对提高统计线性化精度及高阶矩传播法的研究

提出提高统计线性化精度的新方法,同时研究高阶矩传播法的计算方法,并以此方法做为衡量计算精度的标准,计算结果表明,提出的修正方法改善了计算精度,并且易于推广使用。     

日地平动点卫星两脉冲转移轨道设计

研究基于最小二乘微分修正方法的平动点卫星两脉冲转移轨道设计,推导了考虑高度和航迹角约束的微分修正公式,讨论了该方法的收敛性.以日地L₁点附近的Halo轨道为目标轨道,在圆型限制性三体问题模型下设计了其转移轨道,系统地研究了HOI(Halo Orbit Insertion)点和Halo轨道幅值对转移轨道的影响,给出了HOI点的选择策略,并讨论了应急情况下快速转移轨道设计.数值仿真验证了方法的有效性,选择Halo轨道靠近地球侧的点作HOI点可以获得飞行时间适中的转移轨道.     

激光制导炸弹的弹道解算与仿真

介绍了激光制导炸弹的组成、工作原理以及弹道方程的求解,并在给出初始条件下,对传统方式求解和柱坐标方式求解结果进行比较,给出了最理想的求解办法。同时根据实际情况对激光制导炸弹在不同条件下的投放进行了仿真。     

翼伞系统分段归航轨迹的优化设计

如何有效利用翼伞系统自身的可操作性来规划归航轨迹 ,一直是研究人员关心的问题。近来 ,分段设计的方法以其计算简单、轨迹可知和工程实用的特点而备受关注。从六自由度动力学建模和仿真入手 ,分析了翼伞系统飞行的基本特性 ,在此基础上进一步简化了模型。然后详细介绍了一种分段优化设计翼伞轨迹的思想和各阶段的特点 ,仿真试验结果表明此方法是可行的。     

弹射过程座舱盖抛放轨迹的预测

通过分析座舱盖在各个不同抛放阶段的受力关系,并着重考虑了抛放过程中气动系数的修正和铆钉剪切的影响,最终建立了座舱盖抛放轨迹的预测模型.该模型可广泛用于预测不同型号座舱盖在各种飞行状态下的抛放轨迹.算例表明计算结果与实验数据一致,证明了模型的实用性和有效性.     

Kalman弹道滤波器的快速收敛性研究

在弹道修正过程中,需根据一段实测弹道参数,准确地估算常规弹箭的飞行弹道。工程中,常应用Kalman滤波方法,结合质点弹道模型建立六状态滤波弹道模型。速度初值估计的准确性,是对滤波过程造成影响的主要因素。为改善这一状况,采用多项式拟合用以对速度状态进行估计并以此作为滤波初始值。在此种估计下滤波,速度滤波过程可快速收敛,位置滤波过程收敛速度大幅度提高,可使最优弹道诸元参数获取时间缩短30%。     

Satellite proximate interception vector guidance based on differential games

This paper studies the proximate satellite interception guidance strategies where both the interceptor and target can perform orbital maneuvers with magnitude limited thrusts. This problem is regarded as a pursuit-evasion game since satellites in both sides will try their best to capture or escape. In this game, the distance of these two players is small enough so that the highly nonlinear earth-centered gravitational dynamics can be reduced to the linear Clohessy-Wiltshire (CW) equations. The system is then simplified by introducing the zero effort miss variables. Saddle solution is formulated for the pursuit-evasion game and time-to-go is estimated similarly as that for the exo-atmospheric interception. Then a vector guidance is derived to ensure that the interception can be achieved in the optimal time. The proposed guidance law is validated by numerical simulations.     

Reliability-based trajectory optimization using nonintrusive polynomial chaos for Mars entry mission

This paper presents the reliability-based sequential optimization (RBSO) method to settle the trajectory optimization problem with parametric uncertainties in entry dynamics for Mars entry mission. First, the deterministic entry trajectory optimization model is reviewed, and then the reliability-based optimization model is formulated. In addition, the modified sequential optimization method, in which the nonintrusive polynomial chaos expansion (PCE) method and the most probable point (MPP) searching method are employed, is proposed to solve the reliability-based optimization problem efficiently. The nonintrusive PCE method contributes to the transformation between the stochastic optimization (SO) and the deterministic optimization (DO) and to the approximation of trajectory solution efficiently. The MPP method, which is used for assessing the reliability of constraints satisfaction only up to the necessary level, is employed to further improve the computational efficiency. The cycle including SO, reliability assessment and constraints update is repeated in the RBSO until the reliability requirements of constraints satisfaction are satisfied. Finally, the RBSO is compared with the traditional DO and the traditional sequential optimization based on Monte Carlo (MC) simulation in a specific Mars entry mission to demonstrate the effectiveness and the efficiency of the proposed method.     

基于长方体禁飞区的安全绕飞轨迹设计

摘要： 以C W方程为基础针对圆轨道近距离双脉冲绕飞问题,研究基于长方体禁飞区的安全绕飞轨迹设计方法.针对双脉冲绕飞动力学模型中的变量进行代数变换,在此基础上对变量间的关系进行推导,证明部分变量在特定区间范围内具有单调性的定理;给出保证绕飞轨迹安全的约束条件,进而结合推导出的定理和安全约束条件得到轨道面内全方位安全绕飞轨迹的一般性设计方法.通过针对以目标器正后方为绕飞起点的两种典型绕飞以及到任意方位的绕飞进行仿真,验证方法的有效性.