大型消磁站设计中消磁兼容性分析

针对大型消磁站的消磁兼容性,基于通电线圈磁场计算,分析大型消磁站补偿线圈安匝组合,提出磁探头的布局问题,为大型消磁站消磁线圈的计算设计方案提供了参考依据.     

基于最小二乘支持向量机的测控数据融合

提出利用最小二乘支持向量机方法研究GPS和雷达系统对机动目标联合测量中的数据融合问题,GPS数据经过时间配准处理与雷达数据达到时间同步,经过空间配准和坐标系变换,进行卡尔曼滤波,以滤波估计坐标值作为支持向量机的输入,以最小二乘支持向量机为同步融合中心,输出为目标轨迹的融合估计值,仿真结果表明这种方案可以达到比融合前数据更贴近真实值的效果.     

炮兵营射击的弹着点模拟及射击误差分析

弹着点模拟是对敌火力打击目标毁伤仿真的重要环节。在分析炮兵营射击误差构成与计算方法的基础上,研究建立了炮兵射击的弹着点散布蒙特卡洛(Monte-Carlo)仿真模型,实现了对集火射向、适宽射向、三距离射击等多种火力打击方式共同作用下的弹着点散布模拟,为目标毁伤仿真研究提供了模型支持。以此为基础,通过分析各组误差对毁伤概率的影响,发现对于炮兵营打击面散布目标来说,营共同误差是影响毁伤概率的最显著因素,应当通过提高测定目标位置和气象准备的精度减小误差以提高对目标的毁伤效果。     

群众路线:中国共产党的根本路线

群众路线是我们党创造性地运用马克思主义的群众观点创立的根本路线,是我们党的优良传统和政治优势.新形势下坚持群众路线,是巩固党的执政地位的必然要求,是推进中国特色社会主义宏伟事业的强大动力,是构建社会主义和谐社会的重要因素,是党的执政能力建设和作风建设的核心所在.当前要结合人民群众的新特点,探索坚持群众路线的新规律;着眼人民群众的新诉求,拓展坚持群众路线的新载体;汲取人民群众的新创见,丰富坚持群众路线的新形式,不断开创坚持群众路线的新局面.     

复杂电磁环境下电子系统仿生防护模式研究

阐述电磁防护工作中仿生研究所需要涉及的学科类型和基本内容,对所做工作在整个仿生领域中进行大致的定位;提出生物一电子研究的对等模型、总体构成和实现基础,细化具体研究的方向、设想和防护模式,并从原型实现的工程角度介绍实施策略,使得复杂电磁干扰环境下控制系统板卡及芯片级防护的仿生构想在技术上成为可能。     

基于不确定度的专家评价综合方法

针对群决策中专家评价信息的综合处理问题,应用多位专家评价的评价样本不确定度,提出了基于不确定度的数据综合处理方法。该方法能够有效应用于群决策问题,尤其是参与决策人员(专家)较多时,出现专家相对权重可信度不明确而导致评价准确度低的问题,科学地简化了群决策中专家权重的确定过程,便于应用,具有坚实的理论依据和应用价值。通过算例分析,该方法的有效性得到了验证。     

Multi-objectives nonlinear structure optimization for actuator in trajectory correction fuze subject to high impact loadings

This paper presents an actuator used for the trajectory correction fuze, which is subject to high impact loadings during launch. A simulation method is carried out to obtain the peak-peak stress value of each component, from which the ball bearings are possible failures according to the results. Subsequently, three schemes against impact loadings, full-element deep groove ball bearing and integrated raceway, needle roller thrust bearing assembly, and gaskets are utilized for redesigning the actuator to effectively reduce the bearings' stress. However, multi-objectives optimization still needs to be conducted for the gaskets to decrease the stress value further to the yield stress. Four gasket's structure parameters and three bearings' peak-peak stress are served as the four optimization variables and three objectives, respectively. Optimized Latin hypercube design is used for generating sample points, and Kriging model selected according to estimation result can establish the relationship between the variables and objec-tives, representing the simulation which is time-consuming. Accordingly, two optimization algorithms work out the Pareto solutions, from which the best solutions are selected, and verified by the simulation to determine the gaskets optimized structure parameters. It can be concluded that the simulation and optimization method based on these components is effective and efficient.     

