Abstract
In mixed finite element approximations of Hodge Laplace problems associated with the de Rham complex, the exterior derivative operators are computed exactly, so the spatial locality is preserved. However, the numerical approximations of the associated coderivatives are nonlocal and can be regarded as an undesired effect of standard mixed methods. For numerical methods with local coderivatives, a perturbation of low order mixed methods in the sense of variational crimes has been developed for simplicial and cubical meshes. In this paper we extend the low order method to all high orders on cubical meshes using a new family of finite element differential forms on cubical meshes. The key theoretical contribution is a generalization of the linear degree, in the construction of the serendipity family of differential forms, and this generalization is essential in the unisolvency proof of the new family of finite element differential forms.
Reference28 articles.
1. Interpretation of a two-point flux stencil for skew parallelogram grids
2. Abramowitz M. and Stegun I.A., Handbook of Mathematical Functions with Formulas, Graphs, and Mathematical Tables. National Bureau of Standards Applied Mathematics Series. Vol. 55, For sale by the Superintendent of Documents, U.S. Government Printing Office, Washington, DC (1964).
3. Higher order multipoint flux mixed finite element methods on quadrilaterals and hexahedra
4. Finite element differential forms on cubical meshes