SAR图像目标方位角估计与分析

SAR成像对目标方位角特别敏感,方位角估计的准确性会直接影响目标的分类和识别.目标方位角估计方法主要有包络盒准则法、轮廓线变换法和主轴原则法.每种方法都有其局限性,且估计范围是[0, 180],可是目标方位角实际范围是[0, 360].为了能获得任意角度且相对精确目标方位角,提出了一种综合SAR图像目标方位角估计方法.该方法融合了的单一估计法的优点,并利用目标的相关信息,突破了以往仅从图像的角度估计方位角的缺点.实验表明这种方法是有效的、可行的.     

运动参数受限的目标跟踪算法研究

提出一种运动参数受限的目标跟踪算法,对于速度受限目标采用平滑修正滤波跟踪算法,首先使用Kalman滤波得到当前时刻的滤波值,找到平滑精度最高点,根据速度限制条件,对滤波结果进行修正。为了保证滤波的无偏有效性,修正计算得到的结果不参与后续滤波处理。通过理论分析和仿真表明,速度受限跟踪算法在观测误差相对较大以及滤波起始阶段可以使滤波跟踪效果获得较大的改善。     

计算机生成兵力的目标选择研究

根据CGF目标选择的模糊性特点,介绍了一个基于模糊集理论的目标威胁分析算法和基于效用理论的目标选择算法。基于模糊集理论的威胁分析能准确反映和描述实际战场环境下信息的模糊特性,算法通过隶属度函数计算得出不同威胁因素的隶属度值,然后通过层次分析法综合各威胁因素隶属度值获得每个目标的威胁程度。基于效用理论的目标选择算法通过效用函数综合考虑了目标的威胁程度和与之交战的期望效益两方面因素,能很好地模拟实际作战兵力的目标选择过程。     

基于MQNM的双基地雷达目标定位改进算法

针对求解双基地雷达目标定位问题常用的Gauss-Newton法自身固有的缺点,如收敛精度和收敛速度依赖于迭代初值与真实值的接近程度和函数的非线性程度,进一步考虑了目标函数Hessian阵的二阶信息,结合MQNM法(修正拟牛顿法)提出了一种双基地雷达目标定位问题的优化改进算法。计算机仿真结果表明了该算法的可行性和有效性。     

基于非负矩阵分解新的人脸识别方法

非负矩阵分解是一个新的特征提取方法,基于非矩阵分解的理论,提出了具有正交性的投影轴的计算方法和具有统计不相关性的投影轴的计算方法。与原非负矩阵分解方法,提出的方法在某种程度上是降低了特征矢量之间的统计相关性,并且提高识别率。通过在ORL人脸库和YALE人脸库上进行实验,结果表明提出的两种特征提取方法在识别率方面整体上好于原非负矩阵分解特征提取(NMF)方法,甚至超过主成分分析(PCA)法。     

基于时变偏差分离估计的杂波下机动目标跟踪

在杂波环境机动目标跟踪问题中,波门位置和范围的确定是关键技术之一。在分析了时变偏差分离估计算法的有偏差的状态估计协方差基础上,提出了基于时变偏差分离估计(separate bias estimation, SBE)和概率数据关联(probabilistic data association, PDA)的新算法,利用了偏差估计和有偏差的状态估计协方差来确定波门位置和范围,并结合PDA处理多个回波的能力,实现杂波环境下机动目标的跟踪。通过仿真实验,说明了新算法的优势和有效性。     

基于改进粒子滤波的微弱目标检测前跟踪算法

研究高速微弱目标的积累检测问题,提出了一种改进粒子滤波的检测前跟踪算法。该算法采用与雷达距离-多普勒图像相匹配的量测数据模型,能克服传统点扩散函数的模型误差。采用“新生”粒子从强度最高的分辨单元集内均匀产生,且按概率对权重最低的部分“存活”粒子用“新生”粒子将其替换的粒子更新策略,在增加粒子多样性的同时缓解了粒子的退化。仿真实验表明,本文算法的检测与跟踪性能要优于标准的粒子滤波算法。     

Target location with signal fitting and sub-aperture tracking for airborne multi-channel radar

The location of a moving target based on signal fitting and sub-aperture tracking from an airborne multi-channel radar is dealt with. The proposed approach is applied in two steps: first, the ambiguous slant-range velocity is derived with a modified single-snapshot multiple direction of arrival estimation method, and second, the unambiguous slant-range velocity is found using a track-based criterion. The prominent advantage of the proposed approach is that the unambiguous slant-range velocity can be very large. Besides, the first stage is carried out at the determinate range-Doppler test cell by azimuth searching for fitting best to the moving target signal, therefore, the location performance would not be sacrificed in order to suppress clutter and/or interference. The effectiveness and efficiency of the proposed method are validated with a set of airborne experimental data.     

正负靶心灰靶决策模型

对灰靶决策模型进行了进一步的拓展研究.定义理想最优及理想最劣方案分别为灰靶的正负靶心,在综合考虑方案与正负靶心的距离,将靶心距作为向量在空间分析的基础上定义了综合靶心距.由各方案靶心距大小及指标权重的不确定性分析的基础上构建目标规划,并由此确定指标权重.由此建立了正负靶心灰靶决策模型.最后以实例说明了所提出的灰靶决策模型的合理性及算法的有效性.     

Modeling for UAV resource scheduling under mission synchronization

Unmanned aerial vehicle (UAV) resource scheduling means to allocate and aggregate the available UAV resources depending on the mission requirements and the battlefield situation assessment. In previous studies, the models cannot reflect the mission synchronization; the targets are treated respectively,which results in the large scale of the problem and high computational complexity. To overcome these disadvantages, a model for UAV resource scheduling under mission synchronization is proposed, which is based on single-objective non-linear integer programming. And several cooperative teams are aggregated for the target clusters from the available resources. The evaluation indices of weapon allocation are referenced in establishing the objective function and the constraints for the issue. The scales of the target clusters are considered as the constraints for the scales of the cooperative teams to make them match in scale. The functions of the intersection between the "mission time-window" and the UAV "arrival time-window" are introduced into the objective function and the constraints in order to describe the mission synchronization effectively. The results demonstrate that the proposed expanded model can meet the requirement of mission synchronization, guide the aggregation of cooperative teams for the target clusters and control the scale of the problem effectively.