低雷诺数下小展弦比机翼的气动力优化设计

以固定翼式微型飞行器为研究背景,针对小展弦比机翼,将遗传算法与Navier-Stokes方程数值解法相结合,提出了一种以实数编码为基础的数值优化模型.流场数值模拟采用人工压缩方法,遗传算法采用锦标赛选择、自适应交叉和变异操作算子,对微型飞行器机翼选取五个设计点分别进行了升阻比优化设计.优化结果表明,本文的优化模型具有较高的搜索效率和显著的优化效果,五个设计点机翼的升阻比均提高30%以上.优化后的翼面接近椭圆形状,翼型前缘钝厚,尾缘向上拱起,这种形状能大大增加升力,降低诱导阻力,从而显著提高机翼的气动性能.     

弯曲/倾斜叶片对大展弦比涡轮气动性能影响

为了获得弯曲/倾斜导叶对大展弦比低压涡轮气动性能的影响,通过求解基于耦合转捩SST湍流模型的雷诺平均N-S方程组,对GE-E3低压涡轮叶栅的进行了全三维粘性定常与非定常数值模拟。研究了弯曲/倾斜导叶对涡轮级效率的影响,分析了对导叶叶栅气动性能、导叶扩散因子与边界层发展的作用,以及对下游动叶气动性能和动叶吸力面流动特性的影响。结果表明,正弯导叶减小了二次流损失却带了更大的叶型损失,降低了涡轮级效率,而正倾斜改变了上下端壁的二次流损失分配,对总的叶型损失影响较小,在一定角度下能够改善大展弦比涡轮叶栅的气动性能。     

基于仿生的大展弦比机翼结构布局形式研究

为了探讨大展弦比直机翼的结构布局形式,本文借鉴自然界中的鱼骨与树叶的叶脉形式,利用有限元分析与满应力优化作为设计手段,对3种不同的结构布局形式(A构型、B构型和常规构型)开展基于强度、刚度以及质量条件限制下有关响应的对比研究。计算结果表明:在不同尺度的等质量条件限制下,“A构型”弯曲刚度最大,扭转刚度居中;“B构型”弯曲刚度居中,扭转刚度最小;“常规构型”弯曲刚度最小,扭转刚度最大。分析结果证明,机翼的翼肋布置应该“适当地”倾斜。最后给出3点结论。     

数字匹配滤波器在直序扩频快速捕获中的应用

数字匹配滤波器(DMF)也称数字相关器,本文对DMF的工作原理做了简要的分析,给出了实现DMF的几种常见的结构,然后给出了DMF的实现过程,着重对DMF在部分并行捕获中的应用做了详细的描述。     

Type II Solar Radio Bursts: Theory and Space Weather Implications

Recent data and theory for type II solar radio bursts are reviewed, focusing on a recent analytic quantitative theory for interplanetary type II bursts. The theory addresses electron reflection and acceleration at the type II shock, formation of electron beams in the foreshock, and generation of Langmuir waves and the type II radiation there. The theory's predictions as functions of the shock and plasma parameters are summarized and discussed in terms of space weather events. The theory is consistent with available data, has explanations for radio-loud/quiet coronal mass ejections (CMEs) and why type IIs are bursty, and can account for empirical correlations between type IIs, CMEs, and interplanetary disturbances. This revised version was published online in August 2006 with corrections to the Cover Date.     

软件无线电的可重构流处理器体系结构

 针对软件无线电中存在通用数字信号处理器（DSP）计算能力不足以及专用基带处理器缺乏扩展性的问题,提出了一种新的处理器：面向软件无线电的可重构流处理器及相应的专用指令集。仿真证明,该处理器的可重构设计具备指令集扩展能力,可以对多种无线通信标准甚至是新的通信标准提供支持;面向软件无线电的流体系结构和专用指令集保证了对多种高速无线基带信号的实时处理,运算能力是通用DSP的5~13倍。该处理器为软件无线电中的硬件设计难题提供了一种新的解决途径。     

Solar Sources of Heliospheric Energetic Electron Events—Shocks or Flares?

