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Main Authors: Xu, Qingsong, Bamber, Jonathan L, Thuerey, Nils, Boers, Niklas, Bates, Paul, Camps-Valls, Gustau, Shi, Yilei, Zhu, Xiao Xiang
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.21023
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author Xu, Qingsong
Bamber, Jonathan L
Thuerey, Nils
Boers, Niklas
Bates, Paul
Camps-Valls, Gustau
Shi, Yilei
Zhu, Xiao Xiang
author_facet Xu, Qingsong
Bamber, Jonathan L
Thuerey, Nils
Boers, Niklas
Bates, Paul
Camps-Valls, Gustau
Shi, Yilei
Zhu, Xiao Xiang
contents Accurate long-term forecasting of spatiotemporal dynamics remains a fundamental challenge across scientific and engineering domains. Existing machine learning methods often neglect governing physical laws and fail to quantify inherent uncertainties in spatiotemporal predictions. To address these challenges, we introduce a physics-consistent neural operator (PCNO) that enforces physical constraints by projecting surrogate model outputs onto function spaces satisfying predefined laws. A physics-consistent projection layer within PCNO efficiently computes mass and momentum conservation in Fourier space. Building upon deterministic predictions, we further propose a diffusion model-enhanced PCNO (DiffPCNO), which leverages a consistency model to quantify and mitigate uncertainties, thereby improving the accuracy and reliability of forecasts. PCNO and DiffPCNO achieve high-fidelity spatiotemporal predictions while preserving physical consistency and uncertainty across diverse systems and spatial resolutions, ranging from turbulent flow modeling to real-world flood/atmospheric forecasting. Our two-stage framework provides a robust and versatile approach for accurate, physically grounded, and uncertainty-aware spatiotemporal forecasting.
format Preprint
id arxiv_https___arxiv_org_abs_2510_21023
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Physically consistent and uncertainty-aware learning of spatiotemporal dynamics
Xu, Qingsong
Bamber, Jonathan L
Thuerey, Nils
Boers, Niklas
Bates, Paul
Camps-Valls, Gustau
Shi, Yilei
Zhu, Xiao Xiang
Machine Learning
Artificial Intelligence
Computational Physics
Accurate long-term forecasting of spatiotemporal dynamics remains a fundamental challenge across scientific and engineering domains. Existing machine learning methods often neglect governing physical laws and fail to quantify inherent uncertainties in spatiotemporal predictions. To address these challenges, we introduce a physics-consistent neural operator (PCNO) that enforces physical constraints by projecting surrogate model outputs onto function spaces satisfying predefined laws. A physics-consistent projection layer within PCNO efficiently computes mass and momentum conservation in Fourier space. Building upon deterministic predictions, we further propose a diffusion model-enhanced PCNO (DiffPCNO), which leverages a consistency model to quantify and mitigate uncertainties, thereby improving the accuracy and reliability of forecasts. PCNO and DiffPCNO achieve high-fidelity spatiotemporal predictions while preserving physical consistency and uncertainty across diverse systems and spatial resolutions, ranging from turbulent flow modeling to real-world flood/atmospheric forecasting. Our two-stage framework provides a robust and versatile approach for accurate, physically grounded, and uncertainty-aware spatiotemporal forecasting.
title Physically consistent and uncertainty-aware learning of spatiotemporal dynamics
topic Machine Learning
Artificial Intelligence
Computational Physics
url https://arxiv.org/abs/2510.21023