Physics-Informed Machine Learning

Stabilizing PINNs: A regularization scheme for PINN training to avoid unstable fixed points of dynamical systems

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Abstract

It was recently shown that the loss function used for training physics-informed neural networks (PINNs) exhibits local minima at solutions corresponding to fixed points of dynamical systems. 
In the forward setting, where the PINN is trained to solve initial value problems, these local minima can interfere with training and potentially lead to physically incorrect solutions. 
Building on stability theory, this paper proposes a regularization scheme that penalizes solutions corresponding to unstable fixed points. Experimental results on four dynamical systems, including the Lotka-Volterra model and the van der Pol oscillator, show that our scheme helps avoiding physically incorrect solutions and substantially improves the training success rate of PINNs.

How to Cite:

Babić, M., Rohrhofer, F. & Geiger, B., (2026) “Stabilizing PINNs: A regularization scheme for PINN training to avoid unstable fixed points of dynamical systems”, Proceedings of the Austrian Symposium on AI, Robotics, and Vision 3(1), 128-136.