Aerodynamic Shape Optimization Using Reinforcement Learning

Yiğit Saygılı; Baha Zafer; Sadık Yetkin

doi:10.1007/978-3-031-98565-2_70

Aerodynamic Shape Optimization Using Reinforcement Learning

Yiğit Saygılı^*, Baha Zafer, Sadık Yetkin

^*Corresponding author for this work

Department of Aeronautical Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Aerodynamic shape optimization is the process of designing and improving an object's external geometry to enhance its aerodynamic efficiency. Traditional approaches rely on viscous or inviscid flow simulations coupled with mathematical optimization algorithms to generate efficient designs in terms of aerodynamics, based on the sampling methods. This study focuses on developing a reinforcement learning based optimization algorithm for aerodynamic shape optimization, leveraging reinforcement learning (RL) and supervised machine learning techniques. Specifically, Proximal Policy Optimization (PPO), and XGBoost are employed to optimize the airfoil geometry. The primary objective is to maximize the aerodynamic efficiency, specifically the lift-to-drag ratio, of a two-dimensional airfoil by modifying its upper and lower surface geometries. The optimization process is driven by an RL agent and a machine learning model, which learn the relationship between geometric modifications and aerodynamic efficiency through iterative interactions with the flow solver. A key novelty of this work lies in the direct comparison of PPO, and XGBoost for aerodynamic shape optimization, as no prior studies have systematically evaluated these algorithms in this context. By exploring and exploiting optimal shape variations, the proposed machine learning based framework aims to achieve superior aerodynamic performance while minimizing computational cost.

Original language	English
Title of host publication	Intelligent and Fuzzy Systems - Artificial Intelligence in Human-Centric, Resilient and Sustainable Industries, Proceedings of the INFUS 2025 Conference
Editors	Cengiz Kahraman, Selcuk Cebi, Basar Oztaysi, Sezi Cevik Onar, Cagri Tolga, Irem Ucal Sari, Irem Otay
Publisher	Springer Science and Business Media Deutschland GmbH
Pages	648-656
Number of pages	9
ISBN (Print)	9783031985645
DOIs	https://doi.org/10.1007/978-3-031-98565-2_70
Publication status	Published - 2025
Event	7th International Conference on Intelligent and Fuzzy Systems, INFUS 2025 - Istanbul, Turkey Duration: 29 Jul 2025 → 31 Jul 2025

Publication series

Name	Lecture Notes in Networks and Systems
Volume	1530 LNNS
ISSN (Print)	2367-3370
ISSN (Electronic)	2367-3389

Conference

Conference	7th International Conference on Intelligent and Fuzzy Systems, INFUS 2025
Country/Territory	Turkey
City	Istanbul
Period	29/07/25 → 31/07/25

Bibliographical note

Publisher Copyright:
© The Author(s), under exclusive license to Springer Nature Switzerland AG 2025.

Keywords

Aerodynamics
Airfoil
Machine Learning
Optimization
Reinforcement Learning

Access to Document

10.1007/978-3-031-98565-2_70

Cite this

Saygılı, Y., Zafer, B., & Yetkin, S. (2025). Aerodynamic Shape Optimization Using Reinforcement Learning. In C. Kahraman, S. Cebi, B. Oztaysi, S. Cevik Onar, C. Tolga, I. Ucal Sari, & I. Otay (Eds.), Intelligent and Fuzzy Systems - Artificial Intelligence in Human-Centric, Resilient and Sustainable Industries, Proceedings of the INFUS 2025 Conference (pp. 648-656). (Lecture Notes in Networks and Systems; Vol. 1530 LNNS). Springer Science and Business Media Deutschland GmbH. https://doi.org/10.1007/978-3-031-98565-2_70

Saygılı, Yiğit ; Zafer, Baha ; Yetkin, Sadık. / Aerodynamic Shape Optimization Using Reinforcement Learning. Intelligent and Fuzzy Systems - Artificial Intelligence in Human-Centric, Resilient and Sustainable Industries, Proceedings of the INFUS 2025 Conference. editor / Cengiz Kahraman ; Selcuk Cebi ; Basar Oztaysi ; Sezi Cevik Onar ; Cagri Tolga ; Irem Ucal Sari ; Irem Otay. Springer Science and Business Media Deutschland GmbH, 2025. pp. 648-656 (Lecture Notes in Networks and Systems).

