Classical hydrodynamic lubrication simulation solves Reynolds equation to unveil the lubrication pressure and film thickness distributions, yet it overlooks the latent high-level representations buried beneath the lubrication data. While deep learning has illustrated that the mining of high-level representations helps to generate desired outputs from input prompts, the lubrication research, however, has not fully exploited generative deep learning in lubrication prediction and generation. Here, we propose to adopt a deconvolutional neural network to learn the latent representations in hydrodynamic lubrication data and directly generate 2D lubrication scenario from the given working condition without solving any governing equation. Compared to classical method, our approach can output the distribution of lubrication pressure and film thickness in less than 0.1 s on a personal computer and be extended to more complicated scenarios including cavitation.
Zhao et al. (Sun,) studied this question.