U-WNO: U-Net Enhanced Wavelet Neural Operator for Solving Parametric Partial Differential Equations

Neural operators are effective tools for solving parametric partial differential equations (PDEs). They can predict solutions of PDEs with different initial and boundary conditions, as well as different input functions. The recently proposed Wavelet Neural Operator (WNO) utilizes the time-frequency localization of wavelets to capture spatial manifolds effectively. While WNO has shown promise as an operator learning method, it only parameterizes neural network weights under higher-order wavelet factorization. This approach avoids noise interference but may result in insufficient extraction of high-frequency features from the data. In this study, we propose a new network architecture called U-WNO. It incorporates the U-Net path and residual shortcut into the wavelet layer to enhance the extraction of high-frequency features and improve the learning of spatial manifolds. Additionally, we introduce the Adaptive Activation Function into the wavelet layer to address the spectral bias of the neural network. The effectiveness of U-WNO is demonstrated through numerical experiments on various problems, including the Burgers equation, Darcy flow, Navier-Stokes equation, Allen-Cahn equation, Non-homogeneous Poisson equation, and Wave advection equation. This study also includes a comparative analysis of existing operator learning frameworks.