The content presents a new multiscale finite element method, called the Multiscale Hybrid-Hybrid Method (MH2M), for solving the Darcy equation with heterogeneous coefficients. The key highlights are:
The MH2M method is built upon the three-field formulation introduced by Brezzi and Marini, where the continuity of the flow variable is weakly enforced through a second Lagrange multiplier.
The method decomposes the solution into local and global contributions, where the global formulation is defined on the skeleton of a coarse partition and yields the degrees of freedom. The local problems provide the multiscale basis functions and can be computed in parallel.
The MH2M induces a symmetric positive definite global linear system, unlike the original Multiscale Hybrid-Mixed (MHM) method which has a saddle point structure.
The basis for the flux variable is obtained from a Dirichlet-to-Neumann operator defined from new local Neumann problems, which is different from the ad-hoc choice in the MHM method.
The method imposes weak continuity of the discrete primal (pressure) and dual (flow) variables on the skeleton of the coarse partition, with a discrete flow that is in local equilibrium with external forces.
The authors establish the well-posedness and best approximation results for the MH2M under abstract compatibility conditions between the interpolation spaces. They also propose families of interpolation spaces that satisfy these conditions and prove optimal convergence.
Connections between the MH2M and other multiscale finite element methods, notably the MHM method and the Multiscale Finite Element Method (MsFEM), are established.
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