@inproceedings{071668bb727c4ea6ab3b0acabcaba540,

title = "Aerodynamic Shape Optimization Using Reinforcement Learning",

abstract = "Aerodynamic shape optimization is the process of designing and improving an object's external geometry to enhance its aerodynamic efficiency. Traditional approaches rely on viscous or inviscid flow simulations coupled with mathematical optimization algorithms to generate efficient designs in terms of aerodynamics, based on the sampling methods. This study focuses on developing a reinforcement learning based optimization algorithm for aerodynamic shape optimization, leveraging reinforcement learning (RL) and supervised machine learning techniques. Specifically, Proximal Policy Optimization (PPO), and XGBoost are employed to optimize the airfoil geometry. The primary objective is to maximize the aerodynamic efficiency, specifically the lift-to-drag ratio, of a two-dimensional airfoil by modifying its upper and lower surface geometries. The optimization process is driven by an RL agent and a machine learning model, which learn the relationship between geometric modifications and aerodynamic efficiency through iterative interactions with the flow solver. A key novelty of this work lies in the direct comparison of PPO, and XGBoost for aerodynamic shape optimization, as no prior studies have systematically evaluated these algorithms in this context. By exploring and exploiting optimal shape variations, the proposed machine learning based framework aims to achieve superior aerodynamic performance while minimizing computational cost.",

keywords = "Aerodynamics, Airfoil, Machine Learning, Optimization, Reinforcement Learning",

author = "Yiğit Saygılı and Baha Zafer and Sadık Yetkin",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive license to Springer Nature Switzerland AG 2025.; 7th International Conference on Intelligent and Fuzzy Systems, INFUS 2025 ; Conference date: 29-07-2025 Through 31-07-2025",

year = "2025",

doi = "10.1007/978-3-031-98565-2\_70",

language = "English",

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series = "Lecture Notes in Networks and Systems",

publisher = "Springer Science and Business Media Deutschland GmbH",

pages = "648--656",

editor = "Cengiz Kahraman and Selcuk Cebi and Basar Oztaysi and \{Cevik Onar\}, Sezi and Cagri Tolga and \{Ucal Sari\}, Irem and Irem Otay",

booktitle = "Intelligent and Fuzzy Systems - Artificial Intelligence in Human-Centric, Resilient and Sustainable Industries, Proceedings of the INFUS 2025 Conference",

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Saygılı, Y, Zafer, B & Yetkin, S 2025, Aerodynamic Shape Optimization Using Reinforcement Learning. in C Kahraman, S Cebi, B Oztaysi, S Cevik Onar, C Tolga, I Ucal Sari & I Otay (eds), Intelligent and Fuzzy Systems - Artificial Intelligence in Human-Centric, Resilient and Sustainable Industries, Proceedings of the INFUS 2025 Conference. Lecture Notes in Networks and Systems, vol. 1530 LNNS, Springer Science and Business Media Deutschland GmbH, pp. 648-656, 7th International Conference on Intelligent and Fuzzy Systems, INFUS 2025, Istanbul, Turkey, 29/07/25. https://doi.org/10.1007/978-3-031-98565-2_70

Aerodynamic Shape Optimization Using Reinforcement Learning. / Saygılı, Yiğit; Zafer, Baha; Yetkin, Sadık.
Intelligent and Fuzzy Systems - Artificial Intelligence in Human-Centric, Resilient and Sustainable Industries, Proceedings of the INFUS 2025 Conference. ed. / Cengiz Kahraman; Selcuk Cebi; Basar Oztaysi; Sezi Cevik Onar; Cagri Tolga; Irem Ucal Sari; Irem Otay. Springer Science and Business Media Deutschland GmbH, 2025. p. 648-656 (Lecture Notes in Networks and Systems; Vol. 1530 LNNS).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Aerodynamic Shape Optimization Using Reinforcement Learning

AU - Saygılı, Yiğit

AU - Zafer, Baha

AU - Yetkin, Sadık

N1 - Publisher Copyright: © The Author(s), under exclusive license to Springer Nature Switzerland AG 2025.

