基于SPW的有源干扰条件下雷达系统仿真分析

利用SPW软件建立了某型雷达系统和有源遮盖性干扰模型,并在此基础上进行了仿真。基于仿真结果,对有源干扰条件下雷达性能进行亍分析。     

装修材料消防监督管理工作问题研究

从具有防火性能的装修材料在生产、销售、使用环节和消防监管过程两个方面,分析了消防监管工作存在的各部门难以形成合力、执法难度大、销售者和使用者不懂法等问题,提出了公安机关消防机构带头,各社会单位、协会相协调形成齐抓共管局面的工作建议。     

高频地波雷达作战效能评估分析方法

根据高频地波雷达的特点和作战任务,采用层次分析法,从探测能力、情报质量和生存能力三个指标层给出了高频地波雷达作战效能评估的层次结构体系,并确定了各效能指标及相对权重的计算方法,最后得出了高频地波雷达作战效能评估的定量分析方法,解决了雷达系统作为非直接杀伤性武器而无法评价其在作战背景下的作战效能的问题,为该雷达的作战使用提供了辅助决策的依据.     

基于混沌特征的高分辨雷达目标识别

根据高分辨导弹制导雷达的基本工作原则和舰船目标的散射特性,利用现有雷达回波的仿真技术,在合理的战术想定下,计算了三类典型舰船的雷达回波.在此基础上,研究了利用雷达回波功率谱的方法来识别目标类型的有效性,并基于混沌理论提出了一种比功率谱方法更加有效的新的识别方法,从而为进一步利用混沌理论来开发雷达目标识别技术奠定了初步的理论基础.     

干扰下雷达网的威力范围

分析了构成雷达网的主要威胁干扰是压制式干扰,根据压制式干扰的特征和干扰下的雷达方程,分析雷达网的威力范围,提出一种采用MATLAB将雷达网的作用范围、目标轨迹及干扰轨迹画在同一图中的方法.比较目标是否在雷达网威力范围,根据等高线判断某一高度的目标是否在雷达网的威力范围之内.并给出两相控雷达存在压制式干扰情况下对一机动目标的防御范围.     

基于两坐标雷达与红外传感器的融合跟踪

针对两坐标雷达与红外传感器的融合跟踪问题,提出一套基于航迹关联事件的后验概率最大化准则和"最近邻"思想的状态信息相关与融合估计的一体化实现方法,克服了两种传感器观测数据不完整给融合处理带来的困难,通过充分利用雷达的航迹,点迹和历史信息,融合高精度的红外测角和雷达测距信息,改善系统的跟踪能力.最后的仿真实验表明了该方法的有效性.     

突防过程的组网雷达干扰资源优化分配

以组网雷达融合中心检测概率为目标函数,建立针对组网雷达系统的干扰资源优化分配模型.并进一步指出该模型运用于飞行器突防时,其不足之处在于"以点带面",以飞行器突防过程中某一点的融合中心检测概率代替整个突防过程时,该评估方法损失过程中的大量信息.在此基础上充分利用突防过程的信息,提出以"融合中心检测概率加权积分"为目标函数,建立基于突防过程的干扰资源优化分配模型.仿真结果表明具有一定的指导意义.     

某高炮数字指挥仪的改造

为了使某高炮数字指挥仪能够适应现代战争的需要,遵照中央军委关于"要用高新技术改造现役装备"的指示,在不降低原高炮数字指挥仪战术技术性能的基础上,加装了红外热像仪、激光测距机、激光距离转换计算机、雷达诸元转换计算机.使该装备不仅能够与部队现配置的雷达连接使用,还增加了目标探测手段,增强了夜间作战能力,提高了装备的性能,成为新一代的光电防空火控系统,适应现代战争的要求.     

Critical interfaces in body armour systems

The ballistic performance, and behaviour, of an armour system is governed by two major sets of variables, geometrical and material. Of these, the consistency of performance, especially against small arms ammunition, will depend upon the consistency of the properties of the constituent materials. In a body armour system for example, fibre diameter, areal density of woven fabric, and bulk density of ceramic are examples of critical parameters and monitoring such parameters will form the backbone of associated quality control procedures. What is often overlooked, because it can fall into the User’s domain, are the interfaces that exist between the various products; the carrier, the Soft Armour Insert (SAI), and the one or two hard armour plates (HAP1 and HAP2). This is especially true if the various products are sourced from different suppliers.There are between 30 and 150 individual layers within a typical body armour system, and each of the interfaces between each of those layers will, in some way or another, contribute to the ballistic performance of the system. For example, consider the following interfaces/interlayers: (i) the frictional, sliding, inter-ply surfaces within a soft armour pack, and also between the pack and the carrier, (ii) the air-gaps that may develop within the soft armour pack, (iii) the interconnecting space between the soft armour pack and the hard armour plate, (iv) the nature of the interfaces between adjacent plies of a multiplied backing laminate, even in a highly compressed Ultra High Molecular Weight Polyethylene (UHMWPE) variant, (v) the interlayer between the ceramic and its substrate, within a HAP, and (vi) the geometrical fit between two hard armour plates within a stacked body armour system. This paper will provide a User-friendly overview of all such interfaces and provide unique guidance as to their criticality and influence.     

Formation and characterization of core-shell CL-20/TNT composite prepared by spray-drying technique

The core-shell 2,4,6,8,10,12-Hexanitro-2,4,6,8,10,12-hexaazaisowurtzitane/2,4,6-Trinitrotoluene (CL-20/TNT) composite was prepared by spray-drying method in which sensitive high energy explosive (CL-20) was coated with insensitive explosive (TNT). The structure and properties of different formulations of CL-20/TNT composite and CL-20/TNT mixture were characterized by scanning electron microscopy (SEM), Transmission electron microscopy (TEM), Laser particle size analyzer, X-ray photoelectron spectroscopy (XPS), X-ray diffraction (XRD), differential scanning calorimetry (DSC), impact sensitivity test and detonation performance. The results of SEM, TEM, XPS and XRD show that ϵ-CL-20 particles are coated by TNT. When the ratio of CL-20/TNT is 75/25, core-shell structure is well formed, and thickness of the shell is about 20–30 nm. And the analysis of heat and impact show that with the increase of TNT content, the TNT coating on the core-shell composite material can not only catalyze the thermal decomposition of core material (CL-20), but also greatly reduce the impact sensitivity. Compared with the CL-20/TNT mixture (75/25) at the same ratio, the characteristic drop height of core-shell CL-20/TNT composite (75/25) increased by 47.6% and the TNT coating can accelerate the nuclear decomposition in the CL-20/TNT composites. Therefore, the preparation of the core-shell composites can be regarded as a unique means, by which the composites are characterized by controllable decomposition rate, high energy and excellent mechanical sensitivity and could be applied to propellants and other fields.