Robust Moment Identification for Nonlinear PDEs via a Neural ODE Approach
- URL: http://arxiv.org/abs/2506.05245v1
- Date: Thu, 05 Jun 2025 17:03:42 GMT
- Title: Robust Moment Identification for Nonlinear PDEs via a Neural ODE Approach
- Authors: Shaoxuan Chen, Su Yang, Panayotis G. Kevrekidis, Wei Zhu,
- Abstract summary: We propose a data-driven framework for learning reduced-order moment dynamics from PDE-governed systems using Neural ODEs.<n>Using as an application platform the nonlinear Schr"odinger equation, the framework accurately recovers governing moment dynamics when closure is available.
- Score: 7.097168937001958
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: We propose a data-driven framework for learning reduced-order moment dynamics from PDE-governed systems using Neural ODEs. In contrast to derivative-based methods like SINDy, which necessitate densely sampled data and are sensitive to noise, our approach based on Neural ODEs directly models moment trajectories, enabling robust learning from sparse and potentially irregular time series. Using as an application platform the nonlinear Schr\"{o}dinger equation, the framework accurately recovers governing moment dynamics when closure is available, even with limited and irregular observations. For systems without analytical closure, we introduce a data-driven coordinate transformation strategy based on Stiefel manifold optimization, enabling the discovery of low-dimensional representations in which the moment dynamics become closed, facilitating interpretable and reliable modeling. We also explore cases where a closure model is not known, such as a Fisher-KPP reaction-diffusion system. Here we demonstrate that Neural ODEs can still effectively approximate the unclosed moment dynamics and achieve superior extrapolation accuracy compared to physical-expert-derived ODE models. This advantage remains robust even under sparse and irregular sampling, highlighting the method's robustness in data-limited settings. Our results highlight the Neural ODE framework as a powerful and flexible tool for learning interpretable, low-dimensional moment dynamics in complex PDE-governed systems.
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