Div First-Order System LL* (FOSLL*) for Second-Order Elliptic Partial Differential Equations
For researchers in numerical PDEs, this work extends the FOSLL* framework to a simpler formulation, but the improvement over existing methods is incremental.
This paper applies the FOSLL* approach to the div system for second-order elliptic PDEs, establishing well-posedness and deriving a quasi-optimal a priori error bound without mesh size restrictions, and proposes an explicit residual error estimator with reliability and efficiency bounds.
The first-order system LL* (FOSLL*) approach for general second-order elliptic partial differential equations was proposed and analyzed in [10], in order to retain the full efficiency of the L2 norm first-order system least-squares (FOSLS) ap- proach while exhibiting the generality of the inverse-norm FOSLS approach. The FOSLL* approach in [10] was applied to the div-curl system with added slack vari- ables, and hence it is quite complicated. In this paper, we apply the FOSLL* approach to the div system and establish its well-posedness. For the corresponding finite ele- ment approximation, we obtain a quasi-optimal a priori error bound under the same regularity assumption as the standard Galerkin method, but without the restriction to sufficiently small mesh size. Unlike the FOSLS approach, the FOSLL* approach does not have a free a posteriori error estimator, we then propose an explicit residual error estimator and establish its reliability and efficiency bounds