Multiscale Modelling with Physics-informed Neural Network: from Large-scale Dynamics to Small-scale Predictions in Complex Systems

Multiscale phenomena manifest across various scientific domains, presenting a ubiquitous challenge in accurately and effectively predicting multiscale dynamics in complex systems. In this paper, a novel solving mode is proposed for characterizing multiscale dynamics through a decoupling method. By modelling large-scale dynamics independently and treating small-scale dynamics as a slaved system, a Spectral PINN is developed to approach the small-scale system in an orthogonal basis functional space. The effectiveness of the method is demonstrated through extensive numerical experiments, including one-dimensional Kuramot-Sivashinsky (KS) equation, two- and three-dimensional Navier-Stokes (NS) equations, showcasing its versatility in addressing problems of fluid dynamics. Furthermore, we also delve into the application of the proposed approach to more complex problems, including non-uniform meshes, complex geometries, large-scale data with noise, and high-dimensional small-scale dynamics. The discussions about these scenarios contribute to a comprehensive understanding of the method's capabilities and limitations. This novel decoupling approach simplifies the analysis and prediction of spatiotemporal systems, where large-scale data can be obtained with low computational demands, followed by Spectral PINNs for capturing small-scale dynamics with improved efficiency and accuracy.