Minimum residual discretization of a semilinear elliptic problem
This work addresses a specific computational challenge in numerical analysis for partial differential equations, representing an incremental advancement in method adaptation.
The authors tackled the extension of the discontinuous Petrov-Galerkin method to semilinear elliptic problems by using a least-squares penalization approach, proving a Cea estimate for approximation error and demonstrating performance with numerical results on uniform and adaptive meshes.
We propose a least-squares penalization as a means to extend the discontinuous Petrov-Galerkin (DPG) method with optimal test functions to a class of semilinear elliptic problems. The nonlinear contributions are replaced with independent unknowns so that standard DPG techniques apply to the then linear problem with non-trivial kernel. The nonlinear relations are added as least-squares constraints. Assuming solvability of the semilinear problem and an Aubin-Nitsche-type approximation property for the primal variable, we prove a Cea estimate for the approximation error in canonical norms. Numerical results with uniform and adaptively refined meshes illustrate the performance of the scheme.