复杂动态环境下无人飞行器动态避障近似最优轨迹规划

针对复杂动态环境下无人飞行器的动态障碍规避问题，基于合理假设建立了无人飞行器和动态障碍的运动学模型，并综合考虑无人飞行器飞行过程中的终端约束、控制输入约束、安全避障约束等，以能量最少为性能指标构建动态避障问题数学描述。之后，针对终端约束和控制输入约束，依据优化模型预测静态规划算法(OMPSP)生成初始轨迹；针对动态避障问题的不等式约束，引入松弛变量并结合滑模变结构控制方法设计松弛变量动力学，实现对一个、多个或同时多个动态障碍的安全规避；最后，依据有限时间微分动态规划(RHDDP)算法进行轨迹优化，获得满足上述各种约束并能规避动态障碍的近似最优轨迹。     

Optimization of bits allocation and path planning with trajectory constraint in UAV-enabled mobile edge computing system

In this paper, an Unmanned Aerial Vehicle (UAV) enabled Mobile Edge Computing (MEC) system is studied, in which UAV acts as server to offer computing offloading service to the Mobile Users (MUs) with limited computing capability and energy budget. We aim to minimize the total energy consumption of MUs by jointly optimizing the bit allocation for uplink, computing at the UAV and downlink, along with the UAV trajectory in a unified framework. To this end, a trajectory constraint model is employed to avoid sudden changes of velocity and acceleration during flying. Due to high-order information in use, we lead to a more reasonable nonconvex optimization problem than prior arts. An Alternating Direction Method of Multipliers (ADMM) method is introduced to solve the optimization problem, which is decomposed into a set of easy sub-problems, to meet the requirement on the efficiency in edge computing. Numerical results demonstrate that our approach leads a smoother UAV trajectory, significantly save the energy consumption for UAV during flying.     

Topology optimization in lightweight design of a 3D-printed flapping-wing micro aerial vehicle

Topology optimization is an effective method to obtain a lightweight structure that meets the requirements of structural strength. Whether the optimization results meet the actual needs mainly depends on the accuracy of the material properties and the boundary conditions, especially for a tiny Flapping-wing Micro Aerial Vehicle (FMAV) transmission system manufactured by 3D printing. In this paper, experimental and numerical computation efforts were undertaken to gain a reliable topology optimization method for the bottom of the transmission system. First, the constitutive behavior of the ultraviolet (UV) curable resin used in fabrication was evaluated. Second, a numerical computation model describing further verified via experiments. Topology optimization modeling considering nonlinear factors, e.g. contact, friction and collision, was presented, and the optimization results were verified by both dynamic simulation and experiments. Finally, detailed discussions on different load cases and constraints were presented to clarify their effect on the optimization. Our methods and results presented in this paper may shed light on the lightweight design of a FMAV.     

太阳能飞机循环飞行的高度剖面能量策略

为满足设定的太阳能飞机多日连续飞行条件，依据飞行过程中当前时刻的飞行高度、光伏输出功率、动力电池组余量等系统状态参数，研究如何分配动力电池组充放电和电推进系统输入等功率。所用策略立足于实时功率平衡，充分利用正午前后的光伏峰值功率用于飞机爬升及充电，在午后下滑过程中利用全部光伏输出，以最大化利用光伏资源；在光伏有效输出不足时则以一定的维持功率下滑，使能量的综合损失最小。方法能够提高以预定夜间飞行高度连续多日续航的成功率，提升飞行高度、纬度、季节范围或搭载能力，或者拓展这几种飞行条件的组合域，优化太阳能飞机的适用性。     

无人机自由编队飞行的补偿模糊神经网络控制

为了克服当前提出的无人机编队飞行的不足，提出一种新的无人机编队飞行概念——自由编队飞行，制定了相关的避让规则，用补偿模糊神经网络进行训练，实现自由编队飞行的补偿模糊神经网络控制。仿真显示，编队飞行的飞机能按照规则自主改变航路进行避让，表明了该方法的有效性。     

基于商空间理论的模糊控制在航空相机中的应用

针对航空相机快速返回定位问题,应用商空间理论提出了一种快速无超调定位模糊控制算法。将位置偏差量模糊化．并根据模糊等价关系合并正规峰集,从而得到了不同粒度下的控制规则．系统通过不断改变粒度,采用粗拉度粗调,细粒度细调的方法,实现快速无超调定位。在模拟相机平台上采用3个粒度层,通过模糊规则调整模糊输出和PID控制器的积分时间实现最速控制、模糊控制和PID控制在不同粒度下的转换．实验结果表明此算法具有定位快、稳定精度高以及无超调等优点．     

一种低RCS无人飞行器外形的气动特性实验研究

根据气动布局的基本原理,结合低RCS要求,设计了一种鸭式布局、带边条的翼身融合无人飞行器外形,实验结果表明,该外形不仅具有低RCS特征,而且具有良好的气动特性,升阻比达到8左右。     

无人机模拟训练系统中的实时飞行仿真

为了降低无人机的试飞成本,提高操纵手的技能,设计了一种模拟训练系统。介绍了该模拟训练系统的特点和构成,着重对系统中实时飞行仿真的各模块设计方法进行了研究。在DOS操作系统中用C语言实现飞行仿真软件,并讨论了软件实现中的模态切换等关键问题。通过飞行剖面仿真实验,证明该仿真系统可靠性高、实时性好。     

多无人机监控航路规划

为了提高监控任务的效率，在执行任务前必须规划设计出高效的无人机飞行航路。针对这一问题，考虑在任务区域内进行多无人机监控航路优化存在计算的复杂性和收敛性以及计算数据量限制等问题，采用分散式方法对监控航路进行了优化，并以无人机的监控任务为例提出了一种监控效率指标评估的计算方法，解决了航路规划中的监控效率量化问题。通过该方法得到的无人机监控任务的飞行航路可以有效地提高无人机的监控效率。     

基于雷达组网的抗无人机新技术研究

介绍了无人机的概念和基本特性;主要讨论了雷达组网和数据融合的基本原理及其如何实现对敌无人机等弱小目标的检测与跟踪,在此基础上引入了检测跟踪的新方法,有效弥补了单机雷达的不足,便于防空决策的后续处理.