基于FrFT优化窗的STFT及非线性调频信号瞬时频率估计

瞬时频率(IF)是描述非平稳调频信号最基本的参数,调频信号广泛应用于声纳、雷达、通讯和生物等领域。本文采用分数阶Fourier变换来优化STFT的窗函数,并估计非线性调频信号的瞬时频率。进行了详细的误差理论分析。同时在实验上和Wingner分布(WVD)、短时Fourier变换(STFT)进行误差(MSE)比较分析。仿真证明,FrFt优化窗STFT对估计非线性调频信号的瞬时频率具有良好的性能。     

一种新型环氧树脂体系的固化动力学及耐热性研究

通过不同升温速率下DSC研究了E51环氧树脂与DIA芳香胺固化体系的固化工艺、固化交联反应动力学参数及树脂体系的耐热性,利用FTIR方法计算了体系的固化度。通过分析确定了树脂的固化工艺,采用Kissinger、Ozawa法计算出树脂表观活化能,其均值为87.02kJ/mol,结合Crane公式求出反应级数为0.93。采用扭辫法测得玻璃化转变温度Tg=178℃。热失重曲线表明,体系的起始分解温度为364℃。     

三维热化学非平衡流动非结构网格DSMC方法及其应用

研究了过渡流域三维热化学非平衡流动DSMC方法实现的过程.以四面体非结构网格为基本单元,提出一种新型的高效搜索算法,该算法不仅可以快速跟踪模拟分子在网格之间的迁移,而且可以准确判别分子与物面是否相互作用,避免了原有算法中分子表面反射的非确定论判据.设计了适合三维DSMC方法的动态局部时间步长技术,节约了计算时间.将碰撞距离的思想引入到非结构网格上来,有效地消除了网格尺度小于三分之一平均自由程的限制.利用Foaran90的动态分配内存技术编制了适用于任意外形的通用计算程序.最后对全尺寸航天飞机高超声速绕流进行了数值试验,计算结果验证了该算法的可行性及高效性.     

固体火箭发动机试验故障分析

从工程研制角度出发，探讨了分析固体火箭发动机试验失败原因的一般方法和过程，根据某发动机试验故障的具体情况，运用这种试验故障分析方法和过程（即针对试验故障进行故障树分析，设计复审分析，数据曲线的复核复算分析和验证试验），找出造成发动机试验故障的具体原因，确定故障机理；而后针对性地采取综合技术措施，并对这些措施进行试验验证，故障归零。     

基于GPS及其与磁强计组合的姿态确定算法研究

提出了一种组合敏感器定姿算法，针对卫星上同时装备有磁强计与全球卫星定位系统（GPS）的情况，利用两者的测量信息，在卡尔曼滤波算法的基础上，对两者信息融合定姿算法进行了设计和仿真，旨在提高卫星自主定姿精度和可靠性，结果表明，组合定姿算法使姿态确定的精度得到提高。     

激波在狭缝中绕射过程研究

针对固体火箭发动机药柱存在裂纹的情况，对运动激波在狭缝中绕射传播的非定常流场进行了计算，得到了清晰的流场变化图谱，从流场图中可分辨出激波在狭缝中的传播过程。对不同深宽比的狭缝进行研究，发现流场结构存在明显差别，在深宽比较小时狭缝内压力波振荡较小，当深宽比超过一定值时狭缝内的压力波产生剧烈振荡。研究结果表明，该方法可很好地描述激波在狭缝中的传播过程。     

基于RBF网络的惯导系统初始对准

建立了惯导系统（ＩＮＳ）初始对准的线性和非线性误差模型。分析了径向基函数（ＲＢＦ）网络的结构和工作原理。研究了ＲＢＦ网代替初始对准中的卡尔曼滤波器的实现方法。通过仿真表明，用神经网络进行初始对准，既可获得与卡尔曼滤波相同的对准精度，又提高了系统的实时性。     

VentureStar… reaping the benefits of the X-33 program

Major X-33 flight hardware has been delivered, and assembly of the vehicle is well underway in anticipation of its flight test program commencing in the summer of 1999. Attention has now turned to the operational VentureStar^TM, the first single-stage-to-orbit (SSTO) reusable launch vehicle. Activities are grouped under two broad categories: (1) vehicle development and (2) market/business planning, each of which is discussed. The mission concept is presented for direct payload delivery to the International Space Station and to low Earth orbit, as well as payload delivery with an upper stage to Geosynchronous Transfer Orbit (GTO) and other high energy orbits. System requirements include flight segment and ground segment. Vehicle system sizing and design status is provided including the application of X-33 traceability and lessons learned. Technology applications to the VentureStar^TM are described including the structure, propellant tanks, thermal protection system, aerodynamics, subsystems, payload bay and propulsion. Developing a market driven low cost launch services system for the 21st Century requires traditional and non-traditional ways of being able to forecast the evolution of the potential market. The challenge is balancing both the technical and financial assumptions of the market. This involves the need to provide a capability to meet market segments that in some cases are very speculative, while at the same time providing the financial community with a credible revenue stream. Furthermore, the market derived requirements need to be assessed so as not to impose unnecessary requirements on the vehicle design that add unreasonable cost to the development of the system, yet provides the right capabilities for new markets that could be triggered by dramatically lower space transportation prices.     

KuaFu Mission

The KuaFu mission-Space Storms, Aurora and Space Weather Explorer-is an "L1+Polar" triple satellite project composed of three spacecraft: KuaFu-A will be located at L1 and have instruments to observe solar EUV and FUV emissions, and white-light Coronal Mass Ejections (CMEs), and to measure radio waves, the local plasma and magnetic field,and high-energy particles. KuaFuB1 and KuaFu- B2 will bein polar orbits chosen to facilitate continuous 24 hours a day observation of the north polar Aurora Oval. The KuaFu mission is designed to observe the complete chain of disturbances from the solar atmosphere to geospace, including solar flares, CMEs, interplanetary clouds, shock waves, and their geo-effects, such as magnetospheric sub-storms and magnetic storms, and auroral activities. The mission may start at the next solar maximum (launch in about 2012), and with an initial mission lifetime of two to three years. KuaFu data will be used for the scientific study of space weather phenomena, and will be used for space weather monitoring and forecast purposes. The overall mission design, instrument complement, and incorporation of recent technologies will target new fundamental science, advance our understanding of the physical processes underlying space weather, and raise the standard of end-to-end monitoring of the Sun-Earth system.     

太阳宁静及耀斑期间1AU附近等离子体轫致辐射研究

在太空等离子体中，尤其在等离子体内部磁场较弱时，轫致辐射是等离子体能量损失的主要机制．本文对太阳宁静及耀斑期间1AU处等离子体轫致辐射计算表明，等离子体辐射强度If的变化与辐射的电磁波频率有直接的关系．当辐射频率，接近于等离子体频率，fpe时，辐射强度显著增大．随着电磁波辐射频率的增大，辐射强度随频率增大作缓慢对数下降．辐射亮温Tb与等离子体电子温度Te、介质光深成正比．Tb与If随辐射频率变化的整体趋势一致．在相同的辐射频率情况下，太阳宁静期间If值、Tb值低于太阳耀斑期间If值、Tb值．