Simplified procedure for controlling pressure distribution of a scramjet combustor

Scramjet engines are used at extreme temperatures and velocity. New control problems involving distributed parameter control have been found concerning investigations of the control of scramjet engines whose physical states are spatially interacted. Succeeding the existing theoretical studies on the distributed parameter control for scramjet engines, this paper puts forward a simplified distributed parameter control approach for scramjet engines aimed at engineering application. The simplified control procedure uses the classical proportional-integral（PI） compensation to control the target pressure distribution of scramjet engines, which is effective and applicable for practical implements. Simulation results show the validation of the simplified distributed parameter control procedure.     

Changing law of launching pitching angular velocity of rotating missile

In order to provide accurate launching pitching angular velocity（LPAV） for the exterior trajectory optimization design, multi-flexible body dynamics（MFBD） technology is presented to study the changing law of LPAV of the rotating missile based on spiral guideway. An MFBD virtual prototype model of the rotating missile launching system is built using multi-body dynamics modeling technology based on the built flexible body models of key components and the special force model.The built model is verified with the frequency spectrum analysis. With the flexible body contact theory and nonlinear theory of MFBD technology, the research is conducted on the influence of a series of factors on LPAV, such as launching angle change, clearance between launching canister and missile,thrust change, thrust eccentricity and mass eccentricity, etc. Through this research, some useful values of the key design parameters which are difficult to be measured in physical tests are obtained. Finally,a simplified mathematical model of the changing law of LPAV is presented through fitting virtual test results using the linear regression method and verified by physical flight tests. The research results have important significance for the exterior trajectory optimization design.     

一种基于MBSE的小卫星测控分系统建模设计方法

基于模型的系统工程MBSE思想和信息化手段,以模型为核心、关系追溯为手段,集合测控分系统技术指标、设计经验等知识信息,提出一种基于MBSE的小卫星测控分系统建模设计解决方案。利用模型承载文档,显性化经验、信息、关系,形成基于模型的知识管理工具,提高工作效率,解放设计师,实现知识经验的数字化模型化承载,为小卫星测控分系统由经验设计向仿真设计转变,由基于文档到基于模型的研制模式转变,由实物验证向虚拟和实物验证相结合转变进行了探索和尝试。     

用于EMI测量接收机脉冲响应校准的标准脉冲信号产生方法

EMI测量接收机作为电磁兼容测试中的关键仪器应用越来越广泛，但目前该类仪器的脉冲响应校准所用的标准源完全依赖于进口，国内尚无可替代的标准脉冲信号产生器。介绍一种用于EMI测量接收机脉冲响应校准的标准脉冲信号产生方法，首先建立标准脉冲信号的参数模型并对其进行数值分析和仿真，验证其符合CISPR 16-1-1标准的要求，之后搭建实验系统，利用标准脉冲信号生成软件控制任意脉冲信号发生器输出标准脉冲信号并对其进行补偿修正，获得符合CISPR 16-1-1标准要求的标准脉冲信号，该信号可用于EMI测量接收机脉冲响应的校准。     

液体火箭发动机推力自动校准系统仿真

针对液体火箭发动机原位校准高准确度的要求,介绍了一种以伺服电机为执行部件,基于液压传动力值自动加载装置,阐述了该系统的结构和工作原理。建立系统数学模型,通过Matlab和AMEsim搭建了系统的仿真模型,在分析影响模拟推力加载准确度和稳定性的基础上,设计了模糊PID控制器。仿真结果表明:所设计的力值加载系统能够完成力值精确加载,(0~6)kN力值加载时间小于30 s,加载力的示值最大误差为±0.05%,满足校准力值加载需求。证明了在力值加载系统中引入模糊PID控制算法,可以有效补偿系统中的不确定性扰动,增强系统的鲁棒性。     

Experimental and modeling study of surface topography generation considering tool-workpiece vibration in high-precision turning

High-precision turning(HPT) is a main processing method for manufacturing rotary high-precision components, especially for metallic parts. However, the generated vibration between tool tip and workpiece during turning may seriously deteriorate the surface integrity. Therefore,exploring the effect of vibration on turning surface morphology and quality of copper parts using3D surface topography regeneration model is crucial for predicting HPT performance. This developed model can update the machin...     

A review of bird-like flapping wing with high aspect ratio

Bird-like flapping-wing vehicles with a high aspect ratio have the potential to fulfill missions given to micro air vehicles, such as high-altitude reconnaissance, surveillance, rescue, and bird group guidance, due to their good loading and long endurance capacities. Biologists and aeronautical researchers have explored the mystery of avian flight and made efforts to reproduce flapping flight in bioinspired aircraft for decades. However, the cognitive depth from theory to practice is still very limited. The mechanism of generating sufficient lift and thrust during avian flight is still not fully understood. Moving wings with unique biological structures such as feathers make modeling, simulation, experimentation, and analysis much more difficult. This paper reviews the research progress on bird-like flapping wings from flight mechanisms to modeling. Commonly used numerical computing methods are briefly compared. The aeroelastic problems are also highlighted. The results of the investigation show that a leading-edge vortex can be found during avian flight. Its induction and maintenance may have a close relationship with wing configuration, kinematics and deformation. The present models of flapping wings are mainly two-dimensional airfoils or three-dimensional single root-jointed geometric plates, which still exhibit large differences from real bird wings. Aeroelasticity is encouraged to consider the nonignorable effect on aerodynamic performance due to large-scale nonlinear deformation. Introducing appropriate flexibility can improve the peak values and efficiencies of lift and thrust, but the detailed conclusions always have strong background dependence.     

雷达目标特性仿真VV&A方法研究

仿真系统的校核、验证和确认（VV&A）是建模仿真可信度评估工作的基础，直接决定了仿真结果的有效性，必须应用于建模仿真的全周期内。详细分析了目前国内外VV&A在目标特性建模仿真中的研究进展，分别介绍了VV&A在雷达目标特性仿真中的应用研究和VV&A对于提高雷达目标特性仿真可信度的思路及方法，对后续雷达目标特性仿真VV&A研究具有指导意义。