Nonconforming Linear Element Method for a Generalized Tensor-Valued Stokes Equation with Application to the Triharmonic Equation
By: Ziwen Gu, Xuehai Huang
Potential Business Impact:
Solves tricky math problems for better computer simulations.
A nonconforming linear element method is developed for a three-dimensional generalized tensor-valued Stokes equation associated with the Hessian complex in this paper. A discrete Helmholtz decomposition for the piecewise constant space of traceless tensors is established, ensuring the well-posedness of the nonconforming method, and optimal error estimates are derived. Building on this, a low-order decoupled finite element method for the three-dimensional triharmonic equation is constructed by combining the Morley-Wang-Xu element methods for the biharmonic subproblems with the proposed nonconforming linear element method. Numerical experiments confirm the theoretical convergence rates.
Similar Papers
Superconvergent and Divergence-Free Finite Element Methods for Stokes Equation
Numerical Analysis
Makes computer simulations of fluid flow more accurate.
An Optimal and Robust Nonconforming Finite Element Method for the Strain Gradient Elasticity
Numerical Analysis
Solves hard math problems for stronger materials.
A linearly-implicit energy-momentum preserving scheme for geometrically nonlinear mechanics based on non-canonical Hamiltonian formulations
Numerical Analysis
Simulates how bendy things move without breaking.