Stability Analysis of Physics-Informed Neural Networks via Variational Coercivity, Perturbation Bounds, and Concentration Estimates

Abstract

We develop a rigorous stability framework for Physics-Informed Neural Networks (PINNs) grounded in variational analysis, operator coercivity, and explicit perturbation theory. PINNs approximate solutions to partial differential equations (PDEs) by minimizing residual-based losses over sampled collocation points. We derive deterministic stability bounds that quantify how bounded perturbations in the network output propagate through both residual and supervised loss components. Probabilistic stability is established via McDiarmid's inequality, yielding non-asymptotic concentration bounds that link sampling variability to empirical loss fluctuations under minimal assumptions. Generalization from Sobolev-norm training loss to uniform approximation is analyzed using coercivity and Sobolev embeddings, leading to pointwise error control. The theoretical results apply to both scalar and vector-valued PDEs and cover composite loss formulations. Numerical experiments validate the perturbation sensitivity, sample complexity estimates, and Sobolev-to-uniform generalization bounds. This work provides a mathematically grounded and practically applicable stability framework for PINNs, clarifying the role of operator structure, sampling design, and functional regularity in robust training.

Tasks

Reproductions