基于LMI的模糊增益调参控制器的设计

利用线性矩阵不等式(LMI)技术将增益调参的控制律设计转化为相应的LMI凸优化问题,结合 模糊控制和H_∞方法,给出了一种基于LMI的模糊参数化的飞控系统增益调参控制器的 设计方法,该方法解决了传统增益调参设计中以经验设计的弊病,并保证了系统的全局 稳定性及鲁棒性能要求.将该方法应用于某型飞机模型上,仿真结果表明该设计方法简便有 效,且控制器鲁棒性较好.     

PCB红外热像辐射率校准的非线性滤波方法

在印制电路板(PCB)的红外辐射诊断中,为了获得PCB表面温度的真实分布,须对PCB红外热像进行辐射率校准.将PCB表面温度的测量波形看作真实温度分布与辐射率分布的混合波形,提出一种非线性滤波方法,利用二者连续性的差异将其区分开来.讨论了作为该方法关键步骤的红外热像突变点检测的小波变换实现问题.实验结果表明该方法能够准确地估计PCB表面温度的真实分布波形.该方法还可以用于PCB红外热像的热源辨识以及对未知材料的辐射率估计中.     

飞机穿越风切变时的地速/空速控制

为解决飞机穿越风切变过程中控制系统解耦和飞行轨迹的实时/在线控制问题,对飞机纵向三自由度非线性模型,运用非线性动态逆方法,在风轴系中设计了飞行轨迹的高度变化率/空速控制模式,在地轴系中设计了高度变化率/地速控制模式.对2种控制模式进行比较并将其结合起来,得到更加完善的地速/空速控制律.仿真计算表明动态逆方法在飞机穿越风切变的轨迹控制过程中实用有效.     

采用抗积分器卷绕改进高增益PI控制器的性能

研究了饱和非线性对采用Ｓａｌｆｏｒｄ奇异摄动法设计的高增益（快采样）误差驱动ＰＩ控制器的影响，在分析了使系统性能降低的原因后，提出了抗积分器卷绕方案，以ＡＦＴＩ／Ｆ－１６直接力控制系统为例，说明了该方法是可行和有效的。     

中心或反中心对称线性方程组的缩减算法

推广了文［１，２］的概念，系统地叙述了中心对称和反中心对称矩阵的性质，导出了一类求解系数矩阵为中心对称和反中心对称线性方程组及超定方程组的缩减算法。这类算法可节省７０％－７５％的计算量，大大提高了计算效率     

实双对称矩阵的特征值问题及其反问题的降阶法

本文将实双对称矩阵的特征值问题化为阶数减半的实对称矩阵的特征值问题。并利用这个结果来求解斜对称Jacobi矩阵的特征值反问题,即构造一个斜对称Jacobi矩阵A,使之具有预先指定的特征值{λ_i}_(i=1)~n或预先指定的特征对(λ_1,x_1)和(λ_2,x_2)。     

对称矩阵反问题解的稳定性

考虑如下对称矩阵反问题：问题Ⅰ：给定Ｘ，Ｂ∈Ｒ（ｎ×ｎ），求Ａ∈ＳＲ（ｎ×ｎ）使得ＡＸ＝Ｂ，其中ＳＲ（ｎ×ｎ）＝｛｛Ａ｜Ａ∈Ｒ（ｎ×ｎ），ＡＴ＝Ａ｝。问题Ⅱ：给定，求使得其中是矩阵的Ｆｒｏｂｅｎｉｕｓ范数，ＳＡ表示问题Ⅰ的解集合。本文讨论问题Ⅰ解的稳定性，给出问题Ⅱ解的扰动界。     

Neuroimmune response and sleep studies after whole body irradiation with high-LET particles

