一种利用信号幅度信息的光学传感器像平面GM-PHD滤波算法

针对光学传感器像平面多目标跟踪应用,基于有限集统计学理论(Finite Set Statistics, FISST)提出一种利用信号幅度信息的高斯混合概率假设密度(Gaussian Mixture-Probability Hypothesis Density, GM-PHD)滤波算法。该算法通过建立信号幅度似然函数将幅度信息引入到PHD的递推公式中,首先根据光学传感器的特点对输出的信号幅度进行建模,然后分别计算来源于目标和杂波的信号幅度似然函数,在目标信噪比未知的情况下给出一种替代计算方法,最后采用高斯混合方式实现该算法。仿真结果表明,本文提出的算法相比仅利用量测位置信息的PHD滤波器能够显著提高多目标跟踪性能和计算效率,而且在目标信噪比未知时同样具有稳定的性能。     

国外光学遥感成像系统仿真软件发展综述与思考

光学遥感系统仿真是一个复杂的系统工程,涉及多个交叉学科领域。遥感成像仿真需要严格按照成像的物理过程进行模拟,对各关键环节建立精确的模型,设计标准化的技术流程,最终完成基于地学、光学、大气科学、电子学、传感器设计等多学科和多技术领域交叉融合的系统集成。文章通过广泛调研国外光学遥感仿真软件的应用和发展现状,比较3种典型仿真软件的设计框架和技术路线,分析其发展趋势,为自主研发的光学遥感仿真模拟软件提供借鉴。     

航天光学采样成像系统MTF的优化设计与MTFC

简要介绍了成像链、成像系统和遥感系统的概念;对像质和像质差异的表征和度量、成像系统性能的表征等予以说明;重点探讨航天光学采样成像系统MTF的优化设计与MTFC问题,并给出讨论结果。     

高速BPSK相干光通信系统对激光器线宽要求

文章概述了激光器相位噪声对零差相干检测光通信系统性能的影响，对特定的基于平衡探测的科斯塔斯（Costas）环路接收系统相位误差进行了详细的理论分析，最后获得了不同传输码速率下的零差相干检测光通信系统对激光器线宽的具体要求。     

计算机在光栅和线纹检测中的应用

介绍了一个将PC机和8031单片机组成的计算机系统应用于光栅尺、线纹尺检测的实例。     

某型飞机机身合拢总装型架设计新技术

某型飞机机身合拢总装型架，在设计上采用了先进制造技术。型架上装有目前国际先进的光学坐标系统，型架地基采用整体框架式底盘。型架结构为分散式。按飞机飞行状态在型架中摆放，并由上方起吊形式下架。本文简要介绍了该型架的设计、制造情况及效果。     

微机在发展光学计测中的作用

通过列举材料，阐述了微型电子计算机的特点与功能，微机在光学计测中的作用，展望了微机在未来光学计测中的应用前景。     

一种非接触光外差轮廓仪

介绍了一种纳米级非接触超高精度光外差轮廓仪。该量仪是基于普通光路的外差干涉仪,两束具有微小频差的激光束照射到制件表面:其中一束光被会聚后作为测量光针扫瞄制件表面;另一束光则被用作参考光束。这两束光经反射后形成干涉,所得信号的光程差与制件表面高度变化成正比。量仪的横向分辩力小于2μm,垂直分辩力小于1nm。制件不需要进行大的调整。制件表面同时亦被作为测量参考面。经光电转换后,信号由微机处理,从而快速完成测量、计算、显示与打印各种参数与图形。     

The adjusted optical properties for Galileo/BeiDou-2/QZS-1 satellites and initial results on BeiDou-3e and QZS-2 satellites

Solar Radiation Pressure (SRP) is the dominant non-gravitational perturbation for GNSS (Global Navigation Satellite System) satellites. In the absence of precise surface models, the Empirical CODE Orbit Models (ECOM, ECOM2) are widely used in GNSS satellite orbit determination. Based on previous studies, the use of an a priori box-wing model enhances the ECOM model, especially if the spacecraft is a stretched body satellite. However, so far not all the GNSS system providers have published their metadata. To ensure a precise use of the a priori box-wing model, we estimate the optical parameters of all the Galileo, BeiDou-2, and QZS-1 (Quasi Zenith Satellite System) satellites based on the physical processes from SRP to acceleration. Validation using orbit prediction proves that the adjusted parameters of Galileo and QZS-1 satellites exhibit almost the same performance as the corresponding published and “best guess” values. Whereas, the estimated parameters of BeiDou-2 satellites demonstrate an improvement of more than 60% over the initial “guess” values. The resulting optical parameters of all the satellites are introduced into an a priori box-wing model, which is jointly used with ECOM and ECOM2 model in the orbit determination. Results show that the pure ECOM2 model exhibits better performance than the pure ECOM model for Galileo, BeiDou-2 GEO and QZS-1 orbits. Combined with the a priori box-wing model the ECOM model (ECOM+BW) results in the best Galileo, BeiDou-2 GEO and QZS-1 orbits. The standard deviation (STD) of satellite laser ranging residuals reduce by about 20% and 5% with respect to the pure ECOM2 model for Galileo and BeiDou-2 GEO orbits, while the reductions are about 40% and 60% for QZS-1 orbits in yaw-steering and orbit-normal mode respectively. BeiDou-2 IGSO and MEO satellite orbits do not benefit much from the a priori box-wing model. In summary, we suggest setting up a unified SRP model of ECOM+BW for Galileo, QZS-1, and BeiDou-2 orbits based on the adjusted metadata. In addition, we estimate the optical parameters of BeiDou-3e and QZS-2 satellites using a limited number of tracking stations. Results regarding the unified SRP model indicate the same advantages, the STD of satellite laser ranging residuals reduces by about 30% and 20% for QZS-2 and BeiDou-3e orbits respectively over orbit products without a priori model. The estimation procedure is effective and easy to apply to the new emerging satellites in the future.