We present a framework for solving a broad class of ill-posed inverse problems governed by partial differential equations (PDEs), where the target coefficients of the forward operator are recovered through an iterative regularization scheme that alternates between FEM-based inversion and learned graph neural regularization. The forward problem is numerically solved using the finite element method (FEM), enabling applicability to a wide range of geometries and PDEs. By leveraging the graph structure inherent to FEM discretizations, we employ physics-inspired graph neural networks as learned regularizers, providing a robust, interpretable, and generalizable alternative to standard approaches. Numerical experiments demonstrate that our framework outperforms classical regularization techniques and achieves accurate reconstructions even in highly ill-posed scenarios.
@article{arxiv.2510.21012,
title = {Graph Neural Regularizers for PDE Inverse Problems},
author = {William Lauga and James Rowbottom and Alexander Denker and Željko Kereta and Moshe Eliasof and Carola-Bibiane Schönlieb},
journal= {arXiv preprint arXiv:2510.21012},
year = {2025}
}