炮兵营射击的弹着点模拟及射击误差分析

弹着点模拟是对敌火力打击目标毁伤仿真的重要环节。在分析炮兵营射击误差构成与计算方法的基础上,研究建立了炮兵射击的弹着点散布蒙特卡洛(Monte-Carlo)仿真模型,实现了对集火射向、适宽射向、三距离射击等多种火力打击方式共同作用下的弹着点散布模拟,为目标毁伤仿真研究提供了模型支持。以此为基础,通过分析各组误差对毁伤概率的影响,发现对于炮兵营打击面散布目标来说,营共同误差是影响毁伤概率的最显著因素,应当通过提高测定目标位置和气象准备的精度减小误差以提高对目标的毁伤效果。     

基于不同模式的反导作战管理与敏感性分析

针对反导作战指控系统作战管理任务与过程,分别构建了层次式、中心式和分布式3种作战管理模式。基于3种管理模式,采用以仿真系统搭建作战环境进行对抗的仿真评估方法,以拦截比率（发射数/拦截数）为评估参数对不同作战管理模式的效能进行了仿真评估,同时对影响评估效能的参数进行了敏感性分析。根据分析评估结果,明确了在不同作战样式下采用不同作战管理模式的基本原则。     

延时中断容忍网络(DTN)捆绑层协议研究

文章对延时中断容忍网络技术的基本概念进行了介绍,并对DTN捆绑层协议的框架及重点内容进行了分析,在此基础上,提出了捆绑层协议实现的基本思路,为DTN技术在军事通信领域的应用提供了参考。     

一种声纳浮标无线传感器网络中的目标定位方法

对声纳浮标无线传感器网络进行了介绍;针对声纳浮标无线传感器网络中对目标的定位问题,提出了质心法和Bounding Box法两种解决方法,并给出了计算模型及坐标变换公式;质心法和Bounding Box法,原理简单,计算量小,符合无线传感器网络硬件资源有限、电源能量有限的特点;对质心法和Bounding Box法进行了仿真模拟,结果表明了这两种方法的定位效果受网络中节点探测半径的影响,Bounding Box的定位效果优于质心法.     

弹药集装单元储存静力学有限元分析

以简单的六面体结构为基础,以“铝板-聚氨酯泡沫材料-铝板”复合板材为弹药集装单元的主体材料,结合弹药集装单元的承载能力要求,建立弹药集装单元的基本模型。通过其在储存状态下的静力学有限元分析,了解3种不同堆垛情况下,弹药集装单元的应力与应变情况,为进一步研究弹药集装单元结构强度提供理论依据。     

海上多无人机协同交叉定位的优化配置方法

针对多部无人机协同交叉定位,考虑无人机安全距离、通信距离和动力学约束条件下,解决多部无人机自动实现对飞行速度和角度的优化配置问题.提出了多机协同测向交叉定位方法,该方法先根据几何稀释度精度建立了不等式约束下的无人机运动参数单目标优化模型,再利用惩罚函数法将优化模型转换为无约束条件的极小值求解问题,最后利用粒子群优化算法获得各无人机飞行速度和角度估计值.仿真试验表明,该方法对不同无人机阵型和辐射源运动状态具有较强的适应性,相比直线飞行配置方法,其定位精度有较大的提高.     

基于数据驱动的自学习防空火力控制技术

立足打赢未来智能化战争的作战需求,提高目标探测识别、运动参数估计的实时性和准确性,解决自主拦截决策建模难度大、决策结果稳定性差等问题,通过引入数据挖掘、深度学习、神经网络等人工智能技术,重点开展基于大数据的多类型目标状态空间模型分析、多探测模式下的目标融合识别技术、基于卷积神经网络的射击诸元修正等,研制一套自学习防空火力控制系统,有效弥补传统防空火力控制技术在时敏目标状态空间模型、大闭环校射、协同信息处理、控制决策等环节的不足,提升火控系统自修正、自学习能力,为武器装备向无人化智能化方向发展提供技术支撑.     

Study of high-speed-impact-induced conoidal fracture of Ti alloy layer in composite armor plate composed of Ti-and Al-alloy layers

In order to understand the mechanism of conoidal fracture damage caused by a high-speed fragment-simulating projectile in titanium alloy layer of a composite armor plate composed of titanium- and aluminum-alloy layers, the ballistic interaction process was successfully simulated based on the Tuler-Butcher and GISSMO coupling failure model. The simulated conoidal fracture morphology was in good agreement with the three-dimensional industrial-computed-tomography image. Further, three main damage zones (zones I, II, and III) were identified besides the crater area, which are located respectively near the crater area, at the back of the target plate, and directly below the crater area. Under the high-speed-impact conditions, in zone II, cracks began to form at the end of the period of crack formation in zone I, but crack formation in zone III started before the end of crack formation in zone II. Further, the damage mechanism differed for different stress states. The microcracks in zone I were formed both by void connection and shear deformation. In the formation of zone I, the stress triaxiality ranged from-2.0 to-1.0, and the shear failure mechanism played a dominant role. The microcracks in zone II showed the combined features of shear deformation and void connection, and during the for-mation process, the stress triaxiality was between 0 and 0.5 with a mixed failure mode. Further, the microcracks in zone III showed obvious characteristics of void connection caused by local melting. During the zone III formation, the triaxiality was 1.0-1.9, and the ductile fracture mechanism was dominant, which also reflects the phenomenon of spallation.     

Numerical simulation study on penetration performance of depleted Uranium (DU) alloy fragments

Due to its high strength, high density, high hardness and good penetration capabilities, Depleted ura-nium alloys have already shined in armor-piercing projectiles. There should also be a lot of room for improvement in the application of fragment killing elements. Therefore, regarding the performance of the depleted uranium alloy to penetrate the target plate, further investigation is needed to analyze its advantages and disadvantages compared to tungsten alloy. To study the difference in penetration per-formance between depleted uranium alloy and tungsten alloy fragments,firstly, a theoretical analysis of the adiabatic shear sensitivity of DU and tungsten alloys was given from the perspective of material constitutive model. Then, taking the cylindrical fragment penetration target as the research object, the penetration process and velocity characteristics of the steel target plates penetrated by DU alloy frag-ment and tungsten alloy fragment were compared and analyzed, by using finite element software ANSYS/LS-DYNA and Lagrange algorithm. Lastly, the influence of different postures when impacting target and different fragment shapes on the penetration results is carried out in the research. The results show that in the penetration process of the DU and tungsten alloy fragments, the self-sharpening properties of the DU alloy can make the fragment head sharper and the penetrating ability enhance. Under the same conditions, the penetration capability of cylindrical fragment impacting target in vertical posture is better than that in horizontal posture, and the penetration capability of the spherical fragment is slightly better than that of cylindrical fragment.     

预报风强度对火箭最大气动载荷精度影响及建模分析

针对不同预报风强度的精度以及其对应的最大气动载荷预报值精度的研究文献极少。以某地区实况风为基准,分别对不同预报风强度的精度以及其对应的最大气动载荷预报值精度特征进行了分析,并利用多元线性回归方法建立了订正模型,结果表明在预报日数第1～11天,预报风强度越大,预报风精度及其对应的最大气动载荷预报值精度越高;利用多元线性回归方法可提高最大气动载荷预报值精度,且预报风强度越小,最大气动载荷预报精度提高越明显。这些发现在火箭发射前的飞行保障及安全决策方面具有参考价值。