Spectral-inspired Neural Operator for Data-efficient PDE Simulation in Physics-agnostic Regimes
- URL: http://arxiv.org/abs/2505.21573v1
- Date: Tue, 27 May 2025 07:25:13 GMT
- Title: Spectral-inspired Neural Operator for Data-efficient PDE Simulation in Physics-agnostic Regimes
- Authors: Han Wan, Rui Zhang, Hao Sun,
- Abstract summary: Partial equations (PDEs) govern evolution of various physical systems.<n>Classical numerical solvers require fine discretization and full knowledge of governing PDEs.<n>Data-driven neural PDE solvers mitigate these constraints by learning from data but demand large training.
- Score: 11.74789494197836
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Partial differential equations (PDEs) govern the spatiotemporal evolution of various physical systems. Classical numerical solvers, while accurate, require fine discretization and full knowledge of the governing PDEs, limiting their applicability when the physics is unknown or fast inference is required. Data-driven neural PDE solvers alleviate these constraints by learning from data but demand large training datasets and perform poorly in data-scarce regimes. Physics-aware methods mitigate data requirements by incorporating physical knowledge yet rely on known PDE terms or local numerical schemes, restricting their ability to handle unknown or globally coupled systems. In this work, we propose the Spectral-inspired Neural Operator (SINO), a novel framework that learns PDE operators from limited trajectories (as few as 2-5), without any known PDE terms. SINO operates in the frequency domain and introduces a Frequency-to-Vector module to learn spectral representations analogous to derivative multipliers. To model nonlinear physical interactions, we design a nonlinear operator block that includes a $\Pi$-Block with low-pass filtering to prevent aliasing. Finally, we introduce an operator distillation technique to distill the trained model for efficient inference. SINO achieves state-of-the-art results across multiple PDE benchmarks, demonstrating strong discretization invariance and robust generalization to out-of-distribution initial conditions. To our knowledge, SINO is the first physics-aware method capable of accurately simulating globally coupled systems (e.g., the Navier-Stokes equations) from limited data without any explicit PDE terms.
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