炮兵射击指挥系统的智能检测诊断系统

介绍了某型炮兵射击指挥系统智能检测诊断系统的硬件设计和软件组成,并详细地介绍了该系统的功能和技术特点,它不仅可以对炮兵射击指挥系统中的印制板进行故障诊断,也可用于其它由于装备印制板的测试和诊断.     

纯方位跟踪时利用方位变化规律检测目标机动问题

针对纯方位跟踪中目标变向变速机动导致方位信息可能出现的非平滑变化,首先推导出观测平台与目标均匀速直航时目标方位变化的准确规律,运用最小二乘估计法选取了模型参数并设定了阈值的大小,并设计出具体的算法流程,通过仿真计算,对本算法的可行性进行了验证。结果表明,方位变化规律作为目标机动检测的证据具有一定的可行性,但在一些特殊的态势下,检测灵敏度不高,并对这些态势时行了分析。     

机载红外搜索跟踪系统探测性能评测标定

针对机载红外搜索跟踪系统(Infrared Search and Track,IRST)理论与实际战场探测能力之间的较大差异,提出了IRST系统探测性能评定的方法。对机载红外探测系统探测性能指标进行理论分析,选取探测点源目标的噪声等效辐照度作用距离模型进行分析改进;探讨作用距离与探测概率之间的关系;根据IRST系统工作方式,推导出系统物理扫描概率和目标发现概率计算公式;分析目标发现概率与系统作用距离以及载机速度之间的关系;搭建双余度反馈IRST系统探测概率测试平台,制定实验评测步骤,提出一种对探测系统性能进行评估的方法,该方法简单可靠。仿真实验结果表明,满足一定的探测概率下,系统作用距离极限可达到60km;通过半实物仿真平台的测试,实验结果较好地验证了所建模型的合理性。     

基于改进Morison公式的海上漂浮软管波浪载荷计算

针对海上漂浮软管波浪载荷计算,分析了软管在海上的形态和受力特点,建立了海上漂浮软管力学分析模型,指出直接运用现有Morison方程计算漂浮软管波浪载荷存在的不足,并根据基本原理提出了改进Morison方程。对海上软质管线处于一定海况,分别运用改进Morison方程与现有Morison方程计算海上波浪载荷,并运用ANSYS软件建立软管模型,结果表明现有Morison方程不适用于计算海上漂浮软管波浪载荷,载荷计算结果偏高约15%,从而验证了改进Morison方程的精确性,有利于准确分析波浪载荷对海上漂浮软管的作用情况。     

火炮身管无损检测方法

为了延长火炮身管寿命,进一步提高射击精度。研究火炮身管缺陷检测技术,结合身管不同的损伤类型,通过比较不同的身管检测方法,讨论它们的优缺点和发展前景,并得出相控聚焦超声导波检测新技术的优越性,应用在火炮身管检测中,可占据优势地位,使其可以更好地投入到军队的实际应用中,提高作战效能。     

Wasserstein距离在液体火箭发动机故障检测中的应用

健康监控技术能够切实提高液体火箭发动机的可靠性,针对液体火箭发动机健康监控中的故障检测问题,提出基于Wasserstein距离的方法,利用液氢液氧火箭发动机地面热试车数据进行验证。该方法的核心思想是利用Wasserstein生成对抗网络模拟正常数据的样本分布,利用其判别器计算测试样本与模拟分布间的Wasserstein距离,进而实现故障检测。结果表明:该方法能够克服故障数据不足的困难,有效检测稳态过程中的故障,没有发生误报警,且对早期异常有较高敏感性;在训练样本较少的情况下,当Wasserstein距离阈值为3σ时对启动过程的早期异常有较高敏感性,取5σ时仍可有效检测启动过程中的故障,误报警率为12.5%。     

