水准点(测量)
双稳态
透视图(图形)
多目标优化
优化设计
复合数
数学优化
替代模型
计算机科学
点(几何)
样品(材料)
控制工程
最优控制
最优化问题
悬挂(拓扑)
适应性
实验设计
线性规划
帕累托原理
工程设计过程
控制理论(社会学)
转化(遗传学)
计算
工程类
启发式
半径
内点法
选择(遗传算法)
约束优化
可控性
适应(眼睛)
模拟
汽车工业
工程优化
遗传算法
一体化设计
拓扑优化
机械工程
最小重量
设计方法
作者
Jiang-Bo Bai,Fei-Yan You,Tian-Wei Liu,Nicholas Fantuzzi,Jiarong Ge
出处
期刊:AIAA Journal
[American Institute of Aeronautics and Astronautics]
日期:2025-06-02
卷期号:63 (9): 3737-3751
摘要
Bistable deployable composite booms (Bi-DCBs) have broad application prospects in space deployable structures due to unique bistable characteristics, efficient stowage, lightweight, and excellent mechanical properties. However, the contrasting structural requirements (i.e., stiffness, stability) and operational requirements (i.e., lightweight, compact, and stowage) pose challenges to engineering design. To overcome this issue, this paper proposes a many-objective optimization formulation for the Bi-DCB, leveraging the respective advantages of the analytical and surrogate models, aiming to achieve a balance between multiple objectives, thereby obtaining the optimal comprehensive performance. In this formulation, the cross-sectional radius, cross-sectional angle, and length are selected as design variables while ensuring that the Bi-DCB does not fail during operation. Based on these, an optimization model is established with the objectives to minimize the linear density and the longitude-sectional polar radius at the endpoint and to maximize the average strain energy and the natural frequency. To verify optimal results, benchmark testing and performance evaluation are conducted using different algorithms, and the Pareto front containing 112 solutions is ultimately found, all superior to the initial sample in four objectives. These solutions achieve a good balance and coordination among multiple objectives, providing optimal performance schemes for the design of the Bi-DCB.
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