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考虑禁飞圆的滑翔式机动弹道与气动特性参数耦合设计 总被引:1,自引:0,他引:1
为获得滑翔式再入飞行器最佳气动与弹道机动性能,针对规避禁飞圆的远程滑翔式再入问题提出了一种机动弹道与气动特性参数耦合设计方法。耦合设计外环以气动特性参数为设计变量,基于抛物阻力极线模型提取最大升阻比和对应升力系数为气动特性参数;耦合设计内环以泛化升力系数和侧倾角为设计变量,获得给定升阻特性下能规避禁飞圆且满足再入走廊要求的滑翔式再入轨迹。耦合设计问题以再入驻点总热流最小为优化目标,以再入走廊、终端位置和速度为约束,求解满足弹道机动要求且目标函数最小的最佳气动特性参数。提出了一种规避禁飞圆的侧向几何制导逻辑用于内环轨迹设计。仿真算例得出禁飞圆半径越大,需要的滑翔式再入飞行器最大升阻比越大,且再入轨迹刚好能绕过禁飞圆。仿真结果验证了耦合设计方法和侧向制导逻辑的有效性,该方法可为飞行器方案设计时的气动布局选型等工作提供参考。 相似文献
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从高超声速飞行器集群"探测-打击-评估"一体化任务需求出发,针对多滑翔飞行器时间协同再入轨迹规划问题进行研究,提出集群再入的协同形式及轨迹规划方案,基于改进序列凸化算法解决了再入总飞行时间的精确控制问题,从而实现滑翔段时间协同。首先,给出了滑翔飞行器集群的协同策略,将求解模型转化为协同时间的确定、协同时间约束下的轨迹规划子问题。将模型中的时间项误差等加入罚函数,提高了协同轨迹求解可行性。引入飞行路径角预设剖面作为软约束,并通过罚函数与信赖域自适应调整,以避免轨迹求解时的振荡问题,提高了序列凸化算法的收敛性。以CAV-H飞行器模型为例验证了算法的有效性,仿真结果表明,所提算法对初值的敏感性低,求解得到的再入总时间可调范围与伪谱法一致,轨迹规划结果的平滑性及计算时间均优于伪谱法。 相似文献
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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。 相似文献
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使用三次样条函数拟合再入飞行器纵向运动轨迹,以样条曲线上的控制节点为优化参数,将再入轨迹优化问题转化为静态参数优化问题.最后以纵向平面内的最优轨迹为例,以终点速度最大和飞行时间最短为优化目标,采用基于Pareto定级排序遗传算法求解了在末端状态受约束的最优再入轨迹问题,验证了该方法的有效性. 相似文献
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提出了一种多飞行器再入段时间协同弹道规划方法。首先,在纵向平面内规划满足航程与终端约束的纵向标称轨迹。随后,在采用轨迹跟踪律跟踪纵向标称轨迹的同时,运用考虑初始横侧向状态的多边界航向偏差角走廊策略控制飞行器的横侧向机动,以满足到达时间约束与终端约束,进而实现单枚飞行器到达时间约束下的轨迹规划。在此基础上,完成了飞行器的到达时间分布与飞行能力分析,给出了最小与最大到达时间的分析计算方法,并根据多飞行器协同再入的任务需求完成了协同飞行时间决策。最后,多飞行器协同再入与扰动条件下的仿真结果表明,该方法能够规划出满足到达时间与终端约束的协同再入轨迹,具备良好的计算精度与鲁棒性。 相似文献
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基于直接配点法的滑翔轨迹快速优化设计 总被引:1,自引:0,他引:1
介绍了基于五次Gauss-Lobatto多项式的直接配点法在再入飞行器三维轨迹最优化问题中的应用。首先给出了再入飞行器轨迹优化问题模型,其中运动方程为三自由度模型,性能指标选为到达指定地点飞行时间最短,控制变量则为无量纲升力系数和倾侧角。再入飞行过程中受到加热率、过载和动压约束,终端状态受到目标位置约束。然后,应用直接配点法将最优控制问题离散化为非线性规划问题,将动态优化问题转化为静态参数最优化问题。选取各节点和配点上的状态量和控制量作为优化参数。最后应用SNOPT软件包对参数最优化问题进行求解。仿真结果表明直接配点法对于再入飞行器轨迹初始参数取值不敏感,且求解过程具有一定的实时性。 相似文献
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随着高超声速飞行器的发展,其外形优化受到了广泛关注。应用一种新型的改进多目标布谷鸟优化搜索算法(IMOCS),采用修正的牛顿法与面元法相结合来获得高超声速飞行器的气动性能,采用自由变形参数化方法(FFD)来进行外形的参数化,以最大化容积率和升阻比为设计目标,开展了高超声速滑翔飞行器的多目标气动外形优化设计,获得了综合容积率及升阻比性能更高的气动外形,验证了方法的有效性。最后,将IMOCS算法和当前主流的多目标优化算法NSGA-Ⅱ进行了对比,结果表明,IMOCS算法的效果明显优于NSGA-Ⅱ。 相似文献
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《中国航空学报》2020,33(7):2002-2013
For different flight phases in an overall flight mission, different control and allocation preferences should be pursued considering lift, drag or maneuverability characteristics. The multi-objective flight control allocation problem for a multi-phase flight mission is studied. For an overall flight mission, different flight phases namely climbing, cruise, maneuver and gliding phases are defined. Firstly, a multi-objective control allocation problem considering drag, lift or control energy preference is constructed. Secondly, considering different control preferences at different flight phases, the analytic hierarchical process method is used to construct a comprehensive performance index from different objectives such as lift or drag preferences. The active set based dynamic programming optimization method is used to solve the real-time optimization problem. For the validation, the Innovative Control Effector (ICE) tailless aircraft nonlinear model and the angular acceleration measurements based adaptive Incremental Backstepping (IBKS) are used to construct the validation platform. Finally, an overall flight mission is simulated to demonstrate the efficiency of the proposed multi-phase and multi-objective flight control allocation method. The results show that the comprehensive performance index for different phases, which are determined from the Analytic Hierarchy Process (AHP) method, can suitably satisfy the preference requirements for different flight phases. 相似文献
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Reentry trajectory optimization for hypersonic vehicle satisfying complex constraints 总被引:7,自引:4,他引:3
The reentry trajectory optimization for hypersonic vehicle(HV)is a current problem of great interest.Some complex constraints,such as waypoints for reconnaissance and no-fly zones for threat avoidance,are inevitably involved in a global strike mission.Of the many direct methods,Gauss pseudospectral method(GPM)has been demonstrated as an effective tool to solve the trajectory optimization problem with typical constraints.However,a series of diffculties arises for complex constraints,such as the uncertainty of passage time for waypoints and the inaccuracy of approximate trajectory near no-fly zones.The research herein proposes a multi-phase technique based on the GPM to generate an optimal reentry trajectory for HV satisfying waypoint and nofly zone constraints.Three kinds of specifc breaks are introduced to divide the full trajectory into multiple phases.The continuity conditions are presented to ensure a smooth connection between each pair of phases.Numerical examples for reentry trajectory optimization in free-space flight and with complex constraints are used to demonstrate the proposed technique.Simulation results show the feasible application of multi-phase technique in reentry trajectory optimization with waypoint and no-fly zone constraints. 相似文献