毫米波制导武器及其防护

介绍了毫米波制导武器的特点以及国外已经装备或正在研制的毫米波制导武器。基于毫米波辐射及传输特点,讨论了对毫米波制导武器进行防护的方法。     

减少航程损失的尾流自导新方案

提出了一种基于三元换能器组的尾流自导导引方案,它对尾流的左右舷判别能力使其可以采用较小的尾流出入角度,从而可以较大程度降低鱼雷航程损失.仿真结果表明,该方案可以在不降低鱼雷末弹道命中概率的前提下,将尾流导引段的航程损失由通常的15%降低到5%左右.     

激光照射指示器束散角数字化检测方法研究

激光末端制导武器系统中,激光照射指示器出射激光的束散角是一个重要的参数。介绍了一种出射激光束散角的数字化检测方法。区别于传统的套孔法和反射靶板法,该方法通过CCD采集激光光斑,用质心法确定光斑中心,根据激光能量密度分布确定激光光斑半径,进而计算出待测的激光束散角。     

变后掠翼导弹制导精度研究(英文)

将飞行器变后掠翼技术应用于导弹上,弹翼的运动对弹体动态特性与整个系统的制导精度会直接产生影响。首先基于多刚体动力学原理获得的变后掠翼导弹完整的数学模型,通过小扰动线性化方法得到了弹体相关的传递函数,并利用统计线性化方法计算了制导数学模型的均值与协方差传播方程,最后应用协方差分析描述函数方法分析得到了导弹的弹翼转动速度、弹翼后掠角大小与弹翼转动时刻对制导精度影响的规律。     

临近空间防空导弹制导律

基于临近空间防空导弹,在拦截高空高速大机动目标的条件下,对导弹的制导律进行了研究。给出了微分对策制导律的理论知识及其具体算法,通过Simulink工具进行模块化建模,并将制导律模型引入导弹六自由度模型中进行仿真,对比分析导弹飞行轨迹和需用过载,表明微分对策制导律要比常用的比例导引制导律更优。     

临近空间武器对预警探测制导技术的挑战

临近空间进攻武器具有速度快、射程远、机动性强的特点,对未来空天安全构成重大威胁.简要综述了国内外临近空间武器的发展现状、主要特点及特性,包括高超声速巡航导弹和高速滑翔弹头两大主要威胁,从预警探测和探测制导的角度,指出了预警探测制导技术在应对临近空间进攻武器上面临的严峻挑战,提出了对其关键技术和技术途径的几点思考.     

光纤激光水听器的PGC实时全数字解调系统

概述了基于麦克尔逊干涉仪的光纤激光水听器的相位载波零差法(PGC)调制解调原理,通过数学推导及仿真,分析了调制信号和混频信号的频差是导致全数字化解调结果错误的主要因素之一。针对该诱导因素提供了可行的解决方案,并实现了基于DSP的1 MHz采样频率下使用PGC方法的全数字实时解调系统。对低频水声波段800Hz水声信号进行解调,实验结果表明:解调信号波形良好。     

变论域模糊自适应滑模有限时间收敛制导律

针对拦截高速机动目标的需求,研究了一种变论域模糊自适应滑模有限时间收敛制导律。推导了导弹-目标空间拦截模型,设计了三维滑模制导律;根据有限时间收敛制导律专家的经验,采用模糊自适应控制方法对滑模制导律的非切换项进行逼近,并设计了有限时间收敛模糊控制规则;提出了一种新型变论域伸缩因子,设计了基于新型伸缩因子的变论域模糊自适应滑模有限时间收敛制导律。仿真结果表明,所设计的制导律能够使导弹准确命中目标,并能够达到视线角速率有限时间收敛,且与比例制导律相比,具有更高的制导精度和更短的飞行时间。     

网络中心战战场精确时间的同步技术

本文阐述网络中心战战场的时间同步技术、精确时间体系结构、双向比对远距离时间同步技术。对各种时间获取技术进行了比较,对GPS定时原理作了较为详细的说明。     

Electronic warfare in the optical band: Main features,examples and selected measurement data

The paper presents the possibilities of, and methods for, acquiring, analysing and processing optical signals in order to recognise, identify and counteract threats on the contemporary battleground. The main ways electronic warfare is waged in the optical band of the electromagnetic wave spectrum have been formulated, including the acquisition of optical emitter signatures, as well as ultraviolet (UV) and thermal (IR) signatures. The physical parameters and values describing the emission of laser radiation are discussed, including their importance in terms of creating optical signatures. Moreover, it has been shown that in the transformation of optical signals into signatures, only their spectral and temporal parameters can be applied. This was confirmed in experimental part of the paper, which includes our own measurements of spectral and temporal emission characteristics for three types of binocular laser rangefinders. It has been further shown that through simple registration and quick analysis involving comparison of emission time parameters in the case of UV signatures in “solar-blind” band, various events can be identified quickly and faultlessly. The same is true for IR signatures, where the amplitudes of the recorded signal for several wavelengths are compared. This was confirmed experimentally for UV signatures by registering and then analyzing signals from several events during military exercises at a training ground, namely Rocket Propelled Grenade (RPG) launches and explosions after hitting targets, trinitrotoluene (TNT) explosions, firing armour-piercing, fin-stabilised, discarding sabots (APFSDS) or high explosive (HE) projectiles. The final section describes a proposed model database of emitters, created as a result of analysing and transforming the recorded signals into optical signatures.