基于深度学习的飞行器外形快速生成

doi:10.7527/S1000-6893.2025.31614

Abstract

Abstract:

Aerodynamic configuration design technology for aircraft is one of the critical research directions for developing advanced aircraft and achieving generational leaps in performance. Traditional aerodynamic layout design faces challenges such as difficulties in selecting aerodynamic configurations and over-reliance on designer’s experience. Moreover， current aerodynamic shape parameterization methods struggle to break through pre-defined aerodynamic configuration schemes， limiting optimization to adjusting parameters within the same aerodynamic configuration during the design process. This necessitates repeated iterations and optimizations by designers， leading to prolonged design cycles and difficulties in obtaining optimal aerodynamic shapes， thereby hindering efficient and rapid scheme evaluation. This paper proposes and develops an image-based aircraft shape generation framework， employing deep marching tetrahedra methods and differentiable renderers. Leveraging the powerful nonlinear fitting capabilities of neural networks， this framework achieves rapid and intelligent generation of aerodynamic shapes. The generated aircraft surfaces are smooth， high-resolution， and controllable in dimensional envelope， offering engineering usability without the need for denoising operations.

Key words: aerodynamic configuration of aircraft, rapid generation, deep learning, lifting-body, generator, checker

CLC Number:

V221.3

Yonghai WANG, Haoge LI, Jiaxin LI, Yi DUAN, Chuan TIAN, Lingxi GUO, Xusheng WU. Rapid aircraft shape generation based on deep learning[J]. Acta Aeronautica et Astronautica Sinica, 2025, 46(10): 631614.

Figures/Tables 20

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高度/km	马赫数	攻角/（°）	侧滑角/（°）
10	5	-5，-2，0，2，5	0
45	8	0，5，7，10	0

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Rapid aircraft shape generation based on deep learning

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飞行器表面网格量（10⁴）	生成速度/（个·min^-1）
1	82
3	45
5	33
7	20