A BEM Adjoint-Based Differentiable Shape Optimization of a Stealth Aircraft

A BEM Adjoint-Based Differentiable Shape Optimization of a Stealth Aircraft

Modern fighter aircraft have an increasing need for at least a moderate level of stealth, and the shape design must bear a part of this constraint. However, the high frequency of close range radar makes high-fidelity radar cross-section computation methods such as the boundary element method too exp...

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Bibliographic Details
Main Authors: Charles Thoulon, Gilbert Roge, Olivier Pironneau
Format: Article
Language:English
Published: MDPI AG 2025-07-01
Series:Eng
Subjects:
shape optimization
gradient-based
CAD-based
method of moments
boundary elements method
high fidelity optimization
Online Access:https://www.mdpi.com/2673-4117/6/7/147
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Summary:Modern fighter aircraft have an increasing need for at least a moderate level of stealth, and the shape design must bear a part of this constraint. However, the high frequency of close range radar makes high-fidelity radar cross-section computation methods such as the boundary element method too expensive to use in a gradient-free optimization process. On the other hand, asymptotic methods are not able to accurately predict the RCS of complex shapes such as intake cavities. Hence, the need arises for efficient and accurate methods to compute the gradient of high-fidelity radar cross-section computation methods with respect to shape parameters. In this paper, we propose an adjoint formulation for the boundary element method to efficiently compute these gradients. We present a novel approach to calculate the gradient of high-fidelity radar cross-section computations using the boundary element method. Our method employs an adjoint formulation that allows for the efficient computation of these gradients. This is particularly beneficial in shape optimization problems where accurate and efficient methods are crucial to designing modern fighter aircraft with stealth capabilities. By avoiding the need for solving the actual adjoint problem in certain cases, our formulation provides a more streamlined solution while still maintaining high accuracy. We demonstrate the effectiveness of our method by performing shape optimization on various shapes, including simple geometries like spheres and ellipsoids, as well as complex aircraft shapes with multiple variables.
ISSN:2673-4117

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