The paper introduces a framework for designing effective feature mapping functions in Physics-Informed Neural Networks (PINNs) and proposes Radial Basis Function (RBF)-based approaches. The authors demonstrate that their RBF feature mapping method not only enhances generalization across a range of forward and inverse physics problems but also surpasses other feature mapping methods by a substantial margin.
The key highlights and insights are:
The authors show the limitations and shortcomings of the widely used Fourier-based feature mappings in certain situations, such as the Gibbs phenomenon in the Burgers' equation and poor performance in high-dimensional problems.
They present a framework for designing feature mapping functions and introduce a conditionally positive definite Radial Basis Function (RBF). This method leverages the properties of RBFs to provide a more effective feature representation compared to Fourier-based approaches.
The empirical results demonstrate the effectiveness of the RBF feature mapping across a variety of forward and inverse problem cases, including time-dependent PDEs, nonlinear PDEs, and inverse problems. The RBF-based methods outperform other feature mapping techniques by a significant margin.
The authors also conduct ablation studies on the number of RBFs, the number of polynomials, and different types of RBFs, providing insights into the design choices for the feature mapping layer.
The RBF feature mapping has the potential to be compatible with various other PINN techniques, including novel activation functions, loss functions, or training strategies, and can be extended to other coordinate-based input neural networks for different tasks.
다른 언어로
소스 콘텐츠 기반
arxiv.org
더 깊은 질문