A Residual Minimization approach for Nonlinear Partial Differential Equations set in Banach spaces

Abstract

In this work, we propose and analyze a residual-minimization strategy for the numerical solution of nonlinear PDEs posed in Banach spaces. Given a finite-dimensional trial space and a suitably enriched discrete test space (of higher dimension than the trial space), we approximate the solution by minimizing the variational residual in a discrete dual norm. This minimization is equivalent to a nonlinear saddle-point formulation for the discrete solution in the trial space together with a residual representative in the test space. The latter provides a natural a posteriori error estimator, enabling automatic mesh adaptivity. To solve the resulting nonlinear saddle-point problem, we propose a Newton iteration whose linearized saddle-point system is symmetric, thereby guaranteeing solvability at each step. We take the p-Laplacian as a model problem and support the theoretical developments with representative numerical experiments, using standard H1-conforming piecewise linear functions for the trial space, and lowest-order Crouzeix--Raviart functions for the test space.