一种非周期调制直扩信号扩频码估计方法

对卫星测控中一类扩频码周期与信息码周期之比为非整数的直扩信号进行了研究,得出这类信号可建模成非周期调制直扩信号,提出并讨论了一种基于差分主元分析（D PCA）的非周期调制直扩信号扩频码估计方法,该方法通过计算与差分序列协方差矩阵的最大特征值对应的特征向量完成信息码个数、子序列、信息码同步点等参数的估计,解决了传统矩阵分解方法在估计码序列时码序列相位模糊问题,理论分析和仿真结果表明该方法可以在低信噪比下进行有效估计。     

卫星设计过程信息分析的方法研究

在综合分析现有卫星设计信息分析技术的基础上,将总体数据规划的思想引入卫星设计过程的信息分析,提出了一种利用信息工程论下的总体数据规划和并行工程下的设计结构矩阵相结合的技术进行卫星设计信息分析的新方法。深入讨论了从任务分析着手构建数据模型的思想,研究了设计结构矩阵的分解和撕裂算法,并以卫星总体设计方案阶段为例,具体说明在这种方法指导下,如何实现卫星设计的信息分析。     

航空树脂基复合材料技术发展

通过介绍我国航空树脂基复合材料的发展现状和应用情况,讨论并分析了航空树脂基复合材料未来的发展趋势和重点方向,强调了这种“低成本”、“工程化”技术应在“一体化”思想指导下综合协调发展。     

基于LMI的不确定线性系统观测器设计

研究了不确定线性系统的观测器设计问题。利用凸优化理论将基于线性矩阵不等８式（ ＬＭＩ）的观测器设计转换为鲁棒控制器设计,给出了标准的ＬＭＩ形式。采用该方法的设计过程只需求解三个线性矩阵不等式就可得到鲁棒控制器。在航空发动机控制应用中表明,基于ＬＭＩ的观测器对于具有干扰的系统仍然能保持系统稳定,数值仿真表明控制效果优于文献「１」的结果。     

碳/碳复合材料用基体先驱体研究进展

综述了碳／碳复合材料用基体先驱体如沥青、酚醛树脂、邻苯二甲腈树脂和炔类树脂的合成及改性研究。为开发新一代低成本、高性能碳／碳复合材料提供了方向。     

典型散射体低频特性估计

本文探讨了几种典型金属物体的低频散射问题。介绍了低频散射截面的计算方法；对计算结果进行了分析；并就雷达目标低频散射特性提出了作者的观点。     

GPS 定位算法研究

给出卫星信号接收时刻ＧＰＳ时的计算方法，然后在Ｇａｕｓｓ－Ｎｅｗｔｏｎ法的基础上得到一个正常情况下的完整的ＧＰＳ迭代定位算法。最后讨论只有三颗可见卫星时的处理方法。     

伴随矩阵的秩

本文研究ｎ 阶矩阵与其伴随矩阵的秩的关系，得到伴随矩阵的秩的重要结论，并给出其应用。     

Friction Stir Welding of Metal Matrix Composites for use in aerospace structures

Friction Stir Welding (FSW) is a relatively nascent solid state joining technique developed at The Welding Institute (TWI) in 1991. The process was first used at NASA to weld the super lightweight external tank for the Space Shuttle. Today FSW is used to join structural components of the Delta IV, Atlas V, and Falcon IX rockets as well as the Orion Crew Exploration Vehicle. A current focus of FSW research is to extend the process to new materials which are difficult to weld using conventional fusion techniques. Metal Matrix Composites (MMCs) consist of a metal alloy reinforced with ceramics and have a very high strength to weight ratio, a property which makes them attractive for use in aerospace and defense applications. MMCs have found use in the space shuttle orbiter's structural tubing, the Hubble Space Telescope's antenna mast, control surfaces and propulsion systems for aircraft, and tank armors. The size of MMC components is severely limited by difficulties encountered in joining these materials using fusion welding. Melting of the material results in formation of an undesirable phase (formed when molten Aluminum reacts with the reinforcement) which leaves a strength depleted region along the joint line. Since FSW occurs below the melting point of the workpiece material, this deleterious phase is absent in FSW-ed MMC joints. FSW of MMCs is, however, plagued by rapid wear of the welding tool, a consequence of the large discrepancy in hardness between the steel tool and the reinforcement material. This work characterizes the effect of process parameters (spindle speed, traverse rate, and length of joint) on the wear process. Based on the results of these experiments, a phenomenological model of the wear process was constructed based on the rotating plug model for FSW. The effectiveness of harder tool materials (such as Tungsten Carbide, high speed steel, and tools with diamond coatings) to combat abrasive wear is explored. In-process force, torque, and vibration signals are analyzed to assess the feasibility of on-line monitoring of tool shape changes as a result of wear (an advancement which would eliminate the need for off-line evaluation of tool condition during joining). Monitoring, controlling, and reducing tool wear in FSW of MMCs is essential to the implementation of these materials in structures (such as launch vehicles) where they would be of maximum benefit.     

Inverted decoupling and LMI-based controller design for a turboprop engine with actuator dynamics

The main objective of the turboprop engine control system is to ensure propeller absorbed power at a constant propeller speed by controlling fuel flow and blade angle. Since each input variable affects the selected output variables, there exist strong interactions between different control loops of a Two-Spool TurboProp Engine (TSTPE). Inverted decoupling is used to decouple the interactions and decompose the TSTPE into two independent single-input single-output systems. The multi-variable PI controller and two single-variable PI controllers are designed for the TSTPE with actuator dynamics based on Linear Matrix Inequality (LMI), respectively, which is derived from static output feedback and pole placement condition. The step responses show that due to the difference in the response times of the selected output variables, it is difficult to design an appropriate multi-variable PI controller. The designed single-variable PI controllers are tested on the TSTPE integrated model to illustrate the effectiveness of the proposed method, that is, the interactions are first decoupled and then the controllers are designed, and the resulting simulated responses show that compared with the controller designed without actuator dynamics, the gas-generator shaft speed and power turbine shaft speed can better track their respective commands under the action of the controller designed with actuator dynamics.