考虑飞行性能和制导精度的微型导弹设计方法

IF 1.9 3区计算机科学 Q3 AUTOMATION & CONTROL SYSTEMS

Journal of Systems Engineering and Electronics Pub Date : 2024-01-16 DOI:10.23919/jsee.2024.000007

Licong Zhang, Chunlin Gong, Hua Su, Da Ronch Andrea

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引用次数: 0

摘要

微型导弹（MMs）的设计面临着一些新的挑战。任务要求以一定的精度到达目标，这就对制导精度提出了严格的要求。微型导弹的小型化使得制导、导航和控制（GNC）设计对主体设计（外形、电机和布局设计）及其设计目标（即飞行性能）的影响比以往更大。为了在飞行性能和制导精度之间进行权衡，在设计主体和 GNC 系统时必须考虑到所有相关的相互作用。在此，提出了一种多目标、多学科优化设计（MOO）方法。与电机、空气动力学、布局、轨迹、飞行动力学、控制和制导相关的学科都被纳入了所提出的 MOO 框架。优化问题旨在实现航程最大化和制导误差最小化。该问题采用非支配排序遗传算法 II 解决。最终获得了兼顾较远航程和较小制导误差的最优设计。最后，通过将最佳设计与传统方法提供的设计进行比较，总结了 MM 设计的经验教训，并深入探讨了飞行性能与制导精度之间的权衡。

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Design Methodology of a Mini-Missile Considering Flight Performance and Guidance Precision

The design of mini-missiles (MMs) presents several novel challenges. The stringent mission requirement to reach a target with a certain precision imposes a high guidance precision. The miniaturization of the size of MMs makes the design of the guidance, navigation, and control (GNC) have a larger-than-before impact on the main-body design (shape, motor, and layout design) and its design objective, i.e., flight performance. Pursuing a trade-off between flight performance and guidance precision, all the relevant interactions have to be accounted for in the design of the main body and the GNC system. Herein, a multi-objective and multidisciplinary design optimization (MOO) is proposed. Disciplines pertinent to motor, aerodynamics, layout, trajectory, flight dynamics, control, and guidance are included in the proposed MOO framework. The optimization problem seeks to maximize the range and minimize the guidance error. The problem is solved by using the nondominated sorting genetic algorithm II. An optimum design that balances a longer range with a smaller guidance error is obtained. Finally, lessons learned about the design of the MM and insights into the trade-off between flight performance and guidance precision are given by comparing the optimum design to a design provided by the traditional approach.

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