The generalized scalar auxiliary variable applied to the incompressible Boussinesq Equation
By: Andreas Wagner, Barbara Wohlmuth, Jan Zawallich
Potential Business Impact:
Makes computer models of ocean waves more accurate.
This paper introduces a second-order time discretization for solving the incompressible Boussinesq equation. It uses the generalized scalar auxiliary variable (GSAV) and a backward differentiation formula (BDF), based on a Taylor expansion around $t^{n+k}$ for $k\geq3$. An exponential time integrator is used for the auxiliary variable to ensure stability independent of the time step size. We give rigorous asymptotic error estimates of the time-stepping scheme, thereby justifying its accuracy and stability. The scheme is reformulated into one amenable to a $H^1$-conforming finite element discretization. Finally, we validate our theoretical results with numerical experiments using a Taylor--Hood-based finite element discretization and show its applicability to large-scale 3-dimensional problems.
Similar Papers
New highly efficient and accurate numerical scheme for the Cahn-Hilliard-Brinkman system
Numerical Analysis
Makes computer models of materials more accurate.
A highly efficient second-order accurate long-time dynamics preserving scheme for some geophysical fluid models
Numerical Analysis
Predicts weather patterns more accurately for longer.
An explicit splitting SAV scheme for the kinetic Langevin dynamics
Numerical Analysis
Makes computer simulations of tiny things more accurate.