Modeling and experimental validation of sawing based lander anchoring and sampling methods for asteroid exploration

This paper presents a novel lander anchoring system based on sawing method for asteroid exploration. The system is composed of three robotic arms, three cutting discs, and a control system. The discs mounted at the end of the arms are able to penetrate into the rock surface of asteroids. After the discs cut into the rock surface, the self-locking function of the arms provides forces to fix the lander on the surface. Modeling, trajectory planning, simulations, mechanism design, and prototype fabrication of the anchoring system are discussed, respectively. The performances of the system are tested on different kinds of rocks, at different sawing angles, locations, and speeds. Results show that the system can cut 15?mm deep into granite rock in 180?s at sawing angle of 60°, with the average power of 58.41?W, and the “weight on bit” (WOB) of 8.637?N. The 7.8?kg anchoring system is capable of providing omni-directional anchoring forces, at least 225?N normal and 157?N tangent to the surface of the rock. The system has the advantages of low-weight, low energy consumption and balance forces, high anchoring efficiency and reliability, and could enable the lander to move and sample or assist astronauts and robots in walking and sampling on asteroids.     

基于有向图模型的民机航空电子系统故障诊断

结合民机航电系统外场可更换单元或模块（LRU/LRM）的故障模式及影响分析（FMEA）、故障树 分析和实时性要求,设计了基于时间故障传播图（TFPG）的系统故障诊断元模型和领域模型,研究了基于逻 辑和时间一致性检验的故障诊断算法,使用后向推理和可信度度量列出候选故障集。以飞行管理系统为例,构 造了其功能失效的TFPG 模型,并通过仿真验证了基于TFPG 的诊断在滤除级联效应和关联驾驶舱效应中的有 效性。     

Dynamic parametric modeling-based model updating strategy of aeroengine casings

For accurate Finite Element (FE) modeling for the structural dynamics of aeroengine casings, Parametric Modeling-based Model Updating Strategy (PM-MUS) is proposed based on efficient FE parametric modeling and model updating techniques regarding uncorrelated/correlated mode shapes. Casings structure is parametrically modeled by simplifying initial structural FE model and equivalently simulating mechanical characteristics. Uncorrelated modes between FE model and experiment are reasonably handled by adopting an objective function to recognize correct correlated modes pairs. The parametrized FE model is updated to effectively describe structural dynamic characteristics in respect of testing data. The model updating technology is firstly validated by the detailed FE model updating of one fixed–fixed beam structure in light of correlated/uncorrelated mode shapes and measured mode data. The PM-MUS is applied to the FE parametrized model updating of an aeroengine stator system (casings) which is constructed by the proposed parametric modeling approach. As revealed in this study, (A) the updated models by the proposed updating strategy and dynamic test data is accurate, and (B) the uncorrelated modes like close modes can be effectively handled and precisely identify the FE model mode associated the corresponding experimental mode, and (C) parametric modeling can enhance the dynamic modeling updating of complex structure in the accuracy of mode matching. The efforts of this study provide an efficient dynamic model updating strategy (PM-MUS) for aeroengine casings by parametric modeling and experimental test data regarding uncorrelated modes.     

翼伞系统纵向飞行性能分析

翼伞系统的飞行性能不仅取决于翼伞本身的气动特性,而且与安装角、伞绳长度、回收物阻力特征、翼载荷等系统参数密切相关。文章应用拉格朗日方程建立翼伞系统的纵向飞行力学模型,对翼伞系统进行飞行力学数值仿真,深入分析了系统参数以及开伞状态对翼伞系统纵向飞行性能的影响规律。结果表明：只有安装角在0°～20°时,翼伞系统才能达到稳定的滑翔状态,且安装角在4°～6°时对应两个稳定的滑翔状态,具体由开伞姿态和速度决定;伞绳特征长度的增加使系统的静稳定性增加;回收物的阻力特征增加6m2,翼伞系统的稳定滑翔角增加15°左右,而迎角减小不到1°;翼伞飞行速度随着翼载荷的增加而增加,其平方与回收物质量成正比。上述结论可为翼伞系统的工程实际应用提供参考。     

三角形机翼参数化有限元网格划分与调整方法

为缩短有限元建模周期,提高三角形机翼结构分析、设计与优化的效率疲,首先,以其满足预定气动性能的几何外形为输入,定义了易用的有限元节点与单元的编号规则;基于可设计的机翼内部构型参数及可变的有限元尺寸参数的设置,引入了翼肋贯穿截止准则以满足任意输入的内部构型的初步判断;借助自定义形状矩阵完成了节点布置与单元生成,进一步通过有限元网格细化完成了开口设置、翼肋贯穿位置修正及桁条建模.然后,基于已建立的有限元网格实现了内外侧副翼翼肋位置的小幅调整及旋转舵面的角度调整,以满足不同飞行状态下结构分析需求.最后,应用PCL语言开发了参数化建模模块,实例表明了方法的有效性和模块可靠性.      