低空复杂场景红外弱小目标快速精准检测

针对低空复杂场景下红外弱小动目标检测难度大、虚警率高等问题,面向探测系统中高帧频图像实时处理应用需求,提出基于全卷积网络的弱小目标精准检测方法和基于现场可编程逻辑门阵列(field programmable gate array, FPGA)的低时延并行处理方法。采用轻量化全卷积网络对红外图像中弱小目标进行空域检测,对相邻图像帧疑似目标进行时域轨迹关联以进一步降低虚警率。实验结果表明:上述方法相比于五种传统方法在检测率和虚警率性能方面均有显著提升,并在单片FPGA上完成100 Hz图像实时处理,处理时延低于1.8 ms,实现低空复杂场景弱小目标高精度高鲁棒快速实时检测。     

利用字节模式二维特征的ROP链智能检测方法

面向返回编程(return oriented programming, ROP)攻击是网络攻击者突破操作系统安全防护、实现漏洞攻击的一种主要手段,ROP链是ROP攻击的重要组成部分。为检测网络流量中的ROP链,提出了一种能自动提取ROP链特征、具有良好泛化性能的智能检测方法。该方法采用顺序抽取的方式将被测流量分成多个序列,利用滑动窗口和数值量化将输入的一维流量数据转换为二维特征向量,基于卷积神经网络模型实现对ROP链的检测。不同于已有的静态检测方法,该方法不依赖程序内存地址的上下文信息,实现简单、部署方便,且具有优异的检测性能。实验结果表明,模型最高准确率为99.4%,漏报率为0.6%,误报率为0.4%,时间开销在0.1 s以内,对真实ROP攻击流量的漏报率为0.2%。     

Cell-type continuous electromagnetic radiation system generating millimeter waves for active denial system applications

The cell-type continuous electromagnetic radiation system is a demonstration device capable of generating high-power millimeter electromagnetic waves of a specific wavelength and observing their effects on living organisms. It irradiates a biological sample placed in a 30 × 30 × 50 cm³ cell with electromagnetic waves in the 3.15-mm-wavelength region (with an output of ≥1 W) and analyzes the temperature change of the sample. A vacuum electronic device-based coupled-cavity backward-wave oscillator converts the electron energy of the electron beam into radiofrequency (RF) energy and radiates it to the target through an antenna, increasing the temperature through the absorption of RF energy in the skin. The system causes pain and ultimately reduces combat power. A cell-type continuous electromagnetic radiation system consisting of four parts—an electromagnetic-wave generator, a high-voltage power supply, a test cell, and a system controller—generates an RF signal of ≥1 W in a continuous waveform at a 95-GHz center frequency, as well as a chemical solution with a dielectric constant similar to that of the skin of a living organism. An increase of 5 °C lasting approximately 10 s was confirmed through an experiment.     

Three-dimensional coordinates test method with uncertain projectile proximity explosion position based on dynamic seven photoelectric detection screen

To objectively obtain the three-dimensional coordinates of the projectile fuze proximity explosion when projectile intersects the head of missile target, we propose a dynamic seven photoelectric detection screen test method, which is made up of six plane detection screens and a flash photoelectric dynamic detection screen. The three-dimensional coordinates calculation model of the projectile proximity explosion position based on seven plane detection screens with dynamic characteristics is established. According to the relation of the dynamic seven photoelectric detection screen planes and the time values, the analytical function of the projectile proximity explosion position parameters under non-linear motion is derived. The projectile signal filtering method based on discrete wavelet transform is explored in this work. Additionally, the projectile signal recognition algorithm using an improved particle swarm is proposed. Based on the characteristics of the time duration and the signal peak error for the projectile passing through the detection screen, the signals attribution of the same projectile passing through six detection screens are analyzed for obtaining precise time values of the same projectile passing through the detection screens. On the basis of the projectile fuze proximity explosion test, the linear motion model and the proposed non-linear motion model are used to calculate and compare the same group of projectiles proximity explosion position parameters. The comparison of test results verifies that the proposed test method and calculation model in this work accurately obtain the actual projectile proximity explosion position parameters.