Bounding The Rademacher Complexity of Fourier Neural Operator

A Fourier neural operator (FNO) is one of the physics-inspired machine learning methods. In particular, it is a neural operator. In recent times, several types of neural operators have been developed, e.g., deep operator networks, GNO, and MWTO. Compared with other models, the FNO is computationally efficient and can learn nonlinear operators between function spaces independent of a certain finite basis. In this study, we investigated the bounding of the Rademacher complexity of the FNO based on specific group norms. Using capacity based on these norms, we bound the generalization error of the FNO model. In addition, we investigated the correlation between the empirical generalization error and the proposed capacity of FNO. Based on this investigation, we gained insight into the impact of the model architecture on the generalization error and estimated the amount of information about FNO models stored in various types of capacities.