一种自主飞行的小型无人机系统设计

介绍了小型无人机系统的总体结构,分析了无人机的结构设计和算法,阐述了弹射起飞系统和伞降着陆系统的设计原理,采用嵌入式系统和GPS设计无人机的飞行姿态控制、导航控制、任务控制系统和数据链,实现了空中机器人的自主飞行。     

基于Simulink的小型无人机弹射架性能仿真

建立弹射系统的动态模型,为弹射起飞提供可信度高的分析设计、仿真验证平台。文章以弹力弹射系统为研究对象,建立无人机弹射起飞过程动力学、运动学模型,基于Matlab/Simulink模块,对弹性元件弹力系数、导轨长度、离架速度等参数进行了系统分析。在仿真过程中,通过改变系统的不同参数,得到了这些参数对系统弹射性能的影响规律。合理的匹配这些参数,可使用此系统弹射多种型号的无人机,提高了效率,节省了试验资源和经费。同时为无人机弹射系统优化和设计研发提供了理论依据。     

有人机/无人机协同任务控制系统

针对有人机/无人机协同任务控制系统的设计和实现问题展开研究。结合有人机/无人机协同控制过程的特点,提出了基于自然语言接口方式的有人机/无人机协同任务控制系统结构。在此基础上,分析了系统模块的关键内容,设计了面向有人机与无人机交互过程的任务指令格式,提出了基于优先级的任务模式调度策略,针对无人机的典型任务模式,讨论了航路规划的计算方法选择,最后构建了有人机/无人机协同任务仿真环境。仿真试验结果验证了整体方法的可行性。     

面向任务协同的云端融合计算架构研究

以有人机/无人机自组云为场景,研究了基于云数据中心、有人机和无人机任务协同的云端融合任务协同处理架构,在该架构中,有人机作为边缘计算处理节点,无人机作为端节点。通过分层设计,将基于无人机自组云的云端融合架构自顶往下划分为用户应用层、组件服务层、资源抽象层、操作系统层、物理资源层五个层级,并对各层级进行功能划分设计。最后通过典型实例仿真试验做了架构性验证。     

舰载无人机发射初始状态研究

首先,根据海浪、海风对舰船的作用,建立了准确而更符合实际的舰船运动模型.然后,引入了发射架在舰船上的位置和方向两个变量,得到了不同状况下舰载无人机的发射初始状态.最后,经数字仿真得出了各种因素对发射无人机的影响规律,为确定舰载无人机的安全发射范围提供了理论数据支持.     

无人机双发固体火箭助推器同步性研究

探讨和分析了无人机采用双发固体火箭助推发射方案时存在的助推器同步性问题。并以某型无人机和火箭助推器为例,进行了火箭助推器的同步性仿真计算以及同步性对无人机发射段飞行稳定性的影响计算,分析确定了影响双发固体火箭同步性的显著因素,并就改善双发火箭同步性提出了相应的技术措施。计算结果表明,火箭助推器同步性对无人机发射段飞行轨迹及稳定性的影响在工程应用上是可行的。     

无人机综合飞行/推力矢量控制

以某无人机为背景,主要研究大机动时带推力矢量的综合飞行/推进控制系统的设计方法。应用非线性动态逆方法,根据无人机本身具有明显不同时间尺度差异的动力学特性,结合奇异摄动理论将控制变量按照响应快慢分为4个回路进行了控制器的设计与仿真;设计推力矢量控制和气动控制相结合的控制器,实现飞行和推力矢量的控制综合;将无人机的任务转化为对飞行控制的限制条件,对所设计的控制系统进行了数字仿真,结果表明所设计的控制器能够满足飞机做大机动时的控制要求。     

影响螺旋桨式无人机安全发射的诸因素

根据无人机的零长发射原理,通过多个型号的发射仿真计算和发射试验分析,详细探讨了影响无人机安全发射的固有参数和外部参数,总结出影响螺桨式无人机安全发射的主要因素有：单发螺旋桨的反扭矩,火箭推力线相对重心的位置,火箭安装角,机体发射角,舵机死区及发射环境等。最后,以发射安全高度、速度、过载为约束条件,给出了火箭总冲、推力线位置、火箭安装角、机体发射角、发射风向和风速等参数的确定方法,该方法对保证无人机     

舰船运动对某无人机发射安全的影响研究

探讨了舰面运动(舰面纵摇、横摇和垂荡运动)对舰载无人机火箭助推发射安全的影响。数值分析表明,舰面纵摇可能导致飞机起飞后撞上甲板,是舰面运动中最危险的因素。舰面横摇对飞机离舰后最大下沉量的影响相比纵摇为小,若无人机在甲板上布置的位置适当,则可以实现安全发射。     

弹性飞翼无人机鲁棒姿态控制设计

针对大展弦比飞翼布局无人机的刚体运动与弹性运动耦合动力学模型,提出了一种基于反步法的鲁棒非线性控制方法。该方法考虑了飞翼无人机的非线性因素,将动态面反步控制作为内环控制抵消系统的非线性因素;同时考虑系统实际存在的弹性耦合项、参数不确定项以及外部扰动,将内环反步控制与飞翼无人机模型整体作为新的被控对象,引入最优化理论对新的被控对象设计了外环鲁棒控制器。仿真结果表明,所提出的控制器不仅满足飞翼无人机姿态跟踪性能的要求,且对模型不确定性和气动弹性影响具有鲁棒性。     

