系统动力学C3I系统作战效能评估

C3I系统效能评估是C3I系统发展的重要问题,现有的ADC法、指数法、层次分析法和SEA方法等都存在着某种局限性,也无法度量C3I系统与作战结果的关系.系统动力学是一门分析研究信息反馈系统的学科,适合于研究C3I系统的系统效能和作战效能之间的定量关系.以一个具体的关于C3I系统的作战想定为例,构建了该C3I作战系统的因...     

燃气流量可调固体火箭冲压发动机飞行性能分析

在建立燃气流量可调固体火箭冲压发动机工作过程仿真模型的基础上,对燃气流量调节过程中发动机飞行性能进行分析.结果表明,在低飞行高度或高飞行马赫数时,发动机有较宽的推力调节范围;随着飞行高度降低或飞行马赫数增加,发动机推力系数降低;随着燃气发生器喷喉面积变小,发动机推力和推力系数增加.     

部队装备管理信息化建设的系统动力学模型

装备管理信息化建设是信息化条件下部队科学管装建设的核心内容。在对部队装备管理信息化建设进行系统分析的基础上,运用系统动力学的理论和方法,从系统的内部结构着手,建立部队装备管理信息化建设的系统动力学模型。通过实例仿真分析,证明了研究方法的有效性和优越性,可以对建设过程中的基本规律进行探索,从而为部队装备管理信息化建设的科学、健康发展提供定量决策支持。     

多孔介质中气体流量对流动阻力影响的实验研究

对空气在多孔介质(Pd/SiO2颗粒催化剂)中的流动阻力特性进行了冷态实验,研究了气体流量对流动阻力的影响.结果表明:催化剂厚度一定时,随着气体流量增大,多孔介质中的流动阻力也逐渐增大.经过与经典阻力计算公式对比,分析了偏差影响因素.最后,结合实验数据拟合出了适合管式反应器中流动阻力计算的半经验公式,能精确地预测颗粒填...     

基于编码矩阵识别的高速空时分组码技术

正交空时分组码和准正交空时分组码的编码速率≤1,为使空时分组码能够应用在高速传输的场合,本文提出了一种基于编码矩阵识别的高速空时分组码设计方法。该方法通过在发送端发送不同的编码矩阵表示不同的附加信息,能够实现大于1编码速率,仿真分析结果表明,在高信噪比条件下该方法使编码速率达到了2.5,并具有良好的有效吞吐容量,特别适合无线高速数据传输。     

一种基于两级均衡的超Nyquist码元速率接收方案

1975年MAZO提出超Nyquist码元速率(FTN)理论,通过理论推导证明,信号在加性高斯白噪声信道下,以超过Nyquist码元速率25%以内的速率进行传输,误码性能可以不下降。但MAZO以及至今都没人能完成FTN的接收,因为当信号以超Nyquist码元速率进行传输所引起的码间串扰长度无限长,若要完全消除码间串扰,使用最大似然检测(MLSE)方法,其复杂度无穷大,是不可实现的。基于MMSE均衡和WCE均衡级联的两级均衡已证明在长码间串扰信道下其误码性能接近于MLSE。文章将两级均衡运用于FTN接收,仿真证明在加性高斯白噪声信道下,信号以超过Nyquist码元速率25%以内的速率进行传输,误码性能不下降。成功实现FTN的接收,验证了MAZO的理论。     

防止反编译技术研究

运用反编译技术可以对软件可执行二进制代码进行非法的修改或窃取其知识产权。为了防范这种情况,提出了在程序的汇编级转化直接跳转为间接跳转和插入伪造的跳转表以隐藏程序控制流的2种方法,来提高程序防止反编译的性能,增加软件分析的难度。     

一类带配送中心运输问题的容量扩张模型研究

运输问题一般采用表上作业法来解决,考虑一类带配送中心的运输问题,若仍采用表上作业法,会使问题复杂化.文中采用一种构造辅助网络的方法:在运输网络中将每个配送中心均拆分成两个点,连接两点形成新弧,构造出新的网络,并给每条弧赋予参数,将此类运输问题转换为最小费用流模型来解决,可以使问题模型和运算简单化.在此基础上,考虑运输网络中配送中心和边的容量扩张问题.     

Recent advances in catalytic combustion of AP-based composite solid propellants

Composite solid propellants (CSPs) have widely been used as main energy source for propelling the rockets in both space and military applications. Internal ballistic parameters of rockets like characteristic exhaust velocity, specific impulse, thrust, burning rate etc., are measured to assess and control the performance of rocket motors. The burn rate of solid propellants has been considered as most vital parameter for design of solid rocket motors to meet specific mission requirements. The burning rate of solid propellants can be tailored by using different constituents, extent of oxidizer loading and its particle size and more commonly by incorporating suitable combustion catalysts. Various metal oxides (MOs), complexes, metal powders and metal alloys have shown positive catalytic behaviour during the com-bustion of CSPs. These are usually solid-state catalysts that play multiple roles in combustion of CSPs such as reduction in activation energy, enhancement of rate of reaction, modification of sequences in reaction-phase, influence on condensed-phase combustion and participation in combustion process in gas-phase reactions. The application of nanoscale catalysts in CSPs has increased considerably in recent past due to their superior catalytic properties as compared to their bulk-sized counterparts. A large surface-to-volume ratio and quantum size effect of nanocatalysts are considered to be plausible reasons for improving the combustion characteristics of propellants. Several efforts have been made to produce nanoscale combustion catalysts for advanced propellant formulations to improve their energetics. The work done so far is largely scattered. In this review, an effort has been made to introduce various combustion catalysts having at least a metallic entity. Recent developments of nanoscale combustion catalysts with their specific merits are discussed. The combustion chemistry of a typical CSP is briefly discussed for providing a better understanding on role of combustion catalysts in burning rate enhancement. Available information on different types of combustion nanocatalysts is also presented with critical comments.