A penalized {\phi}-FEM scheme for the Poisson Dirichlet problem

TL;DR

This paper introduces a penalized {\

Contribution

It proposes a new penalized {\

Findings

Optimal convergence in H1 semi-norm

Quasi-optimal convergence in L2 norm

Validated through numerical experiments

Abstract

In this work, we analyze a penalized variant of the {\phi}-FEM scheme for the Poisson equation with Dirichlet boundary conditions. The {\phi}-FEM is a recently introduced unfitted finite element method based on a level-set description of the geometry, which avoids the need for boundary-fitted meshes. Unlike the original {\phi}-FEM formulation, the method proposed here enforces boundary conditions through a penalization term. This approach has the advantage that the level-set function is required only on the cells adjacent to the boundary in the variational formulation. The scheme is stabilized using a ghost penalty technique. We derive a priori error estimates, showing optimal convergence in the H1 semi-norm and quasi-optimal convergence in the L2 norm under suitable regularity assumptions. Numerical experiments are presented to validate the theoretical results and to compare the proposed method with both the original {\phi}-FEM and the standard fitted finite element method.