A convolutional neural network-based model for reconstructing free surface flow fields

This paper introduces hydrological computational fluid dynamics model (HydroCFD), a deep learning model based on the convolutional neural network U-Net framework designed for reconstructing free surface flow fields. With well-posed boundary and initial conditions, the model rapidly generates a result that approximates the two-dimensional (2D) shallow water equations, significantly improving the efficiency of obtaining free surface flow fields compared to traditional computational fluid dynamics methods. The framework features an input layer that integrates water depth and terrain (hydrological element variables), and incorporates a new loss function, coefficient of variation loss function (CVLoss), based on the variation coefficient to improve accuracy and stability. HydroCFD is trained and validated on two different datasets, open channel flows with a groin, and with an abrupt expansion. Error analysis demonstrated that HydroCFD achieves high precision in reconstructing 2D free surface flow fields. Furthermore, a comparison of six different loss functions reveals that CVLoss contributes to improved accuracy and computational stability.