English

Gridded Transformer Neural Processes for Large Unstructured Spatio-Temporal Data

Machine Learning 2024-10-11 v2 Machine Learning

Abstract

Many important problems require modelling large-scale spatio-temporal datasets, with one prevalent example being weather forecasting. Recently, transformer-based approaches have shown great promise in a range of weather forecasting problems. However, these have mostly focused on gridded data sources, neglecting the wealth of unstructured, off-the-grid data from observational measurements such as those at weather stations. A promising family of models suitable for such tasks are neural processes (NPs), notably the family of transformer neural processes (TNPs). Although TNPs have shown promise on small spatio-temporal datasets, they are unable to scale to the quantities of data used by state-of-the-art weather and climate models. This limitation stems from their lack of efficient attention mechanisms. We address this shortcoming through the introduction of gridded pseudo-token TNPs which employ specialised encoders and decoders to handle unstructured observations and utilise a processor containing gridded pseudo-tokens that leverage efficient attention mechanisms. Our method consistently outperforms a range of strong baselines on various synthetic and real-world regression tasks involving large-scale data, while maintaining competitive computational efficiency. The real-life experiments are performed on weather data, demonstrating the potential of our approach to bring performance and computational benefits when applied at scale in a weather modelling pipeline.

Keywords

Cite

@article{arxiv.2410.06731,
  title  = {Gridded Transformer Neural Processes for Large Unstructured Spatio-Temporal Data},
  author = {Matthew Ashman and Cristiana Diaconu and Eric Langezaal and Adrian Weller and Richard E. Turner},
  journal= {arXiv preprint arXiv:2410.06731},
  year   = {2024}
}
R2 v1 2026-06-28T19:14:07.323Z