Two-level Picard and modified Picard methods for the Navier-Stokes equations

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Iterative methods of Picard type for the Navier-Stokes equations are known to converge only for quite small Reynolds numbers. However, we study methods involving just one such iteration at general Reynolds numbers. For the initial approximation a coarse mesh of width h0 is used. The corrected approximation is computed by just one Picard or modified Picard step on a fine mesh of width h1. For example, h1 may be of order O(h02) when linear velocity elements are used. The resulting method requires the solution of a (small) system of nonlinear equations on the coarse mesh and only one (larger) linear system on the fine mesh.This two-level Picard method is proven to converge for fixed Reynolds number as h → 0. Further, the fine mesh solution satisfies a quasi-optimal error bound. (The error constants grow as Re → ∞, as for the usual finite element method.)One very heuristic explanation why one step of the (divergent) Picard method might work when beginning with a coarse mesh approximation is that the terms neglected involve lower-order derivatives; thus they are approximated with higher accuracy on the coarse mesh. This is linked with a “smoothing property” of the fine mesh step.

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论文评审过程:Available online 7 April 2000.

论文官网地址:https://doi.org/10.1016/0096-3003(94)00134-P