多分量雷达辐射源信号的检测与分离

针对多分量雷达辐射源信号难以有效检测与分离的问题,提出了时频变换结合时变滤波的方法。通过图像分割中的区域生长法在时频平面对各分量进行检测,对其中的线性调频分量采用分数阶傅里叶变换进行优先分离,再对时频或频域没有耦合的分量进行滤波,最后通过支持向量机划分分类线,用于时频耦合分量的分离。仿真实验结果表明,该方法可以对多分量信号进行有效的检测与分离。     

A two-step robust adaptive filtering algorithm for GNSS kinematic precise point positioning

In kinematic navigation and positioning, abnormal observations and kinematic model disturbances are one of the key factors affecting the stability and reliability of positioning performance. Generally, robust adaptive filtering algorithm is used to reduce the influence of them on positioning results. However, it is difficult to accurately identify and separate the influence of abnormal observations and kinematic model disturbances on positioning results, especially in the application of kinematic Precise Point Positioning (PPP). This has always been a key factor limiting the performance of conventional robust adaptive filtering algorithms. To address this problem, this paper proposes a two-step robust adaptive filtering algorithm, which includes two filtering steps: without considering the kinematic model information, the first step of filtering only detects the abnormal observations. Based on the filtering results of the first step, the second step makes further detection on the kinematic model disturbances and conducts adaptive processing. Theoretical analysis and experiment results indicate that the two-step robust adaptive filtering algorithm can further enhance the robustness of the filtering against the influence of abnormal observations and kinematic model disturbances on the positioning results. Ultimately, improvement of the stability and reliability of kinematic PPP is significant.     

Time delay compensation in lateral-directional flight control systems at high angles of attack

The previous studies of time delay compensation in flight control systems are all based on the conventional aerodynamic derivative model and conducted in longitudinal motions at low angles of attack. In this investigation, the effects of time delay on the lateral-directional stability augmentation system in high-α regime are discussed based on the $\dot{\beta }$ model, which is proposed in our previous work and proved as a more accurate aerodynamic model to reveal the lateral-directional unsteady aerodynamic characteristics at high angles of attack. Both the $\dot{\beta }$ model and the quasi-steady model are used for simulating the effects of time delay on the flying qualities in high-α maneuvers. The comparison between the simulation results shows that the flying qualities are much more sensitive to the mismatch of feedback gains than the state errors caused by time delay. Then a typical adaptive controller based on the conventional dynamic derivative model and a gain-prediction compensator based on $\dot{\beta }$ model are designed to address the time delay in different maneuvers. The simulation results show that the gain-prediction compensator is much simpler and more efficient at high angles of attack. Finally, the gain-prediction compensator is combined with a linearized $\dot{\beta }$ model reference adaptive controller to compensate the adverse effects of very large time delay, which exhibits excellent performance when addressing the extreme conditions at high angles of attack.     

Adaptive fuzzy terminal sliding mode control for the free-floating space manipulator with free-swinging joint failure

Space manipulator with free-swinging joint failure simultaneously contains kinematic and dynamic coupling relationships, so it belongs to a new underactuated system. To allow the manipulator to carry on tasks, an effective robust underactuated control method for the space manipulator with free-swinging joint failure is studied in this paper. Considering the effect of model uncertainty and joint torque disturbance, a robust underactuated control system based on the Terminal Sliding Mode Controller (TSMC) is designed, but two drawbacks are discussed: (A) Robustness depraves with eliminating chattering. (B) Control parameters are difficult to be determined under unknown uncertainty and disturbance. To improve the TSMC, the adaptive fuzzy controller is introduced to estimate the real effect of unknown uncertainty and disturbance according to deviations of sliding mode and its reaching law. The estimated result is directly compensated into active joints torque. In simulation, the space manipulator with free-swinging joint executes tasks based on the TSMC and the Adaptive Fuzzy Terminal Sliding Mode Controller (AFTSMC) respectively. Same tasks can be finished with smaller joints torque and stronger robustness based on the AFTSMC. Therefore, AFTSMC can serve as an effective robust control method for the space manipulator with free-swinging joint failure under unknown model uncertainty and torque disturbance.     

