总体结构优化在导弹总体设计中应用

作为导弹总体设计的一项重要内容，结构总体设计优劣影响着导弹最佳总体技术方案成败。现根据型号研制的工程经验，提出了应用于结构总体设计的总体结构优化方法。结合实例，着重从结构最优布局、动力学优化和运动学分析等三方面阐述了具有并行设计特点的总体结构优化内涵。研究表明，总体结构优化是基于并行工程框架的数字化定义、数字化预装配和分析、仿真一体化设计，是解决导弹结构轻质化、提高导弹总体设计水平的有效途径。     

反舰导弹弹道高性能模糊控制系统研究

根据导弹的数学模型及其本身的要求，建立起弹道模糊控制系统，详细介绍了高度一阶模糊控制器的设计，并采用参数寻优的方法得到控制器的量化因子与比例因子。仿真结果表明，在有较大不确定性因素的情况下，该控制系统具有较常规PID控制更好的动态性能和抗干扰性能。     

OPTIMIZATION DESIGN OF HELICOPTER FOR PRELIMINARY PARAMETERS

ＯＰＴＩＭＩＺＡＴＩＯＮＤＥＳＩＧＮＯＦＨＥＬＩＣＯＰＴＥＲＦＯＲＰＲＥＬＩＭＩＮＡＲＹＰＡＲＡＭＥＴＥＲＳＧｕｏＣａｉｇｅｎ（ＴｈｅＲｅｓｅａｒｃｈＩｎｓｔｉｔｕｔｅｏｆＨｅｌｉｃｏｐｔｅｒＴｅｃｈｎｏｌｏｇｙ，ＮａｎｊｉｎｇＵｎｉｖｅｒｓｉｔｙｏ...     

用最大值原理求某无人机的最优上升轨迹

为改进某无人机飞行性能，应用最大值原理求解无人机在垂直平面内的最优上升轨迹，推导了无人机最经济爬升所满足的极值方程；并用此方程和最快爬升极值方程这两类目标函数求解了某无人机的最优上升轨迹，计算结果表明，经优化后的爬升轨迹可以节省燃油，延长无人机的续航时间或快速爬升到预定的终点高度具有较好的性能收益。     

基于退火惩罚混合遗传算法求解生产批量计划问题

针对以获得最低生产成本为目的的批量生产计划问题，提出了该问题的混合整数规划模型，首先，根据单级多资源批量计划问题的特点提出了问题的数学描述，；然后根据该数学问题的复合性，利用遗传算法的随机搜索和进行化过程寻找问题的全局最优解，为了防止适应度函数的过早收敛，引入退火惩罚因子对适应度函数进行处理，使得获得全局优解的可能性加大，实验结果表明，该方法能获得比传统遗传算法更为理想的近似最优解。     

航天飞机气动力辅助异面轨道变换

本文研究了以气动力作为辅助动力,实现异面圆轨道的最优变换。以目标轨道面倾角最大为优化性能指标,获得了升力和滚转角的最优控制规律。文中提出了优化问题的一种参数搜寻方法,有利于问题的求解。文末对结果作了分析,讨论,并就有关的多种变换模态作了分析、对比,表明在一定条件下,气动力辅助变换有明显的优越性。     

一种四连杆机构位置综合的迭代方法

本文提出了一种四连杆机构位置综合的迭代方法,解决了一般解析法对初始点要求过高的问题。该方法对初始点要求很低,而且在计算机上也不易出现“溢出”。     

Multi-objective optimization of frequency and damping of vertical stabilizer skin structure placed with variable-angle tows

The vibration characteristics of composite vertical stabilizer skin structures play a critical role in damping effects designed for overcoming the air disturbances experienced by aircraft structural components during flight. The first-order fundamental frequencies and their corresponding damping characteristics of the vertical stabilizer skin structure tow-steered by automatic fiber placement technique were optimized with the parameterized trajectories and plies as design variables. Firstly, the vibration and damping numerical models were derived based on Kirchhoff laminate theory, the Rayleigh-Ritz method, and the Strain Energy Method. Then the optimization model was developed by adopting the self-adaptive Differential Evolution Multi-objective optimization algorithm and incorporating the solution method of Pareto Front. The constraints of this optimization model considered the experimentally obtained minimum turning radius of prepregs tow-steered in automatic fiber placement process obtained from experimental tests. Finally, the comparison of numerical simulation results was conducted for the optimized trajectories and the conventional straight trajectories under various boundary conditions, and the numerical results were partially validated through damping and frequency tests. The results indicate the vibration characteristics of the composite vertical stabilizer skin structure can be enhanced to a large extent by optimizing fiber trajectories, and the enhancement percentage is affected by the boundary conditions of the actual structure.     

Geometry and size optimization of stiffener layout for three-dimensional box structures with maximization of natural frequencies

Based on the growth mechanism of natural biological branching systems and inspiration from the morphology of plant root tips, a bionic design method called Improved Adaptive Growth Method (IAGM) has been proposed in the authors’ previous research and successfully applied to the reinforcement optimization of three-dimensional box structures with respect to natural frequencies. However, as a kind of ground structure methods, the final layout patterns of stiffeners obtained by using the IAGM are highly subjected to their ground structures, which restricts the optimization effect and freedom to further improve the dynamic performance of structures. To solve this problem, a novel post-processing geometry and size optimization approach is proposed in this article. This method takes the former layout optimization result as start, and iteratively finds the optimal layout angles, locations, and lengths of stiffeners with a few design variables by optimizing the positions of some specific node lines called active node lines. At the same time, thicknesses of stiffeners are also optimized to further improve natural frequencies of three-dimensional box structures. Using this method, stiffeners can be successfully separated from their ground structures and further effectively improve natural frequencies of three-dimensional box structures with less material consumption. Typical numerical examples are illustrated to validate the effectiveness and advantages of the suggested method.     

双损耗Al2O3基多孔吸波材料的制备及其吸波性能

基于片状Al₂O₃陶瓷互锁结构强度高的特点,制备出夹杂石墨的高气孔率的Al₂O₃多孔陶瓷,并通过原位还原在多孔骨架中制备出Ni微粒,形成一种轻质的双损耗陶瓷基吸波材料。通过XRD、FE-SEM和EDS研究了还原温度对多孔吸波材料的组成、微观形貌、元素分布和吸波性能的影响。结果表明,还原温度升温至700 ℃可将多孔网络中Ni完全还原,形成以堆叠互锁Al₂O₃为基,夹杂片状石墨和孔表面覆盖Ni微粒的双损耗轻质吸波材料。当复合材料厚度为6.5 mm时,最小反射损耗为-35.01 dB,有效吸收带宽达到1.75 GHz。片状Al₂O₃锁定的石墨片构筑的导电网络,Ni微粒与基体之间的极化效应等共同促进复合材料良好的微波吸收性能。