Rbf-Pinn: Non-Fourier Positional Embedding in Physics-Informed Neural Networks
Abstract
While many recent Physics-Informed Neural Networks (PINNs) variants have had considerable success in solving Partial Differential Equations, the empirical benefits of feature mapping drawn from the broader Neural Representations research have been largely overlooked. We highlight the limitations of widely used Fourier-based feature mapping in certain situations and suggest the use of the conditionally positive definite Radial Basis Function. The empirical findings demonstrate the effectiveness of our approach across a variety of forward and inverse problem cases. Our method can be seamlessly integrated into coordinate-based input neural networks and contribute to the wider field of PINNs research.
Cite
Text
Zeng et al. "Rbf-Pinn: Non-Fourier Positional Embedding in Physics-Informed Neural Networks." ICLR 2024 Workshops: AI4DiffEqtnsInSci, 2024.Markdown
[Zeng et al. "Rbf-Pinn: Non-Fourier Positional Embedding in Physics-Informed Neural Networks." ICLR 2024 Workshops: AI4DiffEqtnsInSci, 2024.](https://mlanthology.org/iclrw/2024/zeng2024iclrw-rbfpinn/)BibTeX
@inproceedings{zeng2024iclrw-rbfpinn,
title = {{Rbf-Pinn: Non-Fourier Positional Embedding in Physics-Informed Neural Networks}},
author = {Zeng, Chengxi and Burghardt, Tilo and Gambaruto, Alberto M},
booktitle = {ICLR 2024 Workshops: AI4DiffEqtnsInSci},
year = {2024},
url = {https://mlanthology.org/iclrw/2024/zeng2024iclrw-rbfpinn/}
}