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We present a two-scale theoretical framework for approximating the solution of a second order elliptic problem. The elliptic coefficient is assumed to vary on a scale that can be resolved on a fine numerical grid, but limits on computational power require that computations be performed on a coarse grid. We consider the elliptic problem in mixed variational form over W V L² H (div). We base our scale expansion on local mass conservation over the coarse grid. It is used to define a direct sum decomposition of W V into coarse and "subgrid" subspaces Wc Vc and W V such that (1) Vc=Wc and V = W, and (2) the space V is locally supported over the coarse mesh. We then explicitly decompose the variational problem into coarse and subgrid scale problems. The subgrid problem gives a well-defined operator taking Wc Vc to W V, which is localized in space, and it is used to upscale, that is, to remove the subgrid from the coarse-scale problem. Using standard mixed finite element spaces, two-scale mixed spaces are defined. A mixed approximation is defined, which can be viewed as a type of variational multiscale method or a residual-free bubble technique. A numerical Green's function approach is used to make the approximation to the subgrid operator efficient to compute. A mixed method -operator is defined for the two-scale approximation spaces and used to show optimal order error estimates.
Todd Arbogast (Thu,) studied this question.