Study of high-speed-impact-induced conoidal fracture of Ti alloy layer in composite armor plate composed of Ti-and Al-alloy layers

In order to understand the mechanism of conoidal fracture damage caused by a high-speed fragment-simulating projectile in titanium alloy layer of a composite armor plate composed of titanium- and aluminum-alloy layers, the ballistic interaction process was successfully simulated based on the Tuler-Butcher and GISSMO coupling failure model. The simulated conoidal fracture morphology was in good agreement with the three-dimensional industrial-computed-tomography image. Further, three main damage zones (zones I, II, and III) were identified besides the crater area, which are located respectively near the crater area, at the back of the target plate, and directly below the crater area. Under the high-speed-impact conditions, in zone II, cracks began to form at the end of the period of crack formation in zone I, but crack formation in zone III started before the end of crack formation in zone II. Further, the damage mechanism differed for different stress states. The microcracks in zone I were formed both by void connection and shear deformation. In the formation of zone I, the stress triaxiality ranged from-2.0 to-1.0, and the shear failure mechanism played a dominant role. The microcracks in zone II showed the combined features of shear deformation and void connection, and during the for-mation process, the stress triaxiality was between 0 and 0.5 with a mixed failure mode. Further, the microcracks in zone III showed obvious characteristics of void connection caused by local melting. During the zone III formation, the triaxiality was 1.0-1.9, and the ductile fracture mechanism was dominant, which also reflects the phenomenon of spallation.     

Numerical simulation study on penetration performance of depleted Uranium (DU) alloy fragments

Due to its high strength, high density, high hardness and good penetration capabilities, Depleted ura-nium alloys have already shined in armor-piercing projectiles. There should also be a lot of room for improvement in the application of fragment killing elements. Therefore, regarding the performance of the depleted uranium alloy to penetrate the target plate, further investigation is needed to analyze its advantages and disadvantages compared to tungsten alloy. To study the difference in penetration per-formance between depleted uranium alloy and tungsten alloy fragments,firstly, a theoretical analysis of the adiabatic shear sensitivity of DU and tungsten alloys was given from the perspective of material constitutive model. Then, taking the cylindrical fragment penetration target as the research object, the penetration process and velocity characteristics of the steel target plates penetrated by DU alloy frag-ment and tungsten alloy fragment were compared and analyzed, by using finite element software ANSYS/LS-DYNA and Lagrange algorithm. Lastly, the influence of different postures when impacting target and different fragment shapes on the penetration results is carried out in the research. The results show that in the penetration process of the DU and tungsten alloy fragments, the self-sharpening properties of the DU alloy can make the fragment head sharper and the penetrating ability enhance. Under the same conditions, the penetration capability of cylindrical fragment impacting target in vertical posture is better than that in horizontal posture, and the penetration capability of the spherical fragment is slightly better than that of cylindrical fragment.     

Visual SLAM in dynamic environments based on object detection

A great number of visual simultaneous localization and mapping (VSLAM) systems need to assume static features in the environment. However, moving objects can vastly impair the performance of a VSLAM system which relies on the static-world assumption. To cope with this challenging topic, a real-time and robust VSLAM system based on ORB-SLAM2 for dynamic environments was proposed. To reduce the influence of dynamic content, we incorporate the deep-learning-based object detection method in the visual odometry, then the dynamic object probability model is added to raise the efficiency of object detection deep neural network and enhance the real-time performance of our system. Experiment with both on the TUM and KITTI benchmark dataset, as well as in a real-world environment, the results clarify that our method can significantly reduce the tracking error or drift, enhance the robustness, accuracy and stability of the VSLAM system in dynamic scenes.