考虑不确定参数及外部扰动数字液压缸非线性鲁棒位置跟踪控制

在考虑不确定参数及外部扰动的情况下为数字液压缸位置跟踪系统设计了一个非线性控制器。首先,建立了数字液压缸位置跟踪系统的非线性模型;然后,构造了一个李雅普诺夫函数及非线性控制器,推导了系统鲁棒稳定的充分条件,由此将非线性控制器的设计问题转化成为线性矩阵不等式的求解问题;最后,进行了仿真及实验验证。结果表明:所设计的控制器对于参数不确定性及外部扰动具有良好的鲁棒稳定性及更好的动态特性。     

超音速密集弹丸脱靶量测量方法研究

分析了3种雷达测距体制的优缺点。针对超音速密集弹丸数量多、速度快等特点导致的脱靶量测量困难等问题,提出一种基于调频连续波体制的弹载雷达测距方法,采用四面天线收发分置结构,突破了正侧视开窗检测技术,保证目标在穿越窗口时RCS最强,并针对少数测量数据无法归类现象,设计了基于广义Hough变换的分类方法。仿真结果表明:该脱靶量测量方法可以有效区分多个弹丸轨迹。最后进行了试验验证,结果与理论分析一致,证明了该方法合理性和实用性。     

利用线阵CCD自动测量MSBS中悬浮模型的位置与姿态

以我国自行研制的磁悬挂天平系统为背景,主要研究了利用线阵CCD传感器构建MSBS的模型位置与姿态测量系统以及相应的传感器配置方案、信号转换、测量原理和测量流程等问题。该系统的位置与姿态测量系统以两组共5片线阵CCD作为MSBS中悬浮模型的5自由度位置与姿态传感器,以串联的多级惯性环节电路为脉宽-电压转换电路,将测量信号分别输入控制回路和校准测量回路。文中详细介绍了5片CCD传感器的配置方案及其测量原理,然后研究了使用多级惯性环节实现脉宽-电压信号的转换问题,并对该方案进行了理论分析和仿真,最后研究了利用CCD的测量信号反演悬浮模型位置与姿态的数学原理及其自动测量流程。     

齿轮箱振动测试与分析

在对某型齿轮箱的模态、振动烈度和振动加速度进行测试的基础上,详细分析了测试结果.模态测试得到了齿轮箱的振型和模态参数,振动烈度测试结果表明该齿轮箱处于良好工作状态,振动加速度测试结果显示该齿轮箱的减振措施达到了预期的效果.最后,对测试提出了建议.     

光电指向器水平度测量算法

通过对光电跟踪仪安装时水平度调整方法的研究,提出了利用坐标变换算法,用以实现光电跟踪仪安装时水平度的快速调整.利用该算法不但可以减少安装时的测量次数,节约安装调整时间,而且提高了设备安装时的测量精度,具有广泛的推广应用价值.文中还对该方法的测量计算误差进行了分析.     

风洞现场电磁干扰测量研究

根据风洞现场测控系统的特点,对风洞现场的电磁干扰测量方法和技术进行研究,并在风洞中进行试验,得到了相关的试验数据．通过对数据的分析可以得出：影响风洞现场测控系统的电磁干扰源主要是大功率变频装置,耦合途径为空间辐射和电源线传导．     

基于PSD的炮口扰动测试方法

针对火炮性能测试时难于实时、准确测量炮口扰动的问题,提出了一种基于光电位置传感器（Position Sen-sitive Detector,PSD）的炮口扰动测试方法。采用光学杠杆、激光脉冲调制、高精度光电位置传感器、高速数据采集技术,以及所建立的PSD测量炮口角数学模型构建炮口角测量系统,可有效消除炮口闪光、外界自然光及蚊虫干扰,具有较高的灵敏度、精度和可靠性。     

基于正则化的多平台导航定位及探测偏差估计方法

影响舰载雷达探测误差主要为平台导航定位误差和传感器自身探测误差,针对对这两类误差的影响因素进行了分析,首次综合考虑这两种系统误差,提出了一种基于正则化的多平台导航定位及探测偏差估计方法,利用不同舰艇上传感器对公共目标探测的迭合条件,建立系统误差观测方程,利用LS对两种系统误差同时进行了估计,并在偏差估计中采用正则化估计方法,提高估计结果的稳定性,最后进行了仿真验证,仿真效果验证了算法的有效性,具有较高的工程应用价值.     

Ricochet quantification using a multiple sensor approach

This study investigates the ricochet behaviour of three different small-arms projectile types using a novel ricochet measuring device.The results can be used to estimate the danger potential of ricochets on shooting ranges.A ricochet is the change of direction and velocity of a projectile after impacting an oblique surface.This impact produces strong vibrations on a rigid plate.During this impact,flexural waves travel radially outwards from the point of impact.These waves are used to determine the properties of the impactor with accelerometers situated on the target surface.With the use of two measurement plates,one can produce a ricochet and detect the velocity at the same time.Accelerometers are suitable for accurate momentum measurements of single impacts.However,depending upon strike velocity and the impact angle,a ricochet can separate in multiple fragments after being deflected.From the operational safety perspective,these fragments need to be detected,as well.The approach of a coupled sensor concept was chosen to solve this problem.Thermographic sensors were additionally used to visualise the heat which is produced after pene-trating a rubber layer pasted in front of the steel target plate.With this approach one was able to detect the position of impact.The investigations showed that the measurement system performance is better with a multiple sensor design,which includes accelerometers for the velocity,impact strength and partly the position measurement,while the thermographic sensor was used for the position measurement and partly the momentum measurement.The investigated ammunition showed plausible fragmentation behaviour,and the results can already be used to estimate the danger potential of different ammunition types.Frangible projectiles fragment to small particles already after being deflected under a small angle.However,Full Metal Jacket projectiles with or without a steel core do not fragment under angles which are less than 5°.The objective of the paper is to demonstrate the possibility of measuring the complex ricochet me-chanics of small projectiles using standard accelerometers with the adequate signal processing approach.This measuring system is supported by an off the shelf thermographic camera.     

A novel launch dynamics measurement system for multiple launch rocket system and comparative analysis with numerical simulations

In this paper,a novel launch dynamics measurement system based on the photoelectric sensor pair is built.The actual muzzle time(i.e.a time duration that originates from the initial movement to the rocket's departure from the muzzle)and the muzzle velocity are measured.Compared with the classical methods,the actual muzzle time is obtained by eliminating the ignition delay.The comparative analysis method is proposed with numerical simulations established by the transfer matrix method for multibody systems.The experiment results indicate that the proposed measurement system can effectively measure the actual muzzle time and reduce the error of classical methods,which match well with the simulation results showing the launch dynamics model is reliable and helpful for further analysis and design of the MLRS.