时隙分配算法在CDM GDP 程序中的应用

机场容量由于恶劣天气等突发原因受到限制导致大面积航班的延误,带来了巨大的经济损失.CDM(Collaborative Decision Making) GDP(Ground Delay Procedure)就是解决这类突发情况的空中交通流量管理程序.就其核心问题——时隙分配,在现有的时隙分配算法基础上,引入航班延误损失系数,使得算法以延误损失替代延误时间,提出了2种基于该系数的时隙分配算法.最后,用java语言进行了仿真实验,引入了评判函数来选择在总延误损失和延误损失分配的公平性上最佳满足决策者要求的分配结果.      

机载图像无损/近无损压缩方案及其FPGA实现

根据机载图像压缩和传输的特点,在改进JPEG-LS算法基础上,设计了一种有效的图像无损/近无损压缩方案.该方案由去相关处理、熵编码及压缩位率控制三部分组成.去相关处理部分解决了JPEG-LS预测模型本身的误码扩散问题,熵编码部分使用快速有效的Golomb熵编码器完成对预测误差的编码,同时解决了机载应用中数据传输率恒定条件下压缩码率的控制问题.对压缩算法现场可编程门阵列(FPGA)设计中的一些关键问题也给出了有效的解决途径,从而形成了一套完整、可行的机载图像压缩解决方案.最后通过FPGA实现和验证了压缩方案及逻辑设计的正确性和可行性.      

一种新型双轴太阳帆板驱动线路盒设计

针对双轴太阳帆板驱动装置2个电机的控制要求,提出一种新型双轴帆板驱动线路盒（BSADE,biaxial solar array drive electronics）设计.该线路盒基于现有帆板驱动线路设计,通过在电机驱动线路中设计一种电流方向转换延时线路,解决了电流方向转换瞬间功率管容易对穿的问题,确保了驱动线路工作的安全性,使得原先大功率管才能实现的线路选用小功率管实现,达到了小型化目标.通过对电机驱动线路和负载绕组进行交叉重组设计,解决了主备份线路间磁耦合问题,实现了严格冷备份目标,大大提高了可靠性.     

改进FDTD／集总源模型分析航天器场线耦合

针对典型的电磁脉冲对航天器电缆耦合问题,建立了航天器场线耦合分析模型。在场分布计算方面,采用基于平均电参数和分析目标与 Yee网格不重合的边缘部分修正的改进时域有限差分法。在场线耦合方面,建立基于集总等效源模型的多导体传输线瞬态响应模型,将外场在传输线上激励的分布电压源和电流源与传输线指数矩阵解耦,建立了集总等效电压源和电流源模型。采用分析模型分析运载内一根电缆受电磁脉冲影响的响应,结果表明,即使存在屏蔽作用,电磁脉冲在电缆上耦合的干扰足以损毁设备。     

原子时自动测量及数据采集系统

介绍了普通的时间实验室的时频测量,实现自动测量和数据收集的基本系统方案,并以上海天文台原子时实验室为例介绍了实际可行的自动测量和数据收集系统,这个系统高性能、低价格,可应用于国内几乎所有的时间实验室。     

Tropospheric wet refractivity tomography using multiplicative algebraic reconstruction technique

Algebraic reconstruction techniques (ART) have been successfully used to reconstruct the total electron content (TEC) of the ionosphere and in recent years be tentatively used in tropospheric wet refractivity and water vapor tomography in the ground-based GNSS technology. The previous research on ART used in tropospheric water vapor tomography focused on the convergence and relaxation parameters for various algebraic reconstruction techniques and rarely discussed the impact of Gaussian constraints and initial field on the iteration results. The existing accuracy evaluation parameters calculated from slant wet delay can only evaluate the resultant precision of the voxels penetrated by slant paths and cannot evaluate that of the voxels not penetrated by any slant path. The paper proposes two new statistical parameters Bias and RMS, calculated from wet refractivity of the total voxels, to improve the deficiencies of existing evaluation parameters and then discusses the effect of the Gaussian constraints and initial field on the convergence and tomography results in multiplicative algebraic reconstruction technique (MART) to reconstruct the 4D tropospheric wet refractivity field using simulation method.     

单轴台的大角度姿态快速机动联合控制方法

为验证小卫星大角度姿态快速机动与高精度稳定控制能力,基于单轴气浮台硬件仿真环境,提出了一种利用推力器与飞轮组合的联合控制策略.采用相平面控制技术与有限时间控制理论设计控制器,利用推力器实现无超调的快速机动控制,利用飞轮实现有限时间内的高精度稳定控制,使单轴台在有限时间内快速高精度稳定于目标姿态.物理仿真结果表明:该方法在有限时间内完成单轴台快速稳定控制的同时,可有效避免机动过程中的超调现象,且能有效规避推力器的频繁开关与飞轮的过快饱和等问题.     

超声波流量测量中流速计算方法的对比

超声波流量计(UFM,Ultrasonic Flow Meter)通过测量管路中顺流和逆流方向的超声波传播时间变化计算流速,因此超声波传播时间的准确测量对流量计的精度影响至关重要.对超声波流量计的测量方法进行研究,从环境温度的变化、时间测量的准确性、不确定度的计算3个方面,对比超声波传播时间差法和频率差法对流量测量精度的影响.通过超声波流量测量实验,验证了在流量计未校准的情况下,与频率差法相比,时间差法的测量精度更高,且其校准系数曲线的线性度更好,校准后可在全流量范围内获得更高的测量精度.     

Demonstration of a high sensitivity GNSS software receiver for indoor positioning

Advances in signal processing techniques contributed to the significant improvements of GNSS receiver performance in dense multipath environments and created the opportunities for a new category of high-sensitivity GNSS (HS-GNSS) receivers that can provide GNSS location services in indoor environments. The difficulties in improving the availability, reliability, and accuracy of these indoor capable GNSS receivers exceed those of the receivers designed for the most hostile urban canyon environments. The authors of this paper identified the vector tracking schemes, signal propagation statistics, and parallel processing techniques that are critical to a robust HS-GNSS receiver for indoor environments and successfully incorporated them into a fully functional high-sensitivity software receiver. A flexible vector-based receiver architecture is introduced to combine these key indoor signal processing technologies into GSNRx-hs™ – the high sensitivity software navigation receiver developed at the University of Calgary. The resulting receiver can perform multi-mode vector tracking in indoor environment at various levels of location and timing uncertainties. In addition to the obvious improvements in time-to-first-fix (TTFF) and signal sensitivity, the field test results in indoor environments surrounded by wood, glass, and concrete showed that the new techniques effectively improved the performance of indoor GNSS positioning. With fine GNSS timing, the proposed receiver can consistently deliver indoor navigation solution with the horizontal accuracy of 2–15 m depending on the satellite geometry and the indoor environments. If only the coarse GNSS timing is available, the horizontal accuracy of the indoor navigation solution from the proposed receiver is around 30 m depending on the coarse timing accuracy, the satellite geometry, and the indoor environments. From the preliminary field test results, it has been observed that the signal processing sensitivity is the dominant factor on the availability of the indoor navigation solution, while the GNSS timing accuracy is the dominant factor on the accuracy of the indoor navigation solution.