Litcius/Paper detail

Learning the Aerodynamic Design of Supercritical Airfoils Through Deep Reinforcement Learning

Runze Li, Yufei Zhang, Haixin Chen

2021AIAA Journal69 citationsDOIOpen Access PDF

Abstract

The aerodynamic design of modern civil aircraft requires a true sense of intelligence since it requires a good understanding of transonic aerodynamics and sufficient experience. Reinforcement learning is an artificial general intelligence that can learn sophisticated skills by trial and error, rather than by simply extracting features or making predictions from data. The present paper uses a deep reinforcement-learning algorithm to learn the policy for reducing the aerodynamic drag of supercritical airfoils. The policy is designed to take actions based on features of the wall Mach number distribution so that the learned policy can be more general. The initial policy for reinforcement learning is pretrained through imitation learning, and the result is compared with randomly generated initial policies. The policy is then trained in environments based on surrogate models, of which the mean drag reduction of 200 airfoils can be effectively improved by reinforcement learning. The policy is also tested by multiple airfoils in different flow conditions using computational fluid dynamics calculations. The results show that the policy is effective in both the training condition and other similar conditions, and the policy can be applied repeatedly to achieve greater drag reduction.

Topics & Concepts

AirfoilAerodynamicsReinforcement learningTransonicComputer scienceMach numberDragImitationReduction (mathematics)Computational fluid dynamicsEngineeringLift-to-drag ratioFlow (mathematics)ReinforcementArtificial intelligenceSurrogate modelFlow separationSimulationAerospace engineeringAerodynamic forceDrag coefficientModel Reduction and Neural NetworksPlasma and Flow Control in AerodynamicsBiomimetic flight and propulsion mechanisms