Passive attitude stabilization of ionic-wind-powered micro air vehicles

The ionic-wind-powered Micro Air Vehicles (MAVs) can achieve a higher thrust-to-weight ratio than other MAVs. However, this kind of MAV has not yet achieved controlled flight because of the unstable thrust produced by the ionic wind and the dynamic instability related to the small size. In this paper, a passive attitude stabilization method of the ionic-wind-powered MAV using air dampers is introduced. The key factors that influence the performance of the air dampers, including the layout, position, and area of the air dampers, are theoretically studied. The appropriate optimal position of the air dampers is also obtained by Monte Carlo stochastic simulations. Then the proposed passive attitude stabilization method is applied to the ionic-wind-powered MAVs of different wingspan (2 cm and 6.3 cm). Finally, the experimental results show that using the proposed method, attitude stabilization is achieved for the first time for the ionic-wind-powered MAV. Moreover, the altitude control of an ionic-wind-powered MAV with a wingspan of 6.3 cm is also demonstrated.     

基于SiP的低成本微小型GNC系统技术

随着微机电系统(MEMS)技术及微惯性器件的发展,大量小型化、低成本、高性能的导航、制导与控制(GNC)产品正越来越多地应用于小型无人飞行器、地面无人系统以及精确制导弹药等领域.针对各类应用需求,基于MEMS惯性测量单元(IMU)、GNSS接收模块、全捷联红外/可见光/激光多模智能导引头、信息处理器(DSP)与数据链通信模块,采用SiP技术研制出GNC芯片.基于GNC芯片构建一体化微小型GNC系统,突破了基于SiP一体化微小型GNC系统集成、全捷联红外/可见光/激光多模智能感知、嵌入式深组合导航、全捷联多模智能导引头/导航/制导与控制一体化设计等关键技术,并对其性能进行了评估.微小型GNC系统技术为低成本小型无人系统和精确制导弹药的发展夯实技术基础.     

5G微基站环境下GNSS接收机性能及观测质量分析

我国已全面进入5G时代，为研究5G微基站电磁环境对全球卫星导航系统（GNSS）接收机工作性能及观测数据质量的影响，基于自主建设差分基准站的零基线观测数据，采用静态相对定位方法，通过观测数据质量分析、载波与伪距的双差残差序列、对比相对静态定位结果，综合评估5G微基站对GNSS接收机工作性能及观测数据质量的影响。实验表明：当前环境下，GNSS差分基准站及接收机处于近距离建设的5G微基站时，载波相位观测噪声变化范围为5cm，伪距观测噪声变化范围为15cm，零基线测试结果变化范围为1mm。在实验距离内，5G微基站对于GNSS接收机工作性能及数据观测质量影响较小，可以忽略。