基于SIMICS的ICP系统模块仿真技术研究

随着机载综合化航电系统的日益复杂,航电系统中软件的开发和验证也日益困难.通过研究基于SIMICS的仿真平台及二次建模技术,建立了综合核心处理机(ICP)中几种通用功能模块(CFM)的仿真模型,为系统软件和应用软件的开发、调试、测试、综合等提供了一套虚拟仿真环境,实现了软硬件协同开发,缩短了项目研制周期,提高了工作效率和软件质量,较大地提升了复杂机载软件产品的研制能力.     

地面飞行模拟器动力学建模与应用研究

地面飞行模拟器的训练效果主要取决于动力学建模的逼真度和满足正常/特殊情况飞行任务的程度。首先,分析了影响飞机动力学特性和飞行员操作各个因素的相互关系,旨在从任务飞行、故障飞行和特殊环境条件飞行三方面拓展地面飞行模拟器的模拟能力;其次,进行了飞机空中编队、方向舵故障、雨中飞行以及非线性起落架减振支柱的仿真。研究结果表明,拓展地面飞行模拟器的应用范围是实际飞行的需要且技术可行,关注细节的部件建模更是提高地面飞行模拟器逼真度和可信度的关键。     

基于CCFHTLS算法的异步电动机转子故障检测

定子电流经低通滤波器处理后产生高斯有色噪声,限制了异步电机转子故障检测算法的辨识精度。针对该问题,提出一种抑制高斯有色噪声的异步电机故障检测技术。首先对采集到的定子电流进行预处理,利用逆同步旋转变换剔除基波,避免了直接检测时基波对故障辨识精度的影响。然后利用互相关函数(CCF)处理技术对高斯有色噪声的抑制作用,提出基于CCFHTLS算法的电机转子故障诊断技术。针对异步电机转子断条和偏心故障的识别进行试验,结果表明CCFHTLS算法可以有效抑制高斯有色噪声,并保留故障有用信息,显著地提高了故障检测的分辨率。     

基于小波变换和支持向量机的开关电流电路故障诊断新方法

针对开关电流(Switched current,SI)电路的故障诊断和定位问题，为进一步提高故障诊断准 确率，提出了基于小波变换和粒子群优化(Particle swarm optimization，PSO)支持向量机 (Support vector machine，SVM)的开关电流电路故障诊断新方法。该方法首先对节点电流 信号进行蒙特卡罗分析，然后通过小波分解计算分形维数，再利用核主元分析（Kernel pri ncipal component analysis，KPCA）降低特征值维数，实现最优故障特征的提取。最后通 过PSO SVM完成对各种故障模式的分类。对六阶切比雪夫低通滤波器进行了仿真实验验证， 获取了较高的故障诊断准确率，与其他方法进行比较，实验结果显示了本文方法的优越性。     

某型飞机大修中冷液系统常见故障排除方法

从实际工作经验出发，总结了一整套针对某型飞机液压系统和冷气系统常见机械故障的判断、分析、查找及排除方法。     

Behavior and functional modeling methods of doubly salient electromagnetic generators for aircraft electrical power system applications

The Doubly Salient Electromagnetic Generator(DSEG) is a promising candidate in aircraft generator application due to the simplicity, robustness and reliability. However, the field windings and the armature windings are strongly coupled, which makes the inductance characteristics non-linear and too complex to model. The complex model with low precision also leads to difficulties in modeling and analysis of the entire aircraft Electrical Power System(EPS). A behavior level modeling method based on modified inductance Support Vector Machine(SVM) is proposed. The Finite Element Analysis(FEA) inductance data are modified based on the experiment results to improve the precision. A functional level modeling method based on input–output characteristics SVM is also proposed. The two modeling methods are applied to a 9 kW DSEG prototype. The steady state and transient process precision of the proposed methods are proved by comparing with the experiment results. Meanwhile, the modeling time consumption, the application time consumption and the calculation resource demand are compared. The DSEG behavior and functional modeling methods provide precious results with high efficiency, which accelerates theoretical analysis and expands the application foreground of the DSEG in the aircraft EPS.     

