舰舰导弹攻击样式选择的决策分析

根据舰舰导弹攻击时使用雷达方式的不同,可将舰舰导弹攻击主要归结为三种样式,即其他兵力引导攻击样式、被动雷达攻击样式和主动雷达发波攻击样式。衡量各个攻击样式优劣主要考虑攻击的隐蔽性、命中率和发挥武器最大射程等三个因素。为此建立舰舰导弹攻击样式选择问题的递阶层次结构模型,从衡量各攻击样式优劣的三个主要因素出发,对模型进行了分析。最后得出了以其他兵力引导攻击为最佳攻击样式的结论。     

光电对抗在对巡航导弹分层防御中的应用

针对现代防空体系的特点,介绍了巡航导弹及其制导方式,并从巡航导弹自身弱点、实战中的不足以及技术上的可对抗性进行了各方面分析,提出了巡航导弹是可以进行对抗的,尤其是利用光电对抗手段进行对抗的可行性、重要性.目前对巡航导弹的分层防御相对来说费用相当昂贵,而采用光电对抗手段是廉价而又有效的.通过对光电对抗的可行性分析,列出了以侦察告警、定向红外干扰、高重频激光干扰、激光致盲、激光摧毁、烟幕干扰、光电隐身等光电对抗手段进行对抗巡航导弹的方法,并进行探讨.最后对光电技术及光电对抗装备技术的发展趋势作了描述.     

基于HLA的地空导弹拦截仿真系统的开发

高层体系结构HLA建立一个通用的仿真框架,以解决不同仿真器、模型之间的互操作及仿真组件的可重用性问题.针对当前空防对抗的主要特点,在地空导弹拦截的数学模型的基础上,利用HLA技术框架,详细地叙述了地空导弹拦截仿真系统的开发过程.仿真试验表明该系统能有效评估地空导弹火力单元对来袭目标的有效抗击效率和火力范围,为地空导弹火力单元的部署和作战效能的改进提供辅助决策手段.     

深度置信网络在导弹攻击区分类中的应用

针对传统导弹攻击区解算方法忽略双方态势变化等问题,提出运用深度置信网络的导弹攻击区分类模型。根据导弹命中情况与目标机动间的关系,将导弹攻击区划分为五类。通过分析影响导弹攻击结果的态势参数,构建导弹攻击结果预测模型。在实验部分,结合重构误差和测试错误率确定深度置信网络的网络结构,通过逐层提取数据法分析模型参数特征并且讨论微调数据的采样方式。使用反向传播神经网络和支持向量机进行分类有效性对比实验。实验结果表明：深度置信网络运行速度和预测准确度明显优于其他两种方法,满足实时性和准确性要求,所提方法具有良好的应用价值。     

高效率机动部署航空武器靶场关键技术和应用

为用户设计了一个航空武器试验靶场,具备空空、空地和地空导弹试验能力,可机动部署,具有易于运行和运维代价低的特点。靶场由载机遥测系统、测量雷达、光电跟踪系统、微波和光纤通信系统、靶机遥测站、指挥控制等6个子系统构成;指挥控制子系统之外的5个子系统均使用国产成熟产品。在总体方案和指挥控制子系统设计中,对互联集成方案、机动部署、试验航线设计和发布、自动化领航、自动化指挥决策等5项关键技术进行了着重优化。在实际应用中,全靶场运行仅需20多成员(不含飞行和机场机务人员),3天内完成新试验场部署和联调,对作战部队飞行员进行5架次航线训练后即进行实弹试验,2天内完成多发中程拦截和近距格斗空空导弹试验。     

考虑扰动引力影响的弹道助推段误差传播解析计算方法

针对地球扰动引力对弹道导弹惯性导航精度影响日益突出这一问题,研究了沿弹道扰动引力的多项式拟合方法,并基于线性系统理论和弹道摄动思想推导了用于求解扰动引力对弹道助推段状态影响的完整解析表达式。同时考虑扰动引力影响与导弹视加速度之间的耦合特性,将扰动引力引起的视加速度偏差视为扰动引力影响的附加补偿项,并进行迭代修正。仿真结果表明:扰动引力拟合残差小于3×10~(-7)m/s~2,考虑耦合项修正的弹道误差传播解析模型计算残差减小为原有方法的1/3,计算时间仅为直接采用弹道积分求差法的1/10。     

