传输型光学遥感器超模式斜采样新方法研究

文章简要介绍了超模式和斜模式采样的概念,结合超模式采样技术和斜模式采样技术,提出 了一种新的传输型光学遥感器的采样方法,即超模式斜采样,该方法充分发挥了超模式和斜模式采样的优 点,在图像信噪比保持不变的情况下,地面采样间距大大缩短,遥感图像的空间分辨率可以大大提高。     

编队飞行卫星的星间跟踪与测量技术综述

论述了在卫星编队飞行中所应用的几种星间测量方法,包括GPS导航、微波雷达、激光雷达、红外和可见光相机这几种目前在航天工程应用比较成熟的方法,并粗略分析了各种方法的测量精度及可行性。     

基于GPU的干涉测量VDIF格式数据编帧方法*

为提高深空测控网VLBI基带转换器灵活性和多种数据格式适应能力,设计一种基于GPU的VDIF格式数据编帧方法。基于CUDA并行运算架构开发符合VDIF规范的帧头计算模块、多通道单线程编帧模块和多通道多线程编帧模块。为了实现编帧过程效率的优化,设计基于纹理缓存查找表的数据量化方法和基于流式架构的多帧信号异步编帧方法。试验验证表明,设计的编帧方法结果正确,高效可靠,有望为我国深空测控干涉测量数据记录系统参与国际VLBI联合观测提供有效的支持。     

机场安检人员疲劳自评量表设计及检验

通过参考国内外成熟的主观疲劳量表,结合机场安检人员岗位特点,确定影响疲劳的心理因素,编制适用于机场安检人员的疲劳自评量表(FSAS)。对回收的有效问卷数据进行信度、效度及相关性分析,结果显示:KMO为0.848,Bartlett的球形度检验的相伴概率为0,表明量表适合做因子分析;Cronbach’sа为0.908,说明量表内部具有很好的信度。结论:所编制的机场安检人员疲劳自评量表有效且可信,可为初步测量安检人员健康状态提供依据。     

亚跨超风洞现代试验设计方法研究

开展了基于现代试验设计方法(MDOE)的亚跨超风洞试验研究,以八号标模尾翼为试验对象研究其气动特性,采用同时改变攻角-侧滑角的多变量方法,而不是传统的单变量(OFAT)方法进行试验。对自变量攻角和侧滑角进行试验设计(DOE),应用响应面法建模,用IV-最优方法对测量点分布进行设计。在FD-12亚跨超风洞完成了试验,并和传统的OFAT方法结果进行比较分析。结果表明:MDOE方法获得的数据和传统的OFAT方法的数据吻合很好;MDOE采集样点数减少了46%,吹风的时间比OFAT减少30%左右,提高了风洞试验效率,缩短了试验周期;MDOE试验方法可以给出设计空间内任意给定自变量对应的响应值及其置信区间。     

教练机防水设计

通过对飞机结构需要防水部位的阐述,介绍典型结构防水措施,以减少雨水对机体腐蚀,保证飞机在寿命期内的飞行安全.     

单站无源定位中角度变化率的测量方法研究

讨论了单站无源定位中角度变化率测量的问题.首先简要介绍了差分法、最小二乘拟合法和卡尔曼滤波法的测量原理,其次为了解决滤波模型非线性的影响,提出了一种并行分段处理的卡尔曼滤波方法,最后从数字滤波的角度,通过设计相应的低通滤波器对估计获得的角度变化率数据流进行处理,进一步提高了角度变化率的测量精度.仿真实验对比分析了所述几...     

对地观测旋转扫描辐射计星上定标系统设计

文中介绍了一种对地观测旋转扫描辐射计星上定标系统的设计。该星上定标系统由漫射板、定标灯、黑体、定标均衡装置、漫射板稳定性监测器和太阳入射角监测器等几部分组成。文中描述了该定标系统各部分的作用和功能,并针对提高星上定标精度提了几点建议。     

Numerical investigation on the shock wave transition in a three-dimensional scramjet isolator

The scramjet isolator, which is used to prevent the hypersonic inlet from disturbances that arise from the pressure rise in the scramjet combustor due to the intense turbulent combustion, is one of the most critical components in hypersonic airbreathing propulsion systems. Any engineering error that is possible in the design and manufacturing procedure of the experimental model, and the intense heat release in the scramjet combustor, may cause the performance of the isolator to decrease, leading to its lack of capability in supporting the back pressure. The coupled implicit Reynolds Averaged Navier–Stokes (RANS) equations and the two-equation standard k?ε turbulent model have been employed to numerically simulate the flow fields in a three-dimensional scramjet isolator. The effects of the divergent angle and the back pressure on the shock wave transition and the location of the leading edge of the shock wave train have been estimated and discussed. The obtained results show that the present numerical results are in very good agreement with the available experimental shadow-pictures, and the numerical method is more suitable for capturing the shock wave train and predicting the location of the leading edge of the shock wave train in the scramjet isolator than the present two-dimensional numerical methods. This is due to the small width-to-height ratio of the isolator and the intense three-dimensional flow structures. On increasing the divergent angle of the scramjet isolator, the static pressure along the central symmetrical line of the isolator decreases sharply. This is due to the strong expansion wave generated at the entrance of the isolator, and when the divergent angle of the isolator is sufficiently large, namely 1.5°, a zone of negative pressure is formed just ahead of the leading edge of the shock wave train. At the same time, the shock wave train varies from being oblique to being normal, and then back to oblique. With an increase in the prescribed back pressure at the exit of the scramjet isolator, the leading edge of the shock wave train moves forward towards the entrance of the isolator, and when the back pressure is sufficiently large, unstart conditions in the hypersonic inlet can take place if the shock train reaches the inlet.