汽车防抱死制动系统分析

分析了防抱死制动系统的性能与控制原理的关系。提出了系统的稳定性概念，以及用估值和顺馈补偿强干扰－地面附着力矩的方法。找到了制动效率与控制精度的关系，对防抱死制动控制系统的设计具有现实意义。     

基于周向偏置的高精度动平衡测量方法研究

在不改变动平衡机现有状态的前提下，提出了一种利用周向偏置提高动不平衡的测量精度的方法，并给出了基于立式硬支承动平衡机的理论分析和数据处理方法。通过在立式双面动平衡机上的实验验证，表明这种基于周向偏置的高精度动平衡测量方法是合理和有效的。     

空间光学精密展开机构展开方法的初步探讨

文章对空间光学精密展开机构（以下简称展开机构）进行分类，分析了几种典型可展开空间光学系统的展开方法和特点。讨论了展开机构设计需要考虑的主要因素，并给出设计建议。     

真空差压铸造微电脑控制系统的硬件设计

介绍了微电脑真空差压铸造控制系统的组成及工作原理,设计了压力检测电路、调节阀控制电路和串行通信接口电路,同时说明了系统的调试,并给出了实验结论。结果表明,该系统的硬件电路设计合理,运行情况良好,并达到了设计指标。     

关于初轨计算

初轨计算通常是指在二体问题意义下的短弧定轨,为了适应测量精度的提高和深空探测(包括月球探测)轨道器所涉及力学模型的需要,给出一种在测角资料背景下,同时适用于无摄和受摄运动的初轨计算方法。而且,该方法不仅适用于椭圆轨道,亦适用于双曲线轨道,拓宽初轨计算的传统范畴。     

利用狭缝相机实现弹丸攻角的高精度测量研究

在分析狭缝相机测量原理的基础上,重点讨论了两个设备本身无法消除的因素对高精度测量的影响,即弹丸质心运动方向与狭缝不垂直以及弹丸的影像运动速度与胶片的运动速度不相同对测量带来的影响,并分析给出解决方法。     

风洞自由飞实验结果的精度、准度

风洞自由飞实验是一项特殊的地面风洞实验,用风洞自由飞实验研究了飞行 马赫数M0.6～6.0飞行海拔高度最高达45公里范围内多个飞行器的动态气动特性。因而首 先需回答风洞自由飞实验结果的精确度、可靠性。坚持用天（飞行）——地（地面风洞 自由飞实验）一致作为评定实验结果准度、可信度最重要最终的考核 标准 。〖JP〗     

Second post-Newtonian approximation of scalar-tensor theory of gravity

Deep space laser ranging missions like ASTROD I (Single-Spacecraft Astrodynamical Space Test of Relativity using Optical Devices) and ASTROD, together with astrometry missions like GAIA and LATOR will be able to test relativistic gravity to an unprecedented level of accuracy. More precisely, these missions will enable us to test relativistic gravity to 10^-7–10^-9${10}^{-7}''–''{10}^{-9}$ of the size of relativistic (post-Newtonian) effects, and will require second post-Newtonian approximation of relevant theories of gravity. The first post-Newtonian approximation is valid to 10^-6${10}^{-6}$ and the second post-Newtonian approximation is valid to 10^-12${10}^{-12}$ in terms of post-Newtonian effects in the solar system. The scalar-tensor theory is widely discussed and used in tests of relativistic gravity, especially after the interests in inflation models and in dark energy models. In the Lagrangian, intermediate-range gravity term has a similar form as cosmological term. Here we present the full second post-Newtonian approximation of the scalar-tensor theory including viable examples of intermediate-range gravity. We use Chandrasekhar’s approach to derive the metric coefficients and the equation of the hydrodynamics governing a perfect fluid in the second post-Newtonian approximation in scalar-tensor theory; all terms inclusive of O(c^-4)$\mathrm{O}(c^{-4})$ are retained consistently in the equations of motion.     

陶瓷纤维增强梯度铝基复合材料研究

采用挤压铸造法制造的陶瓷纤维增强梯度铝基复合材料,通过观察其金相组织,测试其热学性能,并对梯度复合材料活塞顶的温度分布及隔热效果进行了计算,结果表明,采用挤压铸造法制造出的样度铝基复合材料,梯度层间纤维分布逐渐过渡无分层现象,且采用该材料制造的活塞顶具有良好的隔热效果。     

Introduction to Japanese exploration study to the moon

The Japan Aerospace Exploration Agency (JAXA) views the lunar lander SELENE-2 as the successor to the SELENE mission. In this presentation, the mission objectives of SELENE-2 are shown together with the present design status of the spacecraft. JAXA launched the Kaguya (SELENE) lunar orbiter in September 2007, and the spacecraft observed the Moon and a couple of small satellites using 15 instruments. As the next step in lunar exploration, the lunar lander SELENE-2 is being considered. SELENE-2 will land on the lunar surface and perform in-situ scientific observations, environmental investigations, and research for future lunar utilization including human activity. At the same time, it will demonstrate key technologies for lunar and planetary exploration such as precise and safe landing, surface mobility, and overnight survival. The lander will carry laser altimeters, image sensors, and landing radars for precise and safe landing. Landing legs and a precisely controlled propulsion system will also be developed. A rover is being designed to be able to travel over a wide area and observe featured terrain using scientific instruments. Since some of the instruments require long-term observation on the lunar surface, technology for night survival over more than 2 weeks needs to be considered. The SELENE-2 technologies are expected to be one of the stepping stones towards future Japanese human activities on the moon and to expand the possibilities for deep space science.