Electrons with near-relativistic (E≳30 keV, NrR) and relativistic (E≳0.3 MeV) energies are often observed as discrete events in the inner heliosphere following solar transient activity. Several acceleration mechanisms have been proposed for the production of those electrons. One candidate is acceleration at MHD shocks driven by coronal mass ejections (CMEs) with speeds ≳1000 km s⁻¹. Many NrR electron events are temporally associated only with flares while others are associated with flares as well as with CMEs or with radio type II shock waves. Since CME onsets and associated flares are roughly simultaneous, distinguishing the sources of electron events is a serious challenge. On a phenomenological basis two classes of solar electron events were known several decades ago, but recent observations have presented a more complex picture. We review early and recent observational results to deduce different electron event classes and their viable acceleration mechanisms, defined broadly as shocks versus flares. The NrR and relativistic electrons are treated separately. Topics covered are: solar electron injection delays from flare impulsive phases; comparisons of electron intensities and spectra with flares, CMEs and accompanying solar energetic proton (SEP) events; multiple spacecraft observations; two-phase electron events; coronal flares; shock-associated (SA) events; electron spectral invariance; and solar electron intensity size distributions. This evidence suggests that CME-driven shocks are statistically the dominant acceleration mechanism of relativistic events, but most NrR electron events result from flares. Determining the solar origin of a given NrR or relativistic electron event remains a difficult proposition, and suggestions for future work are given.     

小展弦比飞翼布局作战飞机垂直面机动性研究

比较分析了某小展弦比飞翼布局作战飞机与典型的常规布局战斗机F16在亚、跨、超声速范围的气动特性,相对而言,飞翼布局飞机具有较大的升阻比和较低的翼载荷.计算并分析了该飞翼布局作战飞机与F16在垂直机动面内的平飞加速性能和跃升性能,得到了由于布局和气动特性不同引起的飞翼布局作战飞机机动性的新特点.研究结果对飞翼布局作战飞机的设计和作战使用均具有一定的参考意义.     

穿越微下冲气流的飞翼布局无人机控制方法

微下冲气流是最危险的低空风切变形式,为在起降阶段安全穿越该气流,飞翼布局的无人机控制律应具有快速响应能力和良好的鲁棒性。针对大展弦比飞翼布局无人机舵面附加升力大和低速状态俯仰操纵效能低的特点,提出了舵面附加升力和机体气动力相结合的复合控制方案,改进了以输出误差为参考量的非线性指令分配策略,设计了基于迎角保护的指令分配策略。将风干扰和模型的不确定性视为未知扰动,采用自抗扰控制(ADRC)理论设计飞翼布局无人机非线性控制律,使之对风干扰和模型的不确定性进行估计补偿。仿真结果表明,复合控制与ADRC相结合的方法加速了航迹倾角的单位阶跃响应速度,使上升时间缩短了64%,同时能够实现对风干扰的有效观测和补偿,使高度损失低于2m;能够在风切变中有效保护迎角,使其维持在5.5°以内。因此,该方法能够为飞翼布局无人机安全平稳地穿越微下冲气流提供一种参考方案。     

无线电高度表信号模拟器射频信号延时/衰减模块设计

无线电高度表程控信号模拟器是无线电高度表自动测试系统（ATE,ATS）的重要组成部分,而射频信号延时/衰减模块则是无线电高度表程控信号模拟器3个功能模块组件中的核心模块。研制了一种采用声表面波（SAW）延迟线作为射频信号延时器件、射频衰减器作为射频信号功率衰减器件,通过程控射频开关控制不同声表面波延迟线的切换,包含射频信号变频、放大等结构电路的无线电高度表信号模拟器射频信号延时/衰减模块。经无线电高度表自动测试系统的实际工程应用表明,该无线电高度表射频信号延时/衰减模块对C波段（4.2～4.4 GHz）射频调制信号的延时精度高、衰减范围大,体小、质轻,适合置于无线电高度表测试适配器内部使用,具有较高的工程应用价值。