稀疏孔径成像系统发展概况

介绍了稀疏孔径成像系统的发展现状。重点介绍了系统的成像原理和种类，国外的研究进展以及系统实现的关键技术和应用前景。     

CAD／CAE技术在工艺装备设计中的应用

在镜头的机床定心加工中，过渡环的刚度和质量是影响定心加工精度的主要因素，文章在分析过渡环在加工中的受力情况的基础上，使用Pro／E进行三维造型，使用PATRAN建立有限元模型，使用NASTRAN进行结构静力分析和模态分析，然后根据分析结果优化结构质量。     

TDICCD时序设计在FPGA中的工程实现

文章结合TDICCD和FPGA器件特点，主要从设计目标分析，VHDL算法描述、综合、布线、仿真、代码优化、代码测试验证等几方面，阐述了TDICCD时序设计的全过程；利用同步设计的思想避免了竞争与冒险；利用RC延迟模块实现了时序的精确调整；利用模块化思想提高了代码的可重用性、可测试性、可读性。最终，实现了一个6MHz像元输出速率下能正常工作的TDICCD的成像系统。     

噪声干扰Link-16数据链的干扰功率分配方法

在建立对Link-16数据链的干扰模型和接收机模型的基础上,分析了噪声干扰下接收机的误码性能,研究了干扰功率分配问题,并得到了对Link-16数据链的干扰功率分配方程,最后进行了仿真分析。     

一种基于模糊遗传算法的图像分块恢复方法

针对遗传算法进行图像恢复时运算复杂度高的问题,提出一种基于模糊遗传算法的图像分块恢复方法。将大尺寸的灰度退化图像均匀划分为若干子图块,对各子图块依次采用遗传算法进行恢复,并将其直方图统计数据输入模糊逻辑控制器自适应地调整适应度函数的参数、适应度拉伸时的退火初始温度、交叉概率和变异概率,最后将恢复后的子图块重组为整幅图像并对因分块所造成的边界噪声进行相应处理。仿真结果表明,该方法可有效降低遗传算法进行图像恢复的复杂度,恢复图像的质量也较维纳滤波法和传统遗传算法有明显提高。     

一种未知信源数的快速DOA估计算法

文章针对众多性能优良的超分辨DOA（Direction—Of-Arrival）估计算法大都是以预知信源数为前提、信源数估计不准可能会导致DOA估计失败这一问题,提出了一种基于协方差矩阵对角加载的超分辨DOA估计算法。该算法不需要预判信源个数和进行特征值分解,且通过对协方差矩阵进行对角加载,可以平滑小快拍数时噪声特征值分散程度,因此,该算法更适用于快拍数较少的情况。理论分析表明：该算法的统计估计性能接近于MUSIC（Multiple Signal Classification）算法。计算机仿真结果验证了该算法的鲁棒性和可行性。     

Solar sail formation flying on an inclined Earth orbit

The versatility of solar sail propulsion can be utilized in the exploration of Earth’s magnetotail. An inclined periodic orbit with respect to ecliptic is possible for a solar sail with its orbital plane in synchronous rotation with the sun. Solar sail evolving on such an inclined orbit is free of Earth shadow. Formation flying of a cluster of sails around such an inclined periodic orbit is investigated in this paper. The solution of the first-order approximation to the linear relative motion is used to qualitatively analyze the configurations of relative orbits. Since the relative motion is unstable, active control is necessary to keep a periodic relative motion. A typical LQR method is employed to stabilize the relative motion. The design method is validated by numerical examples.     

Dynamic characteristics analysis of deployable space structures considering joint clearance

The clearance in joints influences the dynamic stability and the performance of deployable space structures (DSS). A virtual experimental modal analysis (VEMA) method is proposed to deal with the effects of joint clearance and link flexibility on the dynamic characteristics of the DSS in this paper. The focus is on the finite element modeling of the clearance joint, VEMA and the modal parameters identification of the DSS. The finite element models (FEM) of the clearance joint and the deployable structure are established in ANSYS. The transient dynamic analysis is conducted to provide the time history data of excitation and response for the VEMA. The fast Fourier transform (FFT) technique is used to transform the data from time domain to frequency domain. The frequency response function is calculated to identify the modal parameters of the deployable structure. Experimental verification is provided to indicate the VEMA method is both a cost and time efficient approach to obtain the dynamic characteristics of the DSS. Finally, we analyze the effects of clearance size and gravity on the dynamic characteristics of the DSS. The analysis results indicate that the joint clearance and gravity strongly influence the dynamic characteristics of the DSS.     

Fault detection,identification and reconstruction for gyroscope in satellite based on independent component analysis

Although satellites are designed with high reliability, faults do occur when satellites are in orbit. To avoid the important services being affected, redundancy is used in satellites. There are many sensors in satellites. In order to reduce the cost, space, weight and power consumption, redundant sensors should be added to satellite as few as possible. Analytical redundancy is an efficient way to optimize the application of redundant. The gyroscope is the attitude determination sensor of the satellite. The minimum redundant structure of the gyroscope system is as follows: three gyroscopes installed in three-axis orthogonally and one gyroscope installed with slantwise for redundancy(3o+1S).To achieve fault detection, identification and reconstruction, hypothesis of statistical independence between the three-axis angular rates and hypothesis of statistical independence between the angular rates and fault are proposed. The scenario that only one sensor is faulting and there are only additive fault and full fault is supposed. Under these assumptions, firstly a threshold method is used for fault detection. After a fault is detected, independent component analysis (ICA) based algorithm for fault identification is employed. To overcome the ambiguities of ICA, correlation coefficients and prior information of the mixed matrix are used. Finally, the reconstruction matrix is obtained. By using this matrix fault signal is extracted so that the yaw, roll and pitch axes (three-axis) angular rates of the satellite can be recovered. Numerical simulations show this method can fulfill fault detection, identification and reconstruction of the gyroscope system.