一种新的星载自动识别系统检测概率计算方法

针对现有星载AIS检测概率计算方法没有考虑不同解调算法对检测结果影响的问题,提出了一种基于泊松分布船舶检测模型的星载AIS检测概率计算方法。该方法首先计算混叠信号功率差和频差的联合概率分布,以及算法的解调概率,进而将两者相结合得到表征算法能力的关键参数,代入AIS检测概率模型进行计算,可使得原有模型具有适应不同解调算法的能力。仿真表明该方法可有效应用于实际工程的评估,对星载AIS的系统设计有重要的参考价值。     

仿生偏振光定向算法及误差分析

基于标准大气偏振模型,研究了仿生偏振光定向原理,推导了当载体倾斜时的航向角计算方法,分析了各项误差源对航向角估计误差的影响。结果表明：若已知载体的水平角,可根据偏振角解算出载体航向角;引起定向误差的主要因素来自于仿生偏振光传感器误差和载体的水平角误差,太阳位置误差的因素可以忽略;当太阳高度角小于50°、载体水平角小于20°时,仿生偏振光定向的精度约等于偏振角的测量精度,即定向精度约为0.2°。     

基于RNP的A＊算法动态航路规划研究

介绍了A＊算法的基本思想,建立了基于RNP的航路模型,利用A＊算法对航路进行了优化,并利用MATLAB程序对航路进行了算法实现,得到了满意的结论。通过实例分析得出基于RNP的A＊算法对航路进行规划研究的可行性和有效性。在MATLAB环境下进行航路规划问题的A＊算法程序,能够利用其强大的运算能力,并且易于其他工具包结合进行算法仿真实现对其中参数进行优化研究。     

基于改进的模糊C-Means航迹聚类方法研究

为指导飞行程序的改善和发现管制员的指挥模式,在分析历史飞行航迹特征基础上,应用最小描绘长度(MDL)原理对航迹特征点进行划分,运用融合了遗传算法和模拟退火算法的改进的模糊C-Means算法对特征点进行聚类,通过最长公共子序列(LCS)算法得到航迹相似性矩阵,利用矩阵得到航迹簇,最后形成中心航迹,算例仿真验证了新算法的有效性.     

空间谱估计经典算法性能比较

空间谱估计是阵列信号处理的一个重要研究方向。空间谱估计理论与技术已日趋成熟,近几十年的经典谱估计技术包括：常规波束形成（CBF）、Capon谱估计、多重信号分类（MUSIC）、旋转不变子空间算法（ESPRIT）、最大似然（ML）、子空间拟合（SF）,及这些算法的扩展和变形。上述算法在各个分散的文章中均有具体深入的理论分析和研究,亦有类似的2种或3种算法的性能比较,但是针对这些所有算法的性能比较,就笔者所知尚无公开报道,而使工程实现时对算法的选择没有依据。本文对这些经典算法做了简介,列出各个算法的优缺点,并对性能进行仿真比较,能直观地得到各个算法的性能对比,给工程实现算法选择提供理论依据。     

Fault self-repair strategy based on evolvable hardware and reparation balance technology

In the face of harsh natural environment applications such as earth-orbiting and deep space satellites, underwater sea vehicles, strong electromagnetic interference and temperature stress,the circuits faults appear easily. Circuit faults will inevitably lead to serious losses of availability or impeded mission success without self-repair over the mission duration. Traditional fault-repair methods based on redundant fault-tolerant technique are straightforward to implement, yet their area, power and weight cost can be excessive. Moreover they utilize all plug-in or component level circuits to realize redundant backup, such that their applicability is limited. Hence, a novel selfrepair technology based on evolvable hardware（EHW） and reparation balance technology（RBT） is proposed. Its cost is low, and fault self-repair of various circuits and devices can be realized through dynamic configuration. Making full use of the fault signals, correcting circuit can be found through EHW technique to realize the balance and compensation of the fault output-signals. In this paper, the self-repair model was analyzed which based on EHW and RBT technique, the specific self-repair strategy was studied, the corresponding self-repair circuit fault system was designed, and the typical faults were simulated and analyzed which combined with the actual electronic devices. Simulation results demonstrated that the proposed fault self-repair strategy was feasible. Compared to traditional techniques, fault self-repair based on EHW consumes fewer hardware resources, and the scope of fault self-repair was expanded significantly.     

