In the present study, to predict the transverse velocity field in the near-wake of laminar flow over a circular cylinder at the Reynolds numbers of 60 and 300, we construct neural networks with instantaneous wall pressures on the cylinder surface as the input variables. For the two-dimensional unsteady flow at (Formula presented.), a fully connected neural network (FCNN) is considered. On the other hand, for a three-dimensional unsteady flow at (Formula presented.) having spanwise variations, we employ two different convolutional neural networks based on an encoder–FCNN (CNN-F) or an encoder–decoder (CNN-D) structure. Numerical simulations are carried out for both Reynolds numbers to obtain instantaneous flow fields, from which the input and output datasets are generated for training these neural networks. At the Reynolds numbers considered, the neural networks constructed accurately predict the transverse velocity fields in the near-wake over the cylinder using the information of instantaneous wall pressures as the input variables. In addition, at (Formula presented.), it is observed that CNN-D shows a better prediction ability than CNN-F.
This research was supported by Basic Science Research Program through the National Research Foundation of Korea (NRF) funded by the Ministry of Education (2016R1D1A1B03932120). Additionally, this work was supported by Korea Ministry of Environment (MOE) as \u201cChemical Accident Advancement Project\u201d (No. 2022003620005/1485018894).
