English

DiffObs: Generative Diffusion for Global Forecasting of Satellite Observations

Computational Physics 2024-04-11 v1 Computer Vision and Pattern Recognition Machine Learning Atmospheric and Oceanic Physics Machine Learning

Abstract

This work presents an autoregressive generative diffusion model (DiffObs) to predict the global evolution of daily precipitation, trained on a satellite observational product, and assessed with domain-specific diagnostics. The model is trained to probabilistically forecast day-ahead precipitation. Nonetheless, it is stable for multi-month rollouts, which reveal a qualitatively realistic superposition of convectively coupled wave modes in the tropics. Cross-spectral analysis confirms successful generation of low frequency variations associated with the Madden--Julian oscillation, which regulates most subseasonal to seasonal predictability in the observed atmosphere, and convectively coupled moist Kelvin waves with approximately correct dispersion relationships. Despite secondary issues and biases, the results affirm the potential for a next generation of global diffusion models trained on increasingly sparse, and increasingly direct and differentiated observations of the world, for practical applications in subseasonal and climate prediction.

Keywords

Cite

@article{arxiv.2404.06517,
  title  = {DiffObs: Generative Diffusion for Global Forecasting of Satellite Observations},
  author = {Jason Stock and Jaideep Pathak and Yair Cohen and Mike Pritchard and Piyush Garg and Dale Durran and Morteza Mardani and Noah Brenowitz},
  journal= {arXiv preprint arXiv:2404.06517},
  year   = {2024}
}

Comments

Published as a workshop paper at "Tackling Climate Change with Machine Learning", ICLR 2024

R2 v1 2026-06-28T15:49:09.012Z