Hypersonic reentry trajectory planning by using hybrid fractional-order particle swarm optimization and gravitational search algorithm

This paper proposes a novel hybrid algorithm called Fractional-order Particle Swarm optimization Gravitational Search Algorithm (FPSOGSA) and applies it to the trajectory planning of the hypersonic lifting reentry flight vehicles. The proposed method is used to calculate the control profiles to achieve the two objectives, namely a smoother trajectory and enforcement of the path constraints with terminal accuracy. The smoothness of the trajectory is achieved by scheduling the bank angle with the aid of a modified scheme known as a Quasi-Equilibrium Glide (QEG) scheme. The aerodynamic load factor and the dynamic pressure path constraints are enforced by further planning of the bank angle with the help of a constraint enforcement scheme. The maximum heating rate path constraint is enforced through the angle of attack parameterization. The Common Aero Vehicle (CAV) flight vehicle is used for the simulation purpose to test and compare the proposed method with that of the standard Particle Swarm Optimization (PSO) method and the standard Gravitational Search Algorithm (GSA). The simulation results confirm the efficiency of the proposed FPSOGSA method over the standard PSO and the GSA methods by showing its better convergence and computation efficiency.     

LDPC码在联合信源信道编码中的应用

介绍了LDPC码的编译码原理,建立了一种应用LDPC码的联合信源信道编码图像传输系统结构,对其性能进行了分析,并给出了LDPC码在联合信源信道编码中应用的进一步研究方向。     

一种高升力系统卡位信号的算法设计

提出了一种高升力系统卡位信号的算法。用于将襟/缝翼控制手柄上的传感器信号转换成高升力系统计算机的命令卡位信号。本算法相较于传统的算法有两处改进,第一处是在手柄卡位信号的计算中增加了信号有效性的确认环节,可以避免当手柄短暂通过手柄卡位信号无效的区域时,产生无效的卡位信号,继而对后续的命令卡位信号计算造成影响。第二处是在命令卡位信号的计算中加入将两个计算机设为主-备关系,并进行表决计算的算法环节,避免了传统算法中由于信号传输延时导致不同通道间输出的命令卡位不一致,从而导致襟/缝翼半速运动的现象发生。本算法可以使最终输出的四个通道的命令卡位信号正确且一致,并已通过实验验证其鲁棒性较强,对民用飞机高升力系统设计有一定的指导作用。     

基于SVM算法的虚假航迹识别

针对云雨杂波和主被动干扰导致多雷达传感器产生虚假目标航迹的问题,利用支持向量机(SVM)算法的自主学习能力,通过构建基于数据驱动的判别模型进行虚假航迹识别。针对航迹起始得到的目标潜在航迹,利用人工智能数据驱动、自学习的特点,设计了SVM算法。通过对已标记真假的目标航迹样本进行离线学习,形成虚假航迹识别的SVM分类器,实现了基于数据驱动的判别模型代替先验知识规则约束的固定模型,并在工程应用中,利用SVM分类器在线识别虚假航迹,完成实时剔除。通过实测雷达数据实验验证,该算法的目标虚假航迹准确率高达95%以上,完全满足实际的工程应用需求。相比基于阈值或规则进行硬性判断的传统虚假航迹识别方法,所提出的算法不仅提高了准确率,还具有较高的实时性,能够适应复杂多变的杂波环境,在实际应用中具有更强的适应性和实用性。因此,提出的基于SVM算法的虚假航迹识别方法对于密集杂波场景下的虚假航迹剔除问题具有显著的实际应用价值。