A hybrid isogeometric and finite element method: NURBS-enhanced finite element method for hexahedral meshes

In this paper, we present a NURBS-enhanced finite element method that integrates NURBS-based boundary representations of geometric domains into standard finite element frameworks applied to hexahedral meshes. We decompose an open, bounded, convex three-dimensional domain with a NURBS boundary into two parts, define the NURBS-enhanced finite elements over the boundary layer, and use piecewise-linear Lagrange finite elements in the interior region. We introduce a novel quadrature rule and a novel interpolation operator for the NURBS-enhanced elements. We derive the stability and approximation properties of the interpolation operators that we use. We describe how the h-refinement in finite element analysis and the knot insertion in isogeometric analysis can be utilized in the refinement of the NURBS-enhanced elements. To illustrate an application of our methodology, we utilize a generic weak formulation of a second-order elliptic PDE and derive a priori error estimates in the $H^{1}$ norm. The proposed methodology combines the efficiency of finite element analysis with the geometric precision of NURBS, and may enable more accurate and efficient simulations over complex geometries.