TY - JOUR
T1 - Adaptive Hybridizable Discontinuous Galerkin discretization of the Grad–Shafranov equation by extension from polygonal subdomains
AU - Sánchez-Vizuet, Tonatiuh
AU - Solano, Manuel E.
AU - Cerfon, Antoine J.
N1 - Funding Information:
The authors are deeply grateful to Wrick Sengupta (NYU) and Georg Stadler (NYU) for their valuable insights on the physical and mathematical aspects of the problem. They also thank François Waelbroeck (UT-Austin) for suggesting the current hole problem as a benchmarking test. Antoine J. Cerfon and Tonatiuh Sánchez-Vizuet were partially funded by the US Department of Energy . Grant No. DE-FG02-86ER53233 . Manuel E. Solano was partially funded by CONICYT–Chile through FONDECYT project No. 1160320 and by Project AFB170001 of the PIA Program: Concurso Apoyo a Centros Cientificos y Tecnologicos de Excelencia con Financiamiento Basal, Chile .
Funding Information:
A.J.C. and T. S-V have been partially funded by the US Department of Energy. Grant No. DE-FG02-86ER53233.M. S. has been partially funded by CONICYT?Chile through FONDECYT project No. 1160320 and by Project AFB170001 of the PIA Program: Concurso Apoyo a Centros Cientificos y Tecnologicos de Excelencia con Financiamiento Basal, Chile.The computational implementation of the algorithm described in this paper benefited greatly from the detailed explanations and code templates for HDG and adaptive refinement provided respectively by Fu, Gatica and Sayas [49], and Funken, Praetorius and Wissgott [50]. Finally, sampling of the confinement regions from the analytic expressions given in [41] was done using chebfun [51]. The authors are deeply grateful to Wrick Sengupta (NYU) and Georg Stadler (NYU) for their valuable insights on the physical and mathematical aspects of the problem. They also thank Fran?ois Waelbroeck (UT-Austin) for suggesting the current hole problem as a benchmarking test. Antoine J. Cerfon and Tonatiuh S?nchez-Vizuet were partially funded by the US Department of Energy. Grant No. DE-FG02-86ER53233. Manuel E. Solano was partially funded by CONICYT?Chile through FONDECYT project No. 1160320 and by Project AFB170001 of the PIA Program: Concurso Apoyo a Centros Cientificos y Tecnologicos de Excelencia con Financiamiento Basal, Chile.
Publisher Copyright:
© 2020 Elsevier B.V.
PY - 2020/10
Y1 - 2020/10
N2 - We propose a high-order adaptive numerical solver for the semilinear elliptic boundary value problem modeling magnetic plasma equilibrium in axisymmetric confinement devices. In the fixed boundary case, the equation is posed on curved domains with piecewise smooth curved boundaries that may present corners. The solution method we present is based on the hybridizable discontinuous Galerkin method and sidesteps the need for geometry-conforming triangulations thanks to a transfer technique that allows to approximate the solution using only a polygonal subset as computational domain. Moreover, the solver features automatic mesh refinement driven by a residual-based a posteriori error estimator. As the mesh is locally refined, the computational domain is automatically updated in order to always maintain the distance between the actual boundary and the computational boundary of the order of the local mesh diameter. Numerical evidence is presented of the suitability of the estimator as an approximate error measure for physically relevant equilibria with pressure pedestals, internal transport barriers, and current holes on realistic geometries.
AB - We propose a high-order adaptive numerical solver for the semilinear elliptic boundary value problem modeling magnetic plasma equilibrium in axisymmetric confinement devices. In the fixed boundary case, the equation is posed on curved domains with piecewise smooth curved boundaries that may present corners. The solution method we present is based on the hybridizable discontinuous Galerkin method and sidesteps the need for geometry-conforming triangulations thanks to a transfer technique that allows to approximate the solution using only a polygonal subset as computational domain. Moreover, the solver features automatic mesh refinement driven by a residual-based a posteriori error estimator. As the mesh is locally refined, the computational domain is automatically updated in order to always maintain the distance between the actual boundary and the computational boundary of the order of the local mesh diameter. Numerical evidence is presented of the suitability of the estimator as an approximate error measure for physically relevant equilibria with pressure pedestals, internal transport barriers, and current holes on realistic geometries.
KW - Adaptive Hybridizable Discontinuous Galerkin (HDG)
KW - Curved boundaries
KW - Local mesh refinement
KW - Plasma Equilibrium
KW - Residual error estimator
KW - Un-fitted mesh
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U2 - 10.1016/j.cpc.2020.107239
DO - 10.1016/j.cpc.2020.107239
M3 - Article
AN - SCOPUS:85081234967
SN - 0010-4655
VL - 255
JO - Computer Physics Communications
JF - Computer Physics Communications
M1 - 107239
ER -