纤维形状对钢纤维增强的湿拌法喷射砼的影响

在喷射砼中加入钢纤维提高其延性，从而提高变形能力和抗冲击强度，通过试验研究，论证了纤维形状对钢纤维增强的湿拌法喷射砼的影响；具有较低的吸水率和可渗性孔隙率表明有充分的密实度；纤维回弹量大大减少，然而纤维回弹量看来与纤维的几何形状并无关系；纤维增强可使抗压和抗弯强度都有所提高；纤维提高了砼的延性，然而延性较低的指数对纤维的几何形状是不太敏感的，只是在较高的指数中才出现差别。     

运用进化算法优化中等PRF雷达的脉冲重复频率

本文运用进化算法选择最佳脉冲重复频率（PRF）组，在中PRF雷达的模型中使距离-多普勒盲区最小。介绍了8个和9个PRF的两个方案，该算法能确保得到的所有结果是完全可解码的并且没有盲速。我们考虑了旁瓣杂波的详细影响以及在以中等PRF模式运行的实际机载火控雷达中影响雷达PRF选择的多个技术因素。     

空间运输系统对空军卫星控制网的影响

二十多年来,空军卫星控制网(AFSCN)为许多军用航天器和发射运载器提供了实时跟踪、遥测和遥控支持。随着国防部航天任务测控要求的变化,空军卫星控制网的测控、通信和数据处理能力的扩展和现代化都已稳步增长。空间运输系统的发展促进了空军卫星控制网的发展。本文介绍了为满足空间运输系统的要求对空军卫星控制网目前已进行的和预期进行的一系列改造。     

实现零电压开关的半桥DC—DC变换器的“改变占空比PWM控制”新方案

不对称控制方案是半桥隔离DC—DC变换器实现零电压开关（ZVS）的一种途径。但是由于电压不平稳和电流分量的压力，它不适宜于宽范围的输入电压。本文提出了一个半桥隔离dc—dc变换器的新“改变占空比PWM控制”方案，可以在没有不对称代价以及不增加额外元件的情况下实现ZVS工作。因为两个开关的占空比宽度保持相等。不对称电流和电压压力问题就消除了。说明了工作原理和主要特征。实验结果证实了用所提出的“改变占空比”控制方法可以获得较高的效率，尤其是在较高的开关频率。     

宽带相参机载雷达系统的动目标检测性能

详细分析了不存在模糊的瞬时宽带（10％）相参雷达系统在空-地应用和空-空应用中的主要优点和缺点，并通过实际杂波中的目标仿真进行了验证。     

毫米波雷达的原理与应用(一)

历来最为流行的雷达工作频率都在电磁频谱上约300兆赫和35千兆赫之间,这一区域基本上包括了特高频和超高频段。然而,除远程超视距雷达以外,大多数现代雷达都工作在特高频段的高端,更为可能的是工作在超高频段的某些频率上,典型值在1千兆赫和35千     

战术应用卫星成像系统

战术成像显示试验系统（ＴＩＤＥＳ）的目标在于研制由战场指挥官控制、根据需要以合理成本发射的小型战术应用成像卫星。其成像有效载荷为两台改进型施密特相机，采用线性ＣＣＤ，在７００ｋｍ的极地太阳同步轨道上分辨率可达到５ｍ。实验表明，应用一些新技术，如采用新研制的编码本处理芯片（ＣＰＣ）的矢量量化（ＶＱ）技术将有能力在获取高质量图像的同时把图像压缩１２：１或更高，这就可减小从卫星到地面的数据传输带宽、星载     

Conversations with Rep. Ken Calvert. Interview by Frank Sietzen Jr

Rep. Calvert, chair of the House aeronautics and space subcommittee of the Science Committee, answers questions related to priorities for space in the current congressional session: the Vision for Space Exploration, development of the Crew Exploration Vehicle (CEV) and other heavy-lift launch vehicles, entrepreneurial alliances in the space transportation industry, the U.S. aerospace industry, space tourism, entrepreneurs and NASA, U.S. aeronautics research, a service mission to the Hubble Space Telescope, and priority military space programs.     

Thoracic sonography for pneumothorax: the clinical evaluation of an operational space medicine spin-off

The recent interest in the use of ultrasound (US) to detect pneumothoraces after acute trauma in North America was initially driven by an operational space medicine concern. Astronauts aboard the International Space Station (ISS) are at risk for pneumothoraces, and US is the only potential medical imaging available. Pneumothoraces are common following trauma, and are a preventable cause of death, as most are treatable with relatively simple interventions. While pneumothoraces are optimally diagnosed clinically, they are more often inapparent even on supine chest radiographs (CXR) with recent series reporting a greater than 50% rate of occult pneumothoraces. In the course of basic scientific investigations in a conventional and parabolic flight laboratory, investigators familiarized themselves with the sonographic features of both pneumothoraces and normal pulmonary ventilation. By examining the visceral–parietal pleural interface (VPPI) with US, investigators became confident in diagnosing pneumothoraces. This knowledge was subsequently translated into practice at an American and a Canadian trauma center. The sonographic examination was found to be more accurate and sensitive than CXR (US 96% and 100% versus US 74% and 36%) in specific circumstances. Initial studies have also suggested that detecting the US features of pleural pulmonary ventilation in the left lung field may offer the ability to exclude serious endotracheal tube malpositions such as right mainstem and esophageal intubations. Applied thoracic US is an example of a clinically useful space medicine spin-off that is improving health care on earth.