Geometric error analysis of an over-constrained parallel tracking mechanism using the screw theory

This paper deals with geometric error modeling and sensitivity analysis of an overconstrained parallel tracking mechanism. The main contribution is the consideration of overconstrained features that are usually ignored in previous research. The reciprocal property between a motion and a force is applied to tackle this problem in the framework of the screw theory. First of all, a nominal kinematic model of the parallel tracking mechanism is formulated. On this basis, the actual twist of the moving platform is computed through the superposition of the joint twist and geometric errors. The actuation and constrained wrenches of each limb are applied to exclude the joint displacement. After eliminating repeated errors brought by the multiplication of wrenches, a geometric error model of the parallel tracking mechanism is built. Furthermore,two sensitivity indices are defined to select essential geometric errors for future kinematic calibration. Finally, the geometric error model with minimum geometric errors is verified by simulation with SolidWorks software. Two typical poses of the parallel tracking mechanism are selected, and the differences between simulation and calculation results are very small. The results confirm the correctness and accuracy of the geometric error modeling method for over-constrained parallel mechanisms.     

A data-driven approach to modeling high-density terminal areas: A scenario analysis of the new Beijing,China airspace

Airports are being developed and expanded rapidly in China to accommodate and pro-mote a growing aviation market. The future Beijing Daxing International Airport (DAX) will serve as the central airport of the JingJinJi megaregion, knitting the Beijing, Tianjin, and Hebei regions together. DAX will be a busy airport from its inception, relieving congestion and accommodating growth from Beijing Capital International Airport (PEK), currently the second busiest airport in the world in passengers moved. We aim to model terminal airspace designs and possible conflicts in the future Beijing Multi-Airport System (MAS). We investigate standard arrival procedures and mathematically model current and future arrival trajectories into PEK and DAX by collecting large quantities of publicly available track data from historical arrivals operating within the Beijing terminal airspace. We find that (1) trajectory models constructed from real data capture aberrations and deviations from standard arrival procedures, validating the need to incorporate data on histor-ical trajectories with standard procedures when evaluating the airspace and (2) given all existing constraints, DAX may be restricted to using north and east arrival flows, constraining the capacity required to handle the increases in air traffic demand to Beijing. The results indicate that the termi-nal airspace above Beijing, and the future JingJinJi region, requires careful consideration if the full capacity benefits of the two major airports are to be realized.     

基于NFTET的高超声速飞行器鲁棒轨迹重构设计

考虑高超声速飞行器故障下安全再入飞行问题，针对飞行器发生较大故障的情况，提出了基于相邻可行轨迹存在定理(Neighboring feasible trajectory existence theorem,NFTET)的鲁棒在线轨迹重构算法。在标称情况下基于反馈线性化预测校正制导算法生成满足各种约束条件的再入轨迹；由于NFTET只适用于发生较小故障的情况，为保证较大故障下飞行器仍能以较高精度安全着陆，基于NFTET理论设计了鲁棒轨迹重构算法，得到了较高落点精度的飞行轨迹。仿真结果表明，本文所提出算法能有效解决飞行器较大故障下的安全再入轨迹重构问题，提高了飞行器的自主容错能力。     

阵风载荷减缓系统故障分析

阵风引起的额外载荷会引起飞机结构疲劳,降低结构使用寿命。采用非定常气动力有理函数拟合方法建立时域状态空间下的动力学系统,设计了阵风载荷减缓系统。研究了阵风载荷减缓系统3种典型故障模式(副翼偏转饱和、舵机卡死、副翼偏转延时)的力学建模方法,并对机翼在阵风减缓系统故障模式下的阵风响应进行分析。仿真结果表明,3种故障模式均不利于阵风载荷减缓系统对阵风载荷的减缓,对于一些特定情况,故障模式下的阵风载荷减缓系统不仅不能减缓阵风载荷,还会带来由副翼偏转不当引起的额外负载。