多飞行器动态目标追踪协同控制研究

多飞行器追踪动态目标是一个协同控制问题,需要根据目标飞行状态,协同各个追踪飞行器的飞行状态,最终能够在某动态的最佳点实现同时到达。考虑到目标具有较强的机动性,轨迹通常为非线性的,设计了一种基于非线性轨迹预测的、以剩余时间为控制变量的一致性控制方案。仿真结果表明,提出的控制方案能够实现空间位置相距较远的多飞行器动态追踪,具有较好的灵活性和收敛性,目标轨迹的预测结果与实际轨迹误差较小,恰当的轨迹估计有助于缩短追踪时间,提高追踪效率。     

高超声速飞行器再入轨迹多目标优化

针对飞行器再入轨迹多目标优化问题,提出了一种基于粒子群算法与层次分析法的综合求解策略。首先,根据飞行器的动力学模型以及再入约束条件,建立了飞行器多目标优化模型;然后,考虑到粒子群算法只能求解无约束单目标问题,采用罚函数处理飞行过程中的约束条件和优化目标;最后,针对不同约束及目标的权重对再入轨迹的影响,利用层次分析法建立包含主观评估信息的优化模型,采用粒子群算法优化求解满足相应约束条件的再入轨迹问题。仿真结果表明,该方法所生成的优化轨迹具有较高的精度和计算效率,并对设计者的主观需求有良好的体现。     

基于NFTET的高超声速飞行器鲁棒轨迹重构设计

考虑高超声速飞行器故障下安全再入飞行问题,针对飞行器发生较大故障的情况,提出了基于相邻可行轨迹存在定理(Neighboring feasible trajectory existence theorem,NFTET)的鲁棒在线轨迹重构算法。在标称情况下基于反馈线性化预测校正制导算法生成满足各种约束条件的再入轨迹;由于NFTET只适用于发生较小故障的情况,为保证较大故障下飞行器仍能以较高精度安全着陆,基于NFTET理论设计了鲁棒轨迹重构算法,得到了较高落点精度的飞行轨迹。仿真结果表明,本文所提出算法能有效解决飞行器较大故障下的安全再入轨迹重构问题,提高了飞行器的自主容错能力。     

临近空间高超声速目标滑跃式轨迹Sine-AIMM跟踪算法

针对单一的Sine模型算法无法与临近空间高超声速目标滑跃式轨迹准确匹配,现有的交互多模型(IMM)算法跟踪效果也不够理想的问题,提出一种基于多重贝叶斯准则的自适应交互式多Sine模型(Sine-AIMM)临近空间高超声速滑跃式目标跟踪算法.算法采用多个Sine模型对滑跃式轨迹进行匹配,并利用多重贝叶斯准则在线调整各模型...     

空射导弹发射初始弹道数值仿真

导弹从载机上发射时,载机对导弹的流场存在干扰,从而影响导弹在发射初始阶段的姿态和运动轨迹。为了确定导弹的初始弹道参数,本文利用CFD商业软件Fluent6.1计算导弹发射时的非定常流场,并通过该软件的接口嵌入导弹的六自由度弹道方程,同时计算了导弹在载机流场干扰下的非定常气动力和初始弹道。计算结果清晰地表现出导弹与载机的分离过程和载机流场的干扰形式,并可估算出载机的流场干扰范围。     

一种扩展的比例导引规律及其弹道方程的构建

在传统的动力学微分方程的基础上提出了一种扩展的比例导引法 ,并给出了该导引规律下的相对弹道方程。文中的推理过程表明 ,这种导引规律对导弹、目标的运动速度几乎没有限制 ,理论上说明运用该制导规律的导弹将能对付高机动大速度目标 ,其弹道方程的建立 ,使得研究该制导规律下的弹道特性成为可能。     

New design simulation for a high-altitude dual-balloon system to extend lifetime and improve floating performance

This paper presents a comprehensive simulation for a high-altitude dual-balloon system which consists of zero- and super-pressure balloons. Preliminary calculations were established to describe the basic concept of the new integrated system. A mathematical model was investigated to simulate the ascending and floating processes which considered the atmospheric conditions and thermodynamic variations. Based on the simulation, results showed that the floating altitude stability between daytime and nighttime was improved. This integrated system supports higher floating altitude levels than those of ordinary balloons and extends the lifetime of floating balloon systems. Moreover, results demonstrated that the integrated system was lighter than ordinary balloons, saving useful weight for effective payload. Furthermore, exploiting the advantages of both kinds of balloons while avoiding the difficulties was a significant goal in the current design to promote the floating performance of high-altitude balloons technology.     

脉冲雷达凝视模式下低轨碎片相对运动特征分析

脉冲雷达凝视模式是一种探测低轨小碎片的重要方式,其中低轨碎片与雷达的径向运动关系是碎片统计分析的基础.为推算碎片相对雷达的运动特征,基于坐标系的相互转换,先利用雷达测站信息,得到可见碎片在地惯坐标系下的轨道信息;再逆向将目标不同时刻的位置转换至测站坐标系下,得到目标的径向运动特征.在不同要素（雷达波束指向、雷达仰角、测站纬度、目标距离）下,仿真及对比分析了各个参数对速度模糊度、雷达可见性等的影响,得出在凝视模式下目标相对雷达近似做径向匀加速运动,这为后续试验工作提供有力的依据.     

Hybrid optimization for multiple-impulse reconfiguration trajectories of satellite formation flying

A hybrid optimization method is developed for fuel-optimal reconfigurations of a group of satellites flying in formation. The genetic algorithm performs a global search to find two-impulse trajectories, and primer vector analysis finds multiple-impulsive local optimal trajectories with the two-impulse trajectories as initial guesses. Hybrid optimization finds globally optimal trajectories for formation reconfigurations, including formation resizing, reassignment and reorientation maneuvers. Multiple-impulse trajectories reduce the fuel consumption from the two-impulse trajectories by up to 4.4% for those maneuvers. In real missions, satellites can follow two-impulse trajectories to gain the advantage of a smaller number of impulses, with the cost of slightly more propellant. The qualitative characteristics of the optimal trajectories are analyzed from the number of optimal trajectories found by hybrid optimization.     

3-D position estimation of isolated target and optimal trajectory choice in parasitic synthetic aperture radar

Bistatic SAR (BSAR) systems have recently been the subject of several studies, but little attention has been given to the potential of the location of targets. In the paper, the performance of the estimation of 3-D position of a target (TPE) in parasitic SAR is obtained analytically and illustrated by computer simulation using ambiguity function analysis, and the maximum likelihood estimate (MLE) approach. It was shown that by using a multi look parasitic BSAR all three coordinates of an isolated point target (IPT) could be evaluated. Analytical closed form equations that characterize the measurement accuracy were derived. In the final these equations will be used to demonstrate various cases of more practical, including optimal trajectories choice under any geometry configuration case, moreover, the conclusion is verified via Matlab.