Analysis of multipatch discontinuous Galerkin IgA approximations to elliptic boundary value problems

• Published in: Computing and visualization in science Vol. 17; no. 5; pp. 217 - 233
• Main Authors: Langer, Ulrich, Toulopoulos, Ioannis
• Format: Journal Article
• Language: English
• Published: Berlin/Heidelberg Springer Berlin Heidelberg 01.10.2015
• Subjects: Algorithms; Calculus of Variations and Optimal Control; Optimization; Computational Mathematics and Numerical Analysis; Computer Applications in Chemistry; Mathematics; Mathematics and Statistics; Numerical Analysis; Visualization; Isogeometric analysis; 65N15; 65N12; 65N35; Linear elliptic problems; Non-matching meshes; Low regularity solutions; Discontinuous coefficients; A priori discretization error estimates; Discontinuous Galerkin discretization
• ISSN: 1432-9360; 1433-0369
• DOI: 10.1007/s00791-016-0262-6

In this work, we study the approximation properties of multipatch dG-IgA methods, that apply the multipatch Isogeometric Analysis discretization concept and the discontinuous Galerkin technique on the interfaces between the patches, for solving linear diffusion problems with diffusion coefficients that may be discontinuous across the patch interfaces. The computational domain is divided into non-overlapping subdomains, called patches in IgA, where B-splines, or NURBS approximations spaces are constructed. The solution of the problem is approximated in every subdomain without imposing any matching grid conditions and without any continuity requirements for the discrete solution across the interfaces. Numerical fluxes with interior penalty jump terms are applied in order to treat the discontinuities of the discrete solution on the interfaces. We provide a rigorous a priori discretization error analysis for diffusion problems in two- and three-dimensional domains, where solutions patchwise belong to W l , p , with some l ≥ 2 and p ∈ ( 2 d / ( d + 2 ( l - 1 ) ) , 2 ] . In any case, we show optimal convergence rates of the discretization with respect to the dG - norm.