English

Large Airfoil Models

Fluid Dynamics 2025-03-18 v4

Abstract

The development of a Large Airfoil Model (LAM), a transformative approach for answering technical questions on airfoil aerodynamics, requires a vast dataset and a model to leverage it. To build this foundation, a novel probabilistic machine learning approach, A Deep Airfoil Prediction Tool (ADAPT), has been developed. ADAPT makes uncertainty-aware predictions of airfoil pressure coefficient (CpC_p) distributions by harnessing experimental data and incorporating measurement uncertainties. By employing deep kernel learning, performing Gaussian Process Regression in a ten-dimensional latent space learned by a neural network, ADAPT effectively handles unstructured experimental datasets. In tandem, Airfoil Surface Pressure Information Repository of Experiments (ASPIRE), the first large-scale, open-source repository of airfoil experimental data has been developed. ASPIRE integrates century-old historical data with modern reports, forming an unparalleled resource of real-world pressure measurements. This addresses a critical gap left by prior repositories, which relied primarily on numerical simulations. Demonstrative results for three airfoils show that ADAPT accurately predicts CpC_p distributions and aerodynamic coefficients across varied flow conditions, achieving a mean absolute error in enclosed area (MAEenclosed\text{MAE}_\text{enclosed}) of 0.029. ASPIRE and ADAPT lay the foundation for an interactive airfoil analysis tool driven by a large language model, enabling users to perform design tasks based on natural language questions rather than explicit technical input.

Keywords

Cite

@article{arxiv.2410.08392,
  title  = {Large Airfoil Models},
  author = {Howon Lee and Aanchal Save and Pranay Seshadri and Juergen Rauleder},
  journal= {arXiv preprint arXiv:2410.08392},
  year   = {2025}
}
R2 v1 2026-06-28T19:17:10.614Z