战争系统复杂性及其基于Agent建模仿真研究进展

复杂性科学是当今世界科学发展的热点和前沿,其研究与应用正迅速向各个学科渗透和扩展,成为备受众多领域科学家关注的交叉学科研究领域.目前,在军事科学领域,战争复杂性的问题正日益受到学者们的广泛关注.应用复杂系统建模与仿真方法对战争复杂性问题进行建模与仿真研究是一种有别于传统的基于兰切斯特方程等数学模型方法研究战争问题的一种新方法.讨论了战争系统复杂性问题,在掌握现有资料的基础上,力图较全面介绍国内外关于基于Agent战争系统复杂性建模与仿真方面的最新研究进展,并对相关的研究成果给出了自己的看法.     

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.     

基于模糊时间Petri网的决策融合模型及时间推理

针对常规导弹旅作战指挥决策过程中伴随大量随机、并发情况的特点,提出利用线性逻辑给出的模糊时间Petri网来描述作战指挥决策融合过程。通过建立相应的FTPN模型,并利用时间推理的方法来分析模糊时间Petri网的运行行为,说明其在作战指挥决策融合中的应用。     

数字波束形成技术(DBF)在雷达中的应用

数字波束形成技术是天线波束形成原理与数字信号处理技术相结合的产物,其广泛应用于阵列信号处理领域。由于电磁工作环境的恶化和大量射频干扰的存在,在极低的信干噪比(SINR)条件下进行目标检测和信息提取十分困难。对于阵列系统,往往采用自适应数字波束形成(ADBF)技术,来抑制强干扰和方向性干扰对有用信号的影响。介绍了数字波束形成器的基本原理及其DSP的实现结构。     

反辐射无人机在电子战中的应用及其效能分析

简要讨论了反辐射无人机系统的组成和两种典型的反辐射无人机,指出了其在电子战中的应用。并针对某型反辐射无人机的系统能力,即命中概率和毁伤概率进行了理论分析和计算。     

基于遗传算法的潜射反舰导弹综合作战效能分析

提出了直接根据单指标相对隶属度的模糊评价矩阵,构造层次分析法中的判断矩阵用以确定各评价指标权重的方法,给出了用遗传算法检验和修正判断矩阵的一致性和计算判断矩阵各要素的权重的模糊综合评价模型,对潜射反舰导弹作战效能进行了综合评估和排序.实例表明,该方法简便通用,计算结果较为客观和稳定.     

软件集群路由器体系结构的研究

分析了集群路由器的研究现状,而后提出了软件集群路由器的两个参考模型:SCR-RM(software-based cluster router reference model)和PCR-RM(parallel cluster routing reference model),给出两个参考模型的具体描述。这两个参考模型将为集群路由器的后续研究提供参照系统、实验系统和IP流处理场景。     

921A钢在海水中腐蚀的力学化学效应

为了研究弹性应力和弹塑性应变对921A船体钢在模拟海水中腐蚀行为的影响,采用自制的载荷-电化学实验装置对921A钢在载荷与腐蚀介质协同作用时的开路电位、动电位极化曲线和电化学阻抗谱等电化学性能进行了测试,并由电化学阻抗谱拟合得到的电荷传递电阻定义载荷下的腐蚀速率修正因子,将实验得到的腐蚀速率修正因子与理论值进行了对比。结果表明:弹性拉应力与弹性压应力对力学化学效应的影响具有对称性。力学化学效应随着弹性应力的增大而增大,随着弹塑性应变的增大先增大后减小。弹塑性应变对力学化学效应的影响远远大于弹性应力的影响。在研究范围内,弹塑性应变引起的腐蚀电位负移量最大为62.6 mV,相应的腐蚀速率修正因子高达4.113,而弹性应力引起的腐蚀电位负移量最大为24.5 mV,相应的腐蚀速率修正因子为1.746。由此可见,应力应变对921A钢在海水中腐蚀行为的影响不容忽视。     

Research on the intermediate phase of 40CrMnSiB steel shell under different heat treatments

In this study, 40CrMnSiB steel cylindrical shells were tempered at 350, 500 and 600 ℃ to study the effect of tempering temperature on the dynamic process of expansion and fracture of the metal shell. A mid-explosion recovery experiment for the metal cylinder under internal explosive loading was designed, and the wreckage of the casings at the intermediate phase was obtained. The effects of different tempering temperatures on the macroscopic and microscopic fracture characteristics of 40CrMnSiB steel were studied. The influence of tempering temperatures on the fracture characteristic parameters of the recovered wreckage were measured and analyzed, including the circumferential divide size, the thick-ness and the number of the circumferential divisions. The results show that as the tempering temper-ature was increased from 350 to 600 ℃, at first, the degree of fragmentation and the fracture characteristic parameters of the recovered wreckage changed significantly and then became essentially consistent. Scanning electron microscopy analysis revealed flow-like structure characteristics caused by adiabatic shear on different fracture surfaces. At the detonation initiation end of the casing, fracturing was formed by tearing along the crack, which existed a distance from the initiation end and propagated along the axis direction. In contrast, the fracturing near the middle position consists of a plurality of radial shear fracture units. The amount of alloy carbide that was precipitated during the tempering process increased continuously with tempering temperature, leading to an increasing number of spherical carbide particles scattered around the fracture surface.     

Static and free vibration analyses of functionally graded porous variable-thickness plates using an edge-based smoothed finite element method

The main purpose of this paper is to present numerical results of static bending and free vibration of functionally graded porous (FGP) variable-thickness plates by using an edge-based smoothed finite element method (ES-FEM) associate with the mixed interpolation of tensorial components technique for the three-node triangular element (MITC3), so-called ES-MITC3. This ES-MITC3 element is performed to eliminate the shear locking problem and to enhance the accuracy of the existing MITC3 element. In the ES-MITC3 element, the stiffness matrices are obtained by using the strain smoothing technique over the smoothing domains formed by two adjacent MITC3 triangular elements sharing an edge. Materials of the plate are FGP with a power-law index (k) and maximum porosity distributions (Ω) in the forms of cosine functions. The influences of some geometric parameters, material properties on static bending, and natural frequency of the FGP variable-thickness plates are examined in detail.