无人机下滑着陆DGPS/INS导航及引导系统的仿真与试验研究

介绍了一种采用输出校正方式DGPS/INS组合导航系统引导无人机下滑着陆的方案。给出了该方案的数学模型,对组合导航系统进行了数字仿真,并在数字仿真的基础上进行了动态跑车试验,验证了所设计的输出校正方式DGPS/INS组合导航系统能够满足引导无人机自动下滑着陆的精度要求。     

箱式发射无人机的一种变体机翼设计思想研究

作为无人机发射方式之一的箱式发射会对无人机总体设计提出更多的约束,同时,无人机越来越复杂的作战方式对无人机的总体设计也提出了新的要求。鉴于此,提出了一种新的机翼处理方法来满足箱式发射无人机的发射要求。由性能估算结果可知,处理后的机翼可以更好地满足无人机在巡航、突防和滞空段的飞行要求。     

Formation flight of fixed-wing UAV swarms: A group-based hierarchical approach

This paper investigates a formation control problem of fixed-wing Unmanned Aerial Vehicle (UAV) swarms. A group-based hierarchical architecture is established among the UAVs, which decomposes all the UAVs into several distinct and non-overlapping groups. In each group, the UAVs form hierarchies with one UAV selected as the group leader. All group leaders execute coordinated path following to cooperatively handle the mission process among different groups, and the remaining followers track their direct leaders to achieve the inner-group coordination. More specifically, for a group leader, a virtual target moving along its desired path is assigned for the UAV, and an updating law is proposed to coordinate all the group leaders’ virtual targets; for a follower UAV, the distributed leader-following formation control law is proposed to make the follower’s heading angle coincide with its direct leader, while keeping the desired relative position with respect to its direct leader. The proposed control law guarantees the globally asymptotic stability of the whole closed-loop swarm system under the control input constraints of fixed-wing UAVs. Theoretical proofs and numerical simulations are provided, which corroborate the effectiveness of the proposed method.     

State of art on energy management strategy for hybrid-powered unmanned aerial vehicle

New energy sources such as solar energy and hydrogen energy have been applied to the Unmanned Aerial Vehicle(UAV), which could be formed as the hybrid power sources due to the requirement of miniaturization, lightweight, and environmental protection issue for UAV. Hybrid electrical propulsion technology has been used in UAV and it further enforces this trend for the evolution to the Hybrid-Powered System(HPS). In order to realize long endurance flight mission and improve the energy efficiency of UAV, many researching works are focused on the Energy Management Strategy(EMS) of the HPS with digital simulation, ground demonstration platforms and a few flight tests for the UAV in recent years. energy management strategy, in which off-line or on-line control algorithms acted as the core part, could optimize dynamic electrical power distribution further and directly affect the efficiency and fuel economy of hybrid-powered system onboard.In order to give the guideline for this emerging technology for UAV, this paper presents a review of the topic highlighting energy optimal management strategies of UAV. The characteristics of typical new energy sources applied in UAV are summarized firstly, and then the classification and analysis of the architecture for hybrid power systems in UAV are presented. In the context of new energy sources and configuration of energy system, a comprehensive comparison and analysis for the state of art of EMS are presented, and the various levels of complexity and accuracy of EMS are considered in terms of real time, computational burden and optimization performance based on the optimal control and operational modes of UAV. Finally, the tendency and challenges of energy management strategy applied to the UAV have been forecasted.     

某型飞机发射装置自动测试系统的设计与实现

介绍了基于MCS51系列单片机AT89C51架构的某型飞机发射装置自动测试系统的设计与实现,系统电路中采用了强电信号隔离电路、抗干扰电路等关键电路,分析了测试系统的硬件电路和软件设计.并给出了控制程序流程图.     

Time-triggered State-machine Reliable Software Architecture for Micro Turbine Engine Control

Time-triggered (TT) embedded software pattern is well accepted in aerospace industry for its high reliability. Fi-nite-state-machine (FSM) design method is widely used for its high efficiency and predictable behavior. In this paper, the time-triggered and state-machine combination software architecture is implemented for a 25 kg thrust micro turbine engine (MTE) used for unmanned aerial vehicle (UAV) system; also model-based-design development workflow for airworthiness software directive DO-178B is utilized. Experimental results show that time-triggered state-machine software architecture and development method could shorten the system development time, reduce the system test cost and make the turbine engine easily comply with the airworthiness rules.     

Robust trajectory planning for UAV communication systems in the presence of jammers

Unmanned Aerial Vehicle(UAV) has emerged as a promising novel application for the Sixth-Generation(6G) wireless communication by leveraging more favorable Line-of-Sight(Lo S)propagation. However, the jamming resistance by exploiting UAV’s mobility is a new challenge in the UAV-ground communication. This paper investigates the trajectory planning problem in an UAV communication system, where the UAV is operated by a Ground Control Unit(GCU)to perform certain tasks in the presence of multiple jamm...     

Transition control of a tail-sitter unmanned aerial vehicle with L1 neural network adaptive control

The main task of this work is to design a control system for a small tail-sitter Unmanned Aerial Vehicle(UAV) during the transition process. Although reasonable control performance can be obtained through a well-tuned single PID or cascade PID control architecture under nominal conditions, large or fast time-varying disturbances and a wide range of changes in the equilibrium point bring nonlinear characteristics to the transition control during the transition process, which leads to control prec...