Unconditional Convergence of High-Order Extrapolations of the Crank-Nicolson, Finite Element Method for the Navier-Stokes Equations
Year: 2013
International Journal of Numerical Analysis and Modeling, Vol. 10 (2013), Iss. 2 : pp. 257–297
Abstract
Error estimates for the Crank-Nicolson in time, Finite Element in space (CNFE) discretization of the Navier-Stokes equations require application of the discrete Gronwall inequality, which leads to a time-step (Δt) restriction. All known convergence analyses of the fully discrete CNFE with linear extrapolation rely on a similar Δt-restriction. We show that CNFE with arbitrary-order extrapolation (denoted CNLE) is convergences optimally in the energy norm without any Δt-restriction. We prove that CNLE velocity and corresponding discrete time-derivative converge optimally in l∞(H1) and l2(L2) respectively under the mild condition Δt≤Mh1/4 for any arbitrary M>0 (e.g. independent of problem data, h, and Δt) where h>0 is the maximum mesh element diameter. Convergence in these higher order norms is needed to prove convergence estimates for pressure and the drag/lift force a fluid exerts on an obstacle. Our analysis exploits the extrapolated convective velocity to avoid any Δt-restriction for convergence in the energy norm. However, the coupling between the extrapolated convecting velocity of usual CNLE and the a priori control of average velocities (characteristic of CN methods) rather than pointwise velocities (e.g. backward-Euler methods) in l2(H1) is precisely the source of Δt-restriction for convergence in higher-order norms.
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Journal Article Details
Publisher Name: Global Science Press
Language: English
DOI: https://doi.org/2013-IJNAM-568
International Journal of Numerical Analysis and Modeling, Vol. 10 (2013), Iss. 2 : pp. 257–297
Published online: 2013-01
AMS Subject Headings: Global Science Press
Copyright: COPYRIGHT: © Global Science Press
Pages: 41
Keywords: Navier-Stokes Crank-Nicolson finite element extrapolation linearization error convergence linearization.