PY - 2025

Y1 - 2025

N2 - Aerodynamic shape optimization is the process of designing and improving an object's external geometry to enhance its aerodynamic efficiency. Traditional approaches rely on viscous or inviscid flow simulations coupled with mathematical optimization algorithms to generate efficient designs in terms of aerodynamics, based on the sampling methods. This study focuses on developing a reinforcement learning based optimization algorithm for aerodynamic shape optimization, leveraging reinforcement learning (RL) and supervised machine learning techniques. Specifically, Proximal Policy Optimization (PPO), and XGBoost are employed to optimize the airfoil geometry. The primary objective is to maximize the aerodynamic efficiency, specifically the lift-to-drag ratio, of a two-dimensional airfoil by modifying its upper and lower surface geometries. The optimization process is driven by an RL agent and a machine learning model, which learn the relationship between geometric modifications and aerodynamic efficiency through iterative interactions with the flow solver. A key novelty of this work lies in the direct comparison of PPO, and XGBoost for aerodynamic shape optimization, as no prior studies have systematically evaluated these algorithms in this context. By exploring and exploiting optimal shape variations, the proposed machine learning based framework aims to achieve superior aerodynamic performance while minimizing computational cost.

AB - Aerodynamic shape optimization is the process of designing and improving an object's external geometry to enhance its aerodynamic efficiency. Traditional approaches rely on viscous or inviscid flow simulations coupled with mathematical optimization algorithms to generate efficient designs in terms of aerodynamics, based on the sampling methods. This study focuses on developing a reinforcement learning based optimization algorithm for aerodynamic shape optimization, leveraging reinforcement learning (RL) and supervised machine learning techniques. Specifically, Proximal Policy Optimization (PPO), and XGBoost are employed to optimize the airfoil geometry. The primary objective is to maximize the aerodynamic efficiency, specifically the lift-to-drag ratio, of a two-dimensional airfoil by modifying its upper and lower surface geometries. The optimization process is driven by an RL agent and a machine learning model, which learn the relationship between geometric modifications and aerodynamic efficiency through iterative interactions with the flow solver. A key novelty of this work lies in the direct comparison of PPO, and XGBoost for aerodynamic shape optimization, as no prior studies have systematically evaluated these algorithms in this context. By exploring and exploiting optimal shape variations, the proposed machine learning based framework aims to achieve superior aerodynamic performance while minimizing computational cost.

KW - Aerodynamics

KW - Airfoil

KW - Machine Learning

KW - Optimization

KW - Reinforcement Learning

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DO - 10.1007/978-3-031-98565-2_70

M3 - Conference contribution

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SN - 9783031985645

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BT - Intelligent and Fuzzy Systems - Artificial Intelligence in Human-Centric, Resilient and Sustainable Industries, Proceedings of the INFUS 2025 Conference

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A2 - Cebi, Selcuk

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A2 - Cevik Onar, Sezi

A2 - Tolga, Cagri

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Saygılı Y, Zafer B, Yetkin S. Aerodynamic Shape Optimization Using Reinforcement Learning. In Kahraman C, Cebi S, Oztaysi B, Cevik Onar S, Tolga C, Ucal Sari I, Otay I, editors, Intelligent and Fuzzy Systems - Artificial Intelligence in Human-Centric, Resilient and Sustainable Industries, Proceedings of the INFUS 2025 Conference. Springer Science and Business Media Deutschland GmbH. 2025. p. 648-656. (Lecture Notes in Networks and Systems). doi: 10.1007/978-3-031-98565-2_70

Aerodynamic Shape Optimization Using Reinforcement Learning

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Keywords

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