基于分层神经网络的航天器故障诊断技术

为了提高卫星、飞船等复杂系统的故障诊断速度和精度,文章提出了一种基于分层神经网络的整星故障诊断模型。模型中的上层神经网络采用自组织特征映射网络,完成整星故障的初步定位与辨识;下层神经网络采用广义回归神经网络,实现整星各分系统故障的精确定位和定因。引入主元分析法实现原始状态变量的降维,减少神经网络神经元数量。该模型已成功应用于某卫星各分系统的故障诊断,提高了诊断效率,并能精确给出诊断结果。     

一种基于非线性回归的载人航天器密封舱内在轨噪声分析方法

文章提出一种载人航天器密封舱内噪声非线性回归通用分析方法,可基于地面噪声试验测得的数量较多的数据样本和在轨噪声测试获取的少量数据样本,建立密封舱内位置–在轨噪声的数学模型。经验证该模型能够较为准确地拟合密封舱内在轨噪声水平,从而为开展载人航天器的降噪设计、优化噪声仿真模型和验证降噪措施效果提供数据支持。     

航天器环境干扰力矩的闭环辨识与补偿

研究引入干扰力矩辨识的方法提高三轴稳定航天器在稳态运行期间的高精度指向控制问题.基于航天器的稳态输出数据和系统传递函数,对环境干扰力矩的完整模型进行闭环辨识.其中采用改进的特征系统实现相关算法和多元线性回归法辨识环境干扰力矩的模型参数,最后使用前馈控制对所辨识的环境干扰力矩实现在线补偿.分析和仿真结果表明,该方案能有效地克服不确定的环境干扰力矩对姿态稳定度的影响,提高在轨运行航天器的姿态稳定精度.     

基于多元线性回归模型的光纤陀螺温度误差建模

在-40℃～60℃温度范围内测试了数字闭环光纤陀螺的标度因数、偏置和噪声,基于对测试 数据的分析指出,零偏稳定性大于0.3°／h的光纤陀螺的温 度误差主要来源于标度因数误差和偏置误差。利用逐步回归法分析了零偏与温度、温度梯度 之间的线性关系和标度因数与温度之间的线性关系,建立了零偏误差和标度因数误差的多元 线性回归模型。在模型中引入到达探测器的光功率作为新变量,提高了标度因数模型精度, 并使计算量减小40％。建模结果表明,标度因数误差回归模型的残差均方(RMS)达到1
(bit／(°／s)) 2,偏置误差回归模型的残差均方达到0.067(°／h) 2。     

考虑刀具偏心的微铣削加工表面粗糙度预测模型研究

基于微铣削刀具轨迹建立了考虑刀具偏心、最小切削厚度的塑性材料微铣削底面粗糙度的预测模型,预测结果表明粗糙度表面形貌呈锯齿状,刀具偏心会影响表面粗糙度的形貌周期和高度,并进行微铣削加工实验,对粗糙度预测模型进行了验证。采用回归统计方法,建立了脆性材料微铣削加工表面粗糙度预测模型,对加工表面形貌进行观察,利用响应曲面法得到了各铣削用量对表面粗糙度的影响规律。     

基于遥测数据的无人机气动参数辨识方法研究

针对无人机在高空低速飞行时易受风场影响及在数据分析时遥测数据不完备的问题,进行了气动参数辨识方法研究,提出了基于空速管平面矢量三角形的风场估计方法及基于风场信息修正的气动角估计方法。以某型无人机为例,对遥测数据进行了充分分析与信息综合,运用逐步回归方法进行了纵向气动参数辨识,并进行了实验验证。结果表明,模型计算结果与实测数据吻合较好,说明所提方法有效。考虑到辨识模型的数学本质,该方法对其他固定翼无人机同样适用。     

航天器表面电荷激发空间静电场规律研究

从带电表面微元出发,通过求解泊松方程,得到带电介质平板表面邻近空间静电势的解析表达式,建立介质表面电位-介电常数模型,求得了带电介质平板表面电位、表面带电量和介质介电常数三者之间的关系式。结合典型的航天器表面介质材料带电案例,对此类圆盘结构介质平板带电问题进行了仿真分析,结果表明,在介质材料表面电位一定的情况下,表面电荷激发的空间静电势值随距离的增大而减小,并且距离介质表面越近,电势的空间变化率越大;在介质材料带电量相等的情况下,介质表面电位随着介质介电常数的增大而减小,并逐渐趋于一个稳定值,所以在一定范围内选择介电常数较大的介质材料可以降低介质的表面电位,减小介质间发生静电放电的几率。     

Remote sensing and GIS-based landslide hazard analysis and cross-validation using multivariate logistic regression model on three test areas in Malaysia

This paper presents the results of the cross-validation of a multivariate logistic regression model using remote sensing data and GIS for landslide hazard analysis on the Penang, Cameron, and Selangor areas in Malaysia. Landslide locations in the study areas were identified by interpreting aerial photographs and satellite images, supported by field surveys. SPOT 5 and Landsat TM satellite imagery were used to map landcover and vegetation index, respectively. Maps of topography, soil type, lineaments and land cover were constructed from the spatial datasets. Ten factors which influence landslide occurrence, i.e., slope, aspect, curvature, distance from drainage, lithology, distance from lineaments, soil type, landcover, rainfall precipitation, and normalized difference vegetation index (ndvi), were extracted from the spatial database and the logistic regression coefficient of each factor was computed. Then the landslide hazard was analysed using the multivariate logistic regression coefficients derived not only from the data for the respective area but also using the logistic regression coefficients calculated from each of the other two areas (nine hazard maps in all) as a cross-validation of the model. For verification of the model, the results of the analyses were then compared with the field-verified landslide locations. Among the three cases of the application of logistic regression coefficient in the same study area, the case of Selangor based on the Selangor logistic regression coefficients showed the highest accuracy (94%), where as Penang based on the Penang coefficients showed the lowest accuracy (86%). Similarly, among the six cases from the cross application of logistic regression coefficient in other two areas, the case of Selangor based on logistic coefficient of Cameron showed highest (90%) prediction accuracy where as the case of Penang based on the Selangor logistic regression coefficients showed the lowest accuracy (79%). Qualitatively, the cross application model yields reasonable results which can be used for preliminary landslide hazard mapping.     

热管式表面温度计检定装置

叙述一种热管式表面温度计检定装置的原理、结构。该装置可用于航天领域在实验室条件下对表面温度计的检定。     

Transient simulation of regression rate on thrust regulation process in hybrid rocket motor

The main goal of this paper is to study the characteristics of regression rate of solid grain during thrust regulation process. For this purpose, an unsteady numerical model of regression rate is established. Gas–solid coupling is considered between the solid grain surface and combustion gas.Dynamic mesh is used to simulate the regression process of the solid fuel surface. Based on this model, numerical simulations on a H2O2/HTPB(hydroxyl-terminated polybutadiene) hybrid motor have been performed in the flow control process. The simulation results show that under the step change of the oxidizer mass flow rate condition, the regression rate cannot reach a stable value instantly because the flow field requires a short time period to adjust. The regression rate increases with the linear gain of oxidizer mass flow rate, and has a higher slope than the relative inlet function of oxidizer flow rate. A shorter regulation time can cause a higher regression rate during regulation process. The results also show that transient calculation can better simulate the instantaneous regression rate in the operation process.