ENMA: Tokenwise Autoregression for Generative Neural PDE Operators
Koupaï, Armand Kassaï, Boudec, Lise Le, Serrano, Louis, Gallinari, Patrick
–arXiv.org Artificial Intelligence
Solving time-dependent parametric partial differential equations (PDEs) remains a fundamental challenge for neural solvers, particularly when generalizing across a wide range of physical parameters and dynamics. When data is uncertain or incomplete-as is often the case-a natural approach is to turn to generative models. We introduce ENMA, a generative neural operator designed to model spatio-temporal dynamics arising from physical phenomena. ENMA predicts future dynamics in a compressed latent space using a generative masked autoregressive transformer trained with flow matching loss, enabling tokenwise generation. Irregularly sampled spatial observations are encoded into uniform latent representations via attention mechanisms and further compressed through a spatio-temporal convolutional encoder. This allows ENMA to perform in-context learning at inference time by conditioning on either past states of the target trajectory or auxiliary context trajectories with similar dynamics. The result is a robust and adaptable framework that generalizes to new PDE regimes and supports one-shot surrogate modeling of time-dependent parametric PDEs.
arXiv.org Artificial Intelligence
Dec-12-2025
- Country:
- Europe (0.28)
- Genre:
- Research Report > New Finding (0.67)
- Technology:
- Information Technology > Artificial Intelligence
- Vision (1.00)
- Representation & Reasoning (1.00)
- Natural Language (0.88)
- Machine Learning
- Neural Networks > Deep Learning (0.93)
- Statistical Learning (0.67)
- Information Technology > Artificial Intelligence