Multi-objectives nonlinear structure optimization for actuator in trajectory correction fuze subject to high impact loadings

This paper presents an actuator used for the trajectory correction fuze, which is subject to high impact loadings during launch. A simulation method is carried out to obtain the peak-peak stress value of each component, from which the ball bearings are possible failures according to the results. Subsequently, three schemes against impact loadings, full-element deep groove ball bearing and integrated raceway, needle roller thrust bearing assembly, and gaskets are utilized for redesigning the actuator to effectively reduce the bearings' stress. However, multi-objectives optimization still needs to be conducted for the gaskets to decrease the stress value further to the yield stress. Four gasket's structure parameters and three bearings' peak-peak stress are served as the four optimization variables and three objectives, respectively. Optimized Latin hypercube design is used for generating sample points, and Kriging model selected according to estimation result can establish the relationship between the variables and objec-tives, representing the simulation which is time-consuming. Accordingly, two optimization algorithms work out the Pareto solutions, from which the best solutions are selected, and verified by the simulation to determine the gaskets optimized structure parameters. It can be concluded that the simulation and optimization method based on these components is effective and efficient.     

Multi-objective design optimization of composite submerged cylindrical pressure hull for minimum buoyancy and maximum buckling load capacity

This paper presents the design optimization of composite submersible cylindrical pressure hull subjected to 3 MPa hydrostatic pressure. The design optimization study is conducted for cross-ply layups [0s/90t/0u], [0s/90t/0u]s, [0s/90t]s and [90s/0t]s considering three uni-directional composites, i.e. Carbon/Epoxy, Glass/Epoxy, and Boron/Epoxy. The optimization study is performed by coupling a Multi-Objective Genetic Algorithm (MOGA) and Analytical Analysis. Minimizing the buoyancy factor and maximizing the buckling load factor are considered as the objectives of the optimization study. The objectives of the optimization are achieved under constraints on the Tsai-Wu, Tsai-Hill and Maximum Stress composite failure criteria and on buckling load factor. To verify the optimization approach, optimization of one particular layup configuration is also conducted in ANSYS with the same objectives and constraints.     

弹道修正弹系统效能灵敏度分析

灵敏度分析是武器系统效能分析中的一项重要内容,针对正交试验的不足,在分析了弹道修正弹系统效能的影响因素的基础上,建立了基于均匀设计的弹道修正弹系统效能的回归模型。通过对模型求导得到了命中概率对各参数的灵敏度表达式,并进行优化分析,得到了系统效能参数的最优组合以及最优区间,研究结果可作为弹道修正弹参数优化设计的依据。     

动物飞行控制技术在军事中的应用

半机械动物飞行器代表了微型飞行器的未来方向。文中对动物飞行控制技术仅作简要介绍,对半机械动物飞行器在军事领域中的应用价值和应用前景作了重点讨论．综述了近年来动物飞行控制技术的重要研究动态,结合甲虫机器人介绍了本实验室的近期研究成果。最后,基于动物飞行控制技术的研究瓶颈给出了动物飞行控制技术未来的研究方向。     

基于信息流的中枢疲劳脑电分析

为充分利用多导脑电信息,首次提出运用有向传递函数（DTF）方法,对不同中枢疲劳状态下导联间信息流的强度和方向的变化进行分析。研究结果表明,脑电功能耦合中额一到一顶方向的信息流是大脑皮层联系的一个固有特征,可以有效地刻画安静清醒和疲劳两个状态,长时间脑力劳动任务引起中枢疲劳的增加,进而导致整个频率段占优势的信息流的方向发生了反转,信息流占优势的方向从实验前的顶一到一额方向,转变为实验后的额一到一顶方向。     

并行工程关键使能技术及其发展趋势

介绍了并行工程(ConcurrentEngineering,简称CE)的定义、基本原则、组成、驱动力和要素等,概要介绍了CE的部分关键使能技术。基于CE的理论研究与应用实践,给出实施CE的基本模式并进一步设想了CE的发展趋势。     

并串联系统设计优化

建立了并串联系统设计优化的两类模型,提出了遗传算法与模式搜索、启发式算法相结合的求解方法．     

并行工程中的结构分析

简要介绍了并行工程的概念 ,分析了防空导弹弹体结构件传统设计、分析过程中存在的问题 ,提出了实现并发设计的途径并在实践中应用验证。结合研究与实践探索 ,提出本领域的发展设想。进一步指出 :设计与分析的并行是必然的发展趋势     

二元共晶系相变材料热力学模型的研究

推导了二元共晶系的热力学模型,改进了单参数的Margules方程,引入了温度项,利用实验值对方程中的参数进行了回归,结果表明该热力学模型是可行的,从而可以应用该模型计算二元共晶系相变材料的最低共熔点和组成。     

C4ISR分布式信息融合系统拓扑结构设计

提出一种构造分布式信息融合系统的拓扑结构的新方法.首先,简要介绍了该问题的研究现状;然后,在对目前使用的网络结构进行深入分析的基础上,提出了基于多层de Bruijn网的分布式信息融合系统网络拓扑结构及其构造方法;最后讨论了上述网络结构的路由问题.