unstructured triangular mesh.…”
Section: Free Boundary Equilibrium Computationmentioning
confidence: 99%
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