English

Predicting partially observable dynamical systems via diffusion models with a multiscale inference scheme

Machine Learning 2025-11-25 v1 Solar and Stellar Astrophysics Artificial Intelligence Machine Learning

Abstract

Conditional diffusion models provide a natural framework for probabilistic prediction of dynamical systems and have been successfully applied to fluid dynamics and weather prediction. However, in many settings, the available information at a given time represents only a small fraction of what is needed to predict future states, either due to measurement uncertainty or because only a small fraction of the state can be observed. This is true for example in solar physics, where we can observe the Sun's surface and atmosphere, but its evolution is driven by internal processes for which we lack direct measurements. In this paper, we tackle the probabilistic prediction of partially observable, long-memory dynamical systems, with applications to solar dynamics and the evolution of active regions. We show that standard inference schemes, such as autoregressive rollouts, fail to capture long-range dependencies in the data, largely because they do not integrate past information effectively. To overcome this, we propose a multiscale inference scheme for diffusion models, tailored to physical processes. Our method generates trajectories that are temporally fine-grained near the present and coarser as we move farther away, which enables capturing long-range temporal dependencies without increasing computational cost. When integrated into a diffusion model, we show that our inference scheme significantly reduces the bias of the predicted distributions and improves rollout stability.

Keywords

Cite

@article{arxiv.2511.19390,
  title  = {Predicting partially observable dynamical systems via diffusion models with a multiscale inference scheme},
  author = {Rudy Morel and Francesco Pio Ramunno and Jeff Shen and Alberto Bietti and Kyunghyun Cho and Miles Cranmer and Siavash Golkar and Olexandr Gugnin and Geraud Krawezik and Tanya Marwah and Michael McCabe and Lucas Meyer and Payel Mukhopadhyay and Ruben Ohana and Liam Parker and Helen Qu and François Rozet and K. D. Leka and François Lanusse and David Fouhey and Shirley Ho},
  journal= {arXiv preprint arXiv:2511.19390},
  year   = {2025}
}
R2 v1 2026-07-01T07:52:40.053Z