A linear Uzawa-type solver for nonlinear transmission problems
Provides a more robust solver for nonlinear transmission problems in computational engineering, avoiding restrictive assumptions on material properties.
The paper proposes an Uzawa-type iteration for solving nonlinear transmission problems, achieving linear convergence without restrictions on ellipticity constants required by direct discretizations.
We propose an Uzawa-type iteration for the Johnson-Nédélec formulation of a Laplace-type transmission problem with possible (strongly monotone) nonlinearity in the interior domain. In each step, we sequentially solve one BEM for the weakly-singular integral equation associated with the Laplace-operator and one FEM for the linear Yukawa equation. In particular, the nonlinearity is only evaluated to build the right-hand side of the Yukawa equation. We prove that the proposed method leads to linear convergence with respect to the number of Uzawa iterations. Moreover, while the current analysis of a direct FEM-BEM discretization of the Johnson-Nédélec formulation requires some restrictions on the ellipticity (resp. strong monotonicity constant) in the interior domain, our Uzawa-type solver avoids such assumptions.