Deep Learning for Real-Time Aerodynamic Evaluations of Arbitrary Vehicle Shapes

TL;DR

This paper demonstrates that deep learning models can accurately predict aerodynamic drag for arbitrary vehicle shapes without explicit parameterization, enabling more flexible and efficient vehicle design processes.

Contribution

The study introduces a modified U-Net architecture using Signed Distance Fields to predict drag coefficients for arbitrary geometries, outperforming existing models by at least 11% in accuracy.

Findings

Deep learning models outperform existing models by at least 11% in accuracy.

Models can predict velocity fields and drag coefficient simultaneously.

Simple data augmentation improves prediction results.

Abstract

The aerodynamic optimization process of cars requires multiple iterations between aerodynamicists and stylists. Response Surface Modeling and Reduced-Order Modeling are commonly used to eliminate the overhead due to Computational Fluid Dynamics, leading to faster iterations. However, a primary drawback of these models is that they can work only on the parametrized geometric features they were trained with. This study evaluates if deep learning models can predict the drag coefficient for an arbitrary input geometry without explicit parameterization. We use two similar data sets based on the publicly available DrivAer geometry for training. We use a modified U-Net architecture that uses Signed Distance Fields to represent the input geometries. Our models outperform the existing models by at least 11% in prediction accuracy for the drag coefficient. We achieved this improvement by combining multiple data sets that were created using different parameterizations, which is not possible with the methods currently used. We have also shown that it is possible to predict velocity fields and drag coefficient concurrently and that simple data augmentation methods can improve the results. In addition, we have performed an occlusion sensitivity study on our models to understand what information is used to make predictions. From the occlusion sensitivity study, we showed that the models were able to identify the geometric features and have discovered that the model has learned to exploit the global information present in the SDF. In contrast to the currently operational method, where design changes are restricted to the initially defined parameters, this study brings surrogate models one step closer to the long-term goal of having a model that can be used for approximate aerodynamic evaluation of unseen, arbitrary vehicle shapes, thereby providing complete design freedom to the vehicle stylists.