SPIKE: Sparse Koopman Regularization for Physics-Informed Neural Networks

Jose Marie Antonio Miñoza

SPIKE: Sparse Koopman Regularization for Physics-Informed Neural Networks

Jose Marie Antonio Miñoza

Published: 22 Jan 2026, Last Modified: 06 Mar 2026CPAL 2026 (Proceedings Track) PosterEveryoneRevisionsBibTeXCC BY 4.0

Keywords: Physics-Informed Neural Networks, Koopman Operator, Out-Of-Distribution Generalization, Dynamical Systems

TL;DR: Sparse Koopman regularization enables PINNs to generalize beyond training domains, achieving 184 times longer predictions on chaotic systems and orders-of-magnitude improvement on stiff PDEs.

Abstract: Physics-Informed Neural Networks (PINNs) provide a mesh-free approach for solving differential equations by embedding physical constraints into neural network training. However, PINNs tend to overfit within the training domain, leading to poor generalization when extrapolating beyond trained spatiotemporal regions. This work presents SPIKE (Sparse Physics-Informed Koopman-Enhanced), a framework that regularizes PINNs with continuous-time Koopman operators to learn parsimonious dynamics representations. By enforcing linear dynamics $dz/dt = Az$ in a learned observable space, both PIKE (without explicit sparsity) and SPIKE (with L1 regularization on $A$) learn sparse generator matrices, embodying the parsimony principle that complex dynamics admit low-dimensional structure. Experiments across parabolic, hyperbolic, dispersive, and stiff PDEs, including fluid dynamics (Navier-Stokes) and chaotic ODEs (Lorenz), demonstrate consistent improvements in temporal extrapolation, spatial generalization, and long-term prediction accuracy. The continuous-time formulation with matrix exponential integration provides unconditional stability for stiff systems while avoiding diagonal dominance issues inherent in discrete-time Koopman operators.

Submission Number: 108

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