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SVD-NO: Learning PDE Solution Operators with SVD Integral Kernels

Machine Learning 2025-11-14 v1

Abstract

Neural operators have emerged as a promising paradigm for learning solution operators of partial differential equa- tions (PDEs) directly from data. Existing methods, such as those based on Fourier or graph techniques, make strong as- sumptions about the structure of the kernel integral opera- tor, assumptions which may limit expressivity. We present SVD-NO, a neural operator that explicitly parameterizes the kernel by its singular-value decomposition (SVD) and then carries out the integral directly in the low-rank basis. Two lightweight networks learn the left and right singular func- tions, a diagonal parameter matrix learns the singular values, and a Gram-matrix regularizer enforces orthonormality. As SVD-NO approximates the full kernel, it obtains a high de- gree of expressivity. Furthermore, due to its low-rank struc- ture the computational complexity of applying the operator remains reasonable, leading to a practical system. In exten- sive evaluations on five diverse benchmark equations, SVD- NO achieves a new state of the art. In particular, SVD-NO provides greater performance gains on PDEs whose solutions are highly spatially variable. The code of this work is publicly available at https://github.com/2noamk/SVDNO.git.

Keywords

Cite

@article{arxiv.2511.10025,
  title  = {SVD-NO: Learning PDE Solution Operators with SVD Integral Kernels},
  author = {Noam Koren and Ralf J. J. Mackenbach and Ruud J. G. van Sloun and Kira Radinsky and Daniel Freedman},
  journal= {arXiv preprint arXiv:2511.10025},
  year   = {2025}
}

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