弹性高超声速飞行器建模及精细姿态控制

为保证超燃冲压发动机的良好进气,需要对高超声速飞行器进行精细姿态控制,但弹性振动问题极大影响其精细姿态控制精度。以高超声速飞行器的纵向通道为例,分析弹性振动问题对飞行控制系统的影响,建立面向控制的弹性高超声速飞行器数学模型,考虑气动参数和模态参数的大范围摄动,采用主动控制策略,基于鲁棒H∞理论和LQR理论设计精细姿态控制系统。大量仿真表明：在考虑测量噪声、舵机非线性、参数大范围摄动的情况下,控制系统能够很好地跟踪刚体攻角,抑制弹性攻角,并保证进气口当地攻角±0.4度的控制精度,满足高超声速飞行器精细姿态控制的要求。     

基于区域预测和视觉注意计算的快速目标检测

提出了一种结合区域预测与视觉注意模型化计算的快速目标检测方法.通过分析图像近似均匀的3个水平子区域的方向特征图之灰度比率,灰度特征图之信息熵和子区域位置,建立了目标区域预测的判定准则.同时,通过优选特征和优化特征图之权重,改进了视觉注意计算模型.对于一幅待检测图像,根据区域预测的判定准则,实现目标区域的快速预测,并利用改进的视觉注意计算模型对目标区域进行视觉注意计算,实现特定目标的快速精确定位.实验结果表明:针对户外场景中的行人目标,与通过整幅图像的视觉注意计算来实现目标检测的传统方法相比较,该检测方法可使检测时间缩短30%,同时还能使检测准确率提高9%.      

PREDICTION OF SURFACE ROUGHNESS FOR END MILLING TITANIUM ALLOY USING MODIFIED PARTICLE SWARM OPTIMIZATION LS-SVM

It is difficult to construct the prediction model for titanium alloy through analyzing the formation mecha- nism of surface roughness due to the complicated relation between influential factors and surface roughness. A no- vel algorithm based on the modified particle swarm optimization （PSO） least square support vector machine （LS- SVM） is proposed to predict the roughness of the end milling titanium alloys. According to Taguchi method and features in milling titanium alloys, the influences of cutting speed, feed rate and axial depth of cut on surface roughness are investigated with the analysis of variance （ANOVA） of the experimental data. The research results show that the construction speed of the modified PSO LS-SVM model is two orders of magnitude faster than that of back propagation（BP） model. Moreover, the prediction accuracy is about one order of magnitude higher than that of BP model. The modified PSO LS-SVM prediction model can explain the influences of cutting speed, feed rate and axial depth of cut on the surface roughness of titanium alloys. Either a higher cutting speed, a lower feed rate or a smaller axial depth of cut can lead to the decrease of surface roughness.     

临近空间飞行器多物理场耦合建模的网格映射方法

临近空间飞行器的研制面临许多复杂的问题和挑战,涉及总体、气动、结构、控制、防热、动力等多个学科和专业领域的相互作用、高度耦合的子系统。全系统、全流程的仿真验证与性能评估能够为设计工作提供重要依据,缩短研制周期。而气动、结构、防热等专业的仿真建模和模型解算基于有限体积法或有限元方法,依赖于不同的工具软件,且网格的划分方法不同。本文研究了临近空间高超声速飞行器多物理场耦合建模方法,研究并实现了异构网格耦合界面之间与耦合域之间的信息传递方法,从而实现了临近空间高超声速飞行器的多物理场耦合建模与仿真。     

液体火箭发动机传感器故障检测与数据恢复算法研究

以某型液体火箭发动机为研究对象,根据其传感器的故障特性,提出了基于BP神经网络的传感器故障检测与数据恢复算法。通过定义的传感器置信度来判断传感器是否发生故障,以及确定故障传感器,利用已训练好的神经网络结构对故障传感器进行数据恢复。研究内容能够实现传感器的故障检测、定位与补偿,能够有效提高发动机故障检测方法的可靠性和鲁棒性。