Abstract
While the use of finite element methods for the numerical approximation of eigenvalues is a well-studied problem, the use of serendipity elements for this purpose has received little attention in the literature. We show by numerical experiments that serendipity elements, which are defined on a square reference geometry, can attain the same order of accuracy as their tensor product counterparts while using dramatically fewer degrees of freedom. In some cases, the serendipity method uses only 50% as many basis functions as the tensor product method while still producing the same numerical approximation of an eigenvalue. To encourage the further use and study of serendipity elements, we provide a table of serendipity basis functions for low-order cases and a Mathematica file that can be used to generate the basis functions for higher-order cases.
Citation
Andrew Gillette. Craig Gross. Ken Plackowski. "Numerical studies of serendipity and tensor product elements for eigenvalue problems." Involve 11 (4) 661 - 678, 2018. https://doi.org/10.2140/involve.2018.11.661
Information