空间坐标转换技术的分析与研究(一)

系统分析了空间坐标转换的不同形式及其相互关系,运用旋转矩阵理论作了较为深入的探讨,指出了使用中应注意的问题。提出了齐次矩阵,微分算子及雅可比阵矩等有用概念,作为例子,讨论了这些概念在机器人学中的应用。     

硅微陀螺平板结构的压膜阻尼研究

压膜阻尼对硅微陀螺的精度具有重要影响。平板结构是硅微陀螺中一种典型结构,本文通过对雷诺方程的推导,得出平板在正弦规律小振幅刚性运动时的阻尼力解析式,并给出低频时阻尼系数的近似算法。利用Matlab和CoventorWare软件对运动平板的阻尼进行仿真计算,得出运动平板的阻尼系数和刚度系数,并分析平板参数对阻尼系数及刚度系数的影响。建立不同类型的带孔平板模型,通过比较可以看出,当阻尼孔按一定方式排列时,可以降低结构的阻尼。     

纳米精度光学非球面研磨、抛光技术

介绍了高精度光学非球面的研磨、抛光技术与计算机控制水平、机械设计能力等相关领域的发展。     

飞行器控制系统的高精度计算方法

对于连续时间线性二次最优控制问题，在动力学方程和价值泛函的基础上，给出其全状态下的微分方程，进而将精细时程积分法引入上述问题，其优点为，放弃了传统的差分算法，使计算过程既简便又稳定；避免了Ｒｉｃｃａｔｉ代数方程的求解；具有非常高的计算精度。通过对某飞行器控制系统的计算，充分说明了上述特色。     

基于复杂型面薄壁零件成形的电铸试验研究

 在航空、航天领域存在诸如风洞喷管、波导元件和叶片电极等异型薄壁零件,采用常规加工方法对这些薄壁零件进行加工时存在着难加工的问题,利用一种新型的电铸技术——阴极平动式游离粒子辅助磨擦电铸技术对其进行直接成形加工。在电铸过程中,阴阳极之间添加不导电的游离粒子,随着阴极的不断运动,游离粒子能够周期性地对电沉积层产生磨擦、抛光、挤压作用,以此来提高表面质量,强化电铸层。与传统电铸技术所制备的电铸镍层进行了对比试验,试验结果表明：游离粒子辅助磨擦电铸技术能够获得表面光亮、平整电铸层;电铸层（200）晶面的衍射强度明显降低,（111）和（220）晶面的衍射强度显著提高;电铸层的机械性能也得到了明显的改善,显微硬度和抗拉强度比传统电铸工艺提高了一倍左右。以此为基础,成功制备了复杂型面叶片阴极,其显微硬度和表面粗糙度都得到了明显改善。     

基于相位单差精密测速的动态精密单点定位算法

利用相邻历元间的载波相位单差可求得动态载体的高精度三维速度向量,基于此提出了可精确描述载体运动变化的扩展卡尔曼滤波动态精密单点定位算法。该算法克服了高动态条件下采用简化动力学模型可能引起的系统状态描述失实问题,同时还可输出动态载体的精密速度信息。飞机动态试验结果表明,用该算法的动态单点定位结果与TRACK双差解计算互差得到的三维RMS值,平面分量精度优于3cm,高程分量精度优于6cm,速度测量精度可达mm/s级。     

大动态大带宽数字接收机设计实现

大动态数字接收机是机场场面监视雷达的重要组成部分。论证了大动态、大带宽系统参数的选取,数字滤波器的MATLAB仿真设计,采用16位模数转换器,大容量FPGA构建数字接收机平台,解决了大动态、大带宽采样及其数字下变频处理问题,并高速光纤传输数据,给出设计分析及测试结果,该结果表明,信噪比满足系统动态范围的要求。该电路相对于模拟接收机有较高的性能,为现代雷达提供了一种高性能的数字接收机的解决方案,具有广泛的应用前景。     

卫星星座整网轨道确定分析与仿真

编队飞行的卫星或卫星星座对轨道确定自主性和精度提出了较高要求。针对这个问题,通过建立星座的轨道动力学模型和星间观测的测量模型,将星座中的星间观测数据和地面观测数据融合起来,将待估的卫星轨道参数和部分动力学参数进行适当的分类,研究卫星星座整网轨道确定的新方法,并在理论上分析了整网定轨方法能提高定轨精度的原因;最后采用自主开发的卫星星座整网轨道确定软件进行了仿真计算。计算表明,该方法能有效地减少对地面站的依赖,并较大幅度提高定轨时卫星绝对位置和相对位置精度。
     

Near real-time estimation of tropospheric water vapour content from ground based GNSS data and its potential contribution to weather now-casting in Austria

The importance of high resolution meteorological analysis of the atmosphere increased over the past years. A detailed analysis of the humidity field is an important precondition for a better monitoring of local and regional extreme precipitation events and for forecasts with improved spatial resolution. For this reason, the Austrian Meteorological Agency (ZAMG) is operating the spatial and temporal high resolution INCA system (Integrated Now-casting through Comprehensive Analysis) since begin of 2005. Errors in this analysis occur mainly in the areas of rapidly changing and hard to predict weather conditions or rugged topography with extreme differences in height such as the alpine area of Austria. The aim of this work is to provide GNSS based measurements of the tropospheric water vapour content with a temporal resolution of 1 h and a temporal delay of less than 1 h to assimilate these estimates into the INCA system. Additional requirement is an accuracy of better than 1 mm of the precipitable water (PW) estimates.     

The International DORIS Service (IDS): Toward maturity

DORIS is one of the four space-geodetic techniques participating in the Global Geodetic Observing System (GGOS), particularly to maintain and disseminate the Terrestrial Reference Frame as determined by International Earth rotation and Reference frame Service (IERS). A few years ago, under the umbrella of the International Association of Geodesy, a DORIS International Service (IDS) was created in order to foster international cooperation and to provide new scientific products. This paper addresses the organizational aspects of the IDS and presents some recent DORIS scientific results. It is for the first time that, in preparation of the ITRF2008, seven Analysis Centers (AC’s) contributed to derive long-term time series of DORIS stations positions. These solutions were then combined into a homogeneous time series IDS-2 for which a precision of less than 10 mm was obtained. Orbit comparisons between the various AC’s showed an excellent agreement in the radial component, both for the SPOT satellites (e.g. 0.5–2.1 cm RMS for SPOT-2) and Envisat (0.9–2.1 cm RMS), using different software packages, models, corrections and analysis strategies. There is now a wide international participation within IDS that should lead to future improvements in DORIS analysis strategies and DORIS-derived geodetic products.