In order to investigate the biological effects of galactic rays on astronaut cerebral functions after space flight, mice were exposed to different heavy ions (HZE) in whole-body conditions at doses comparable to the galactic flux: ¹²C, ¹⁶O and ²⁰Ne (95 MeV/u, at 42–76 mGy). Animals were also exposed to 42 mGy of ⁶⁰Co radiation for comparison with HZE. The neuroimmune response, evaluated by interleukin-1 (IL-1) measurement, showed that this cytokine was produced 3 h after irradiation by ¹⁶O or ⁶⁰Co. In contrast, neither ¹²C (56.7 mGy) nor ²⁰Ne (76 mGy) induced IL-1 production. However, immunohistochemical staining of ¹²C-irradiated mouse brain tissue showed 2 months later a marked inflammatory reaction in the hippocampus and a diffuse response in parenchyma. Sleep studies were realized before and after exposure to 42 mGy of ¹⁶O and 76 mGy of ²⁰Ne: only the ²⁰Ne radiation displayed a small effect. A slight decrease in paradoxical sleep, corresponding to a reduction in the number of episodes of paradoxical sleep, was manifested between 8 and 22 days after exposure. Exposure to ¹²C and ¹⁶O induced no changes either in cellularity of spleen or thymus, or in caspase 3 activity (as much as four months after irradiation). Taken together, these data indicate that the CNS could be sensitive to heavy ions and that responses to HZE impact depend on the nature of the particle, the dose threshold and the time delay to develop biological processes. Differences in responses to different HZE highlight the complex biological phenomena to which astronauts are submitted during space flight.     

T cell regulation in microgravity – The current knowledge from in vitro experiments conducted in space,parabolic flights and ground-based facilities

Dating back to the Apollo and Skylab missions, it has been reported that astronauts suffered from bacterial and viral infections during space flight or after returning to Earth. Blood analyses revealed strongly reduced capability of human lymphocytes to become active upon mitogenic stimulation. Since then, a large number of in vitro studies on human immune cells have been conducted in space, in parabolic flights, and in ground-based facilities. It became obvious that microgravity affects cell morphology and important cellular functions. Observed changes include cell proliferation, the cytoskeleton, signal transduction and gene expression. This review gives an overview of the current knowledge of T cell regulation under altered gravity conditions obtained by in vitro studies with special emphasis on the cell culture conditions used. We propose that future in vitro experiments should follow rigorous standardized cell culture conditions, which allows better comparison of the results obtained in different flight- and ground-based experiment platforms.     

基于线性稳定性分析的翼尖涡摇摆机制

在涡不稳定性特征的影响下，翼尖涡会在尾迹中发生摇摆运动。为了揭示翼尖涡摇摆的本质原因以及发展机理，采用体视粒子图像测速（SPIV）技术和线性稳定性分析方法对不同雷诺数和迎角下NACA0015等直翼产生的翼尖涡在尾迹区的不稳定性特征及发展进行研究。结果表明：在1~6倍弦长的尾迹区内，翼尖涡存在摇摆现象，摇摆幅值随流向放大，且摇摆运动沿流向逐渐呈现出各向异性特征；在大迎角条件下，翼尖涡摇摆幅值随流向增长更快。采用线性稳定性分析方法，定量化分析翼尖涡的稳定性、空间/时间不稳定性放大率和扰动频率随流向的发展过程。结果显示，在雷诺数2.1×10⁵~3.5×10⁵范围内，翼尖涡均处于临界稳定状态，扰动频率为3~5 Hz。基于线性稳定性分析结果，发现在大迎角条件下翼尖涡时间/空间不稳定性放大率更大，解释了当迎角增大时翼尖涡摇摆幅值随流向增长更快的现象。另外，由线性稳定性分析得到的最不稳定模态显示翼尖涡的横向速度扰动具有明显的方向性，从而诱导翼尖涡产生摇摆运动；速度扰动方向的周期性变化则使翼尖涡摇摆区别于一维的随机振荡，而是表现为在各方向均含有分量且具有主频的摇摆运动。这种由不稳定性导致的速度扰动是翼尖涡摇摆的内在机制，其不稳定性放大率控制着摇摆幅值的增长速率，而其横向速度扰动的方向性与周期性则决定了翼尖涡的摇摆特征。