攻击主动防御飞行器的微分对策制导律

基于微分对策理论设计了躲避护卫弹的同时攻击飞行器的制导律。根据传统的性能指标推导了该场景的微分对策制导律,并且根据权重系数的取值定义了三种制导律:最优追赶制导律、逃脱-追赶制导律和复合制导律。最优追赶制导律容易被护卫弹拦截,逃脱-追赶制导律容易造成导弹和飞行器的零控脱靶量急剧增大而使得攻击失败,复合制导律很难选择合适的权重系数。针对以上不足,提出了两种改进的制导律,并对该两种制导律的适用情况进行了分析。通过非线性模型仿真,验证了这两种方法的可行性。该两种制导律目的性强,攻击导弹可以躲避护卫弹进而攻击飞行器。     

Study on performance degradation and failure analysis of machine gun barrel

An increase in the use of the gun barrel will cause wear of the inner wall, which reduces the muzzle velocity and the spin rate of the projectile. The off-bore flight attitude and trajectory of the projectile also change, affecting the shooting power and the accuracy. Exterior ballistic data of a high-speed spinning projectile are required to study the performance change. Therefore, based on the barrel's accelerated life test, the whole process of projectile shooting is reproduced using numerical simulation technology, and key information on the ballistic performance change at each shooting stage are acquired. Studies have shown that in the later stages of barrel shooting, the accuracy of shooting has not decreased significantly. However, it is found that the angle of attack of the projectile increases as the wear of the barrel increases. The maximum angle of attack reaches 0.106 rad when the number of shots reaches 4300. Meanwhile, elliptical bullet hole has appeared on the target at this shooting stage. Through combining external ballistic theory with simulation results, the primary reason of this phenomenon is found to be a significant decrease in the muzzle spin rate of the projectile. At the end of the barrel life, the projectile muzzle spin rate is 57.5% lower than that of a barrel without wear.     

Development of cost effective personnel armour through structural hybridization

The objective of the present study is to develop cost effective thermoplastic hybrid laminate using Dyneema® HB50 and Tensylon®HSBD 30A through structural hybridization method. Laminates having 20 mm thickness were fabricated and subjected to 7.62 × 39 mm mild steel core projectile with an impact velocity of 730 ± 10 ms⁻¹. Parameters such as energy absorption, back face deformation and rate of back face deformation were measured as a function of hybridization ratio. It was observed that hybrid laminate with 50:50 ratio (w/w) of Tensylon® and Dyneema® with Tensylon® as front face showed 200% more energy absorption when compared to 100% Tensylon® laminate and showed equal energy absorption as that of expensive 100% Dyneema® laminate. Moreover, hybrid laminate with TD50:50 ratio showed 40% lower in terms of final back face deformation than Dyneema® laminate. Rate of back face deformation was also found to be slow for hybrid laminate as compared to Dyneema® laminate. Dynamic mechanical analysis showed that, Tensylon® laminate has got higher stiffness and lower damping factor than Dyneema® and hybrid laminates. The interface between Tensylon® and Dyneema® layers was found to be separating during the penetration process due to the poor interfacial bonding. Failure behaviour of laminates for different hybridization ratios were studied by sectioning the impacted laminates. It was observed that, the Tensylon® laminate has undergone shear cutting of fibers as major failure mode whereas the hybrid laminate showed shear cutting followed by tensile stretching, fiber pull out and delamination. These inputs are highly useful for body armour applications to design cost effective armour with enhanced performance.     

Novel approach for active vibration control of a flexible missile

This paper investigates the feasibility of using an active dynamic vibration absorber (ADVA) for active vibration control of a flexible missile system through simulation. Based on the principles of a dynamic vibration absorber (DVA), a ring-type ADVA is first designed to attenuate the elastic vibration of the flexible missile, and the design of the active controller adopts the proportional-integral-derivative (PID) control algorithm. The motion equations of a flexible missile with an ADVA, which is subjected to follower thrust at its aft end, are derived using the Lagrangian approach. Taking the minimum of the root mean square (RMS) of the lateral displacement response of the center of mass as the objective function, a genetic algorithm (GA) is used to optimize the parameter of the DVA and PID controller. The numerical calculations show that the ADVA and DVA are effective in suppressing the vibration and provide approximately 41.2% and 17.6% improvement, respectively, compared with the case of no DVA. The ADVA has better performance than the DVA. When the missile is subjected to follower thrust, the effect of vibration reduction is more effective than the case without follower thrust. It is feasible to reduce vibration and improve the stability of flexible missiles by means of the ADVA.