基于容积卡尔曼滤波的卫星姿态估计

为了获得更好的估计精度和滤波稳定性,提出了一种基于容积卡尔曼滤波（Cubature Kalman Filter, CKF）的容积四元数估计器（Cubature Quaternion Estimator,CQE）估计卫星姿态。新方法利用四元数进行姿态更新,同时采用广义罗德里格参数表示误差角,有效地避免了滤波过程中的奇异。为克服多传感器融合时运算效率低的问题,通过容积四元数估计器与信息滤波相结合,提出了一种容积信息四元数估计器（Cubature Information Quaternion Estimator,CIQE）。仿真表明角度和陀螺漂移初始估计误差较大时,新方法仍能取得良好的估计性能。     

基于3D Zernike矩的巡检器与空间站的相对导航算法

针对航天器相对导航问题,以空间站表面为"特殊地形",提出一种基于大型航天器表面巡检的相对导航算法。首先,运用巡检飞行器上的TOF （Time of Flight）相机测量空间站表面局部点云数据,以该点云数据为实时图,以空间站表面先验点云数据为基准图。然后,利用3D Zernike矩与三维地形间的一一对应关系,将三维地形匹配转化为基于3D Zernike矩的特征向量匹配。在此基础上求解实时图与匹配上的基准图间的相对位置、相对姿态,从而确定两航天器间的相对导航参数,并通过实验分析了匹配精度及速度的主要影响因素。最后,将该相对导航参数与惯性系统推算的相对导航参数在扩展卡尔曼滤波器的框架下实现信息融合,估计了巡检飞行器与空间站间的相对位置、相对姿态,实验结果表明,相对位置精度优于0.002 m,相对姿态精度优于0.1°。     

重力测量卫星KBR系统相位中心在轨标定算法

针对低低跟踪(SST-LL)重力测量卫星K频段测距(KBR)系统相位中心在轨标定问题,提出了一种应用预测卡尔曼滤波算法的KBR系统在轨标定算法。首先,以磁力矩器和姿态控制喷气发动机为执行部件,对一颗卫星施加一定的组合力矩,使其绕另一颗卫星进行周期性姿态机动;然后,将星敏感器数据代入预测卡尔曼滤波算法中估计出卫星姿态;最后,根据KBR系统观测值与卫星姿态角之间的关系,利用扩展卡尔曼滤波算法估计出KBR系统相位中心的位置。数值仿真结果表明:KBR系统相位中心可以被实时估计,当存在较大的卫星姿态动力学模型误差时,KBR系统相位中心的标定误差仍在0.3mrad以内,证明此算法估计精度较高且鲁棒性强。     

一种基于Kalman滤波的卫星遥测数据判读系统

分析了卫星遥测数据的变化规律,提出了一种基于卡尔曼(Kalman)滤波的遥测数据判读系统框架,并定义了系统中各模块的功能及接口关系,应用卫星实际遥测数据对判读系统的数据预测效果进行了验证。结果表明,此系统对数据异常反应迅速,能够很好地满足卫星测试的实时性要求。     

电机-变距螺旋桨动力系统功率优化控制

电动螺旋桨无人机应用越来越普及,但普遍续航时间较短,提高电动力系统效率、降低功率消耗是提高航时的主要措施。电机-变距螺旋桨动力系统（以下简称变距电动力系统）可同时改变转速、桨距两个量,存在桨距和转速的最佳组合,使系统功率最小。相比电机-定距螺旋桨动力系统,其在耗能方面具有特殊优势,但如何达到最小功率点,目前研究较少。针对上述问题,为提高计算效率,便于控制研究工作的开展,首先基于改进天牛须算法的BP神经网络训练得到变距电动力系统的神经网络代理模型。接着提出了一种变距电动力系统功率优化控制策略：在一定入流速度、拉力需求下,基于自适应扩展卡尔曼滤波-牛顿法实时优化桨距,并在一定桨距下利用模糊PID控制系统转速以达目标拉力,实现目标拉力需求下的最小功率控制。仿真验证结果表明,提出的功率优化控制策略鲁棒性更强、优化速度更快、收敛效果更好。