The role of the dual grid in low-order compatible numerical schemes on general meshes.

• We uncover hidden geometric aspects of low-order compatible numerical schemes. • Proof of the equivalence between mimetic numerical schemes and geometric approaches. • Novel geometric definition of polynomial consistency for reconstruction operators. • Proof of the existence of other dual grids besides the barycentric dual grid. • Optimization of reconstruction operators to minimize the reconstruction error. In this work, we uncover hidden geometric aspect of low-order compatible numerical schemes. First, we rewrite standard mimetic reconstruction operators defined by Stokes theorem using geometric elements of the barycentric dual grid, providing the equivalence between mimetic numerical schemes and discrete geometric approaches. Second, we introduce a novel global property of the reconstruction operators, called P 0 -consistency, which extends the standard consistency requirement of the mimetic framework. This concept characterizes the whole class of reconstruction operators that can be used to construct a global mass matrix in such a way that a global patch test is passed. Given the geometric description of the scheme, we can set up a correspondence between entries of reconstruction operators and geometric elements of a secondary grid, which is built by duality from the primary grid used in the scheme formulation. Finally, we show the that the geometric interpretation is necessary for the correct evaluation of certain physical variables in the post-processing stage. A discussion on how the geometric viewpoint allows to optimize reconstruction operators completes the exposition. [ABSTRACT FROM AUTHOR]