Adaptive refinement for unstructured T-splines with linear complexity
Preprint, 2021

We present an adaptive refinement algorithm for T-splines on unstructured 2D meshes. While for structured 2D meshes, one can refine elements alternatingly in horizontal and vertical direction, such an approach cannot be generalized directly to unstructured meshes, where no two unique global mesh directions can be assigned. To resolve this issue, we introduce the concept of direction indices, i.e., integers associated to each edge, which are inspired by theory on higher-dimensional structured T-splines. Together with refinement levels of edges, these indices essentially drive the refinement scheme. We combine these ideas with an edge subdivision routine that allows for I-nodes, yielding a very flexible refinement scheme that nicely distributes the T-nodes, preserving global linear independence, analysis-suitability (local linear independence) except in the vicinity of extraordinary nodes, sparsity of the system matrix, and shape regularity of the mesh elements. Further, we show that the refinement procedure has linear complexity in the sense of guaranteed upper bounds on
a) the distance between marked and additionally refined elements, and on
b) the ratio of the numbers of generated and marked mesh elements.

T-splines

unstructured meshes

adaptive refinement

Author

Roland Maier

University of Gothenburg

Chalmers, Mathematical Sciences, Applied Mathematics and Statistics

Philipp Morgenstern

University of Hanover

Thomas Takacs

Johannes Kepler University of Linz (JKU)

Subject Categories

Computational Mathematics

More information

Latest update

9/9/2022 7