English

PAINT: Parallel-in-time Neural Twins for Dynamical System Reconstruction

Artificial Intelligence 2026-02-04 v2 Fluid Dynamics

Abstract

Neural surrogates have shown great potential in simulating dynamical systems, while offering real-time capabilities. We envision Neural Twins as a progression of neural surrogates, aiming to create digital replicas of real systems. A neural twin consumes measurements at test time to update its state, thereby enabling context-specific decision-making. We argue, that a critical property of neural twins is their ability to remain on-trajectory, i.e., to stay close to the true system state over time. We introduce Parallel-in-time Neural Twins (PAINT), an architecture-agnostic family of methods for modeling dynamical systems from measurements. PAINT trains a generative neural network to model the distribution of states in parallel over time. At test time, states are predicted from measurements in a sliding window fashion. Our theoretical analysis shows that PAINT is on-trajectory, whereas autoregressive models generally are not. Empirically, we evaluate our method on a challenging two-dimensional turbulent fluid dynamics problem. The results demonstrate that PAINT stays on-trajectory and predicts system states from sparse measurements with high fidelity. These findings underscore PAINT's potential for developing neural twins that stay on-trajectory, enabling more accurate state estimation and decision-making.

Keywords

Cite

@article{arxiv.2510.16004,
  title  = {PAINT: Parallel-in-time Neural Twins for Dynamical System Reconstruction},
  author = {Andreas Radler and Vincent Seyfried and Johannes Brandstetter and Thomas Lichtenegger},
  journal= {arXiv preprint arXiv:2510.16004},
  year   = {2026}
}

Comments

28 pages, 23 figures

R2 v1 2026-07-01T06:43:58.332Z