Zebra: In-Context and Generative Pretraining for Solving Parametric PDEs

Louis Serrano; Armand Kassaï Koupaï; Thomas X Wang; Pierre ERBACHER; Patrick Gallinari

Zebra: In-Context and Generative Pretraining for Solving Parametric PDEs

Louis Serrano, Armand Kassaï Koupaï, Thomas X Wang, Pierre ERBACHER, Patrick Gallinari

27 Sept 2024 (modified: 05 Feb 2025)Submitted to ICLR 2025EveryoneRevisionsBibTeXCC BY 4.0

Keywords: PDE, Adaptation, In-Context, Transformer, Vector-Quantization

TL;DR: Zebra is a generative auto-regressive transformer for solving parametric PDEs, leveraging in-context information to adapt to new dynamics.

Abstract: Solving time-dependent parametric partial differential equations (PDEs) is challenging, as models must adapt to variations in parameters such as coefficients, forcing terms, and boundary conditions. Data-driven neural solvers either train on data sampled from the PDE parameters distribution in the hope that the model generalizes to new instances or rely on gradient-based adaptation and meta-learning to implicitly encode the dynamics from observations. This often comes with increased inference complexity. Inspired by the in-context learning capabilities of large language models (LLMs), we introduce Zebra, a novel generative auto-regressive transformer designed to solve parametric PDEs without requiring gradient adaptation at inference. By leveraging in-context information during both pre-training and inference, Zebra dynamically adapts to new tasks by conditioning on input sequences that incorporate context trajectories or preceding states. This approach enables Zebra to flexibly handle arbitrarily sized context inputs and supports uncertainty quantification through the sampling of multiple solution trajectories. We evaluate Zebra across a variety of challenging PDE scenarios, demonstrating its adaptability, robustness, and superior performance compared to existing approaches.

Primary Area: applications to physical sciences (physics, chemistry, biology, etc.)

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Submission Number: 11340

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