Latent Representation of Computational Fluid Dynamics Meshes and Application to Airfoil Aerodynamics

Mesh manipulation is central to computational fluid dynamics. However, creating appropriate computational meshes often involves substantial manual intervention that has to be repeated each time the target shape changes. To address this problem, we propose an autodecoder-based latent representation approach. Human prior knowledge is embedded into learned geometric patterns, which eliminates the need for further handcrafting. Furthermore, the resulting computational meshes are differentiable with respect to the model parameters, which makes it suitable for inclusion in end-to-end trainable pipelines. We apply the model on two-dimensional airfoils to demonstrate its ability to handle various tasks.

Latent Representation of Computational Fluid Dynamics Meshes and Application to Airfoil Aerodynamics

Ionic wind amplifier for energy-efficient air propulsion: Prototype design, development, and evaluation

Permeability sets the linear path instability of buoyancy-driven disks

The dynamics and timescales of static stall

Ionic wind amplifier for energy-efficient air propulsion: Prototype design, development, and evaluation

Permeability sets the linear path instability of buoyancy-driven disks

The dynamics and timescales of static stall