The Isogeometric Nyström Method
For researchers in computational mechanics and isogeometric analysis, this method offers a simpler and more flexible alternative to existing boundary integral equation solvers, though it has limitations.
The paper introduces the isogeometric Nyström method for solving boundary integral equations, which requires only pointwise function evaluations and works with various CAD geometries. Numerical tests demonstrate higher-order convergence in 2D and 3D for Laplace and Lamé-Navier equations.
In this paper the isogeometric Nyström method is presented. It's outstanding features are: it allows the analysis of domains described by many different geometrical mapping methods in computer aided geometric design and it requires only pointwise function evaluations just like isogeometric collocation methods. The analysis of the computational domain is carried out by means of boundary integral equations, therefor only the boundary representation is required. The method is thoroughly integrated into the isogeometric framework. For example, the regularization of the arising singular integrals performed with local correction as well as the interpolation of the pointwise existing results are carried out by means of Bezier elements. The presented isogeometric Nyström method is applied to practical problems solved by the Laplace and the Lame-Navier equation. Numerical tests show higher order convergence in two and three dimensions. It is concluded that the presented approach provides a simple and flexible alternative to currently used methods for solving boundary integral equations, but has some limitations.