多导弹协同攻击编队非线性最优控制器设计

针对多导弹协同攻击编队控制问题,采用仿射非线性系统最优控制理论设计了基于领弹-从弹法的多导弹编队控制器.首先采用基于微分几何理论的非线性系统精确线性化方法,将导弹非线性运动模型线性化;然后根据从弹、领弹间的相对运动关系,给出了包含领弹运动信息和队形信息的从弹期望轨迹,建立了基于从弹跟踪误差向量的系统状态方程;最后采用基于稳态解的黎卡提矩阵微分方程求解方法解决最优控制问题,设计了从弹的三维非线性编队控制器;仿真结果表明所设计的控制器能够在领弹机动地情况下快速、稳定地实现编队队形的形成和保持.      

卫星编队飞行有限时间控制方法

针对卫星编队飞行相对位置控制问题,提出了一种有限时间控制方法.首先,建立了编队卫星相对运动的非线性动力学方程.其次,设计了有限时间快速收敛的滑模面,提出了一种有限时间控制方法,该方法能保证闭环控制系统的全局稳定性和快速收敛性,并给出了理论证明.最后,将提出的方法应用于卫星编队飞行维持控制.仿真结果表明该方法在收敛时间和控制精度方面均优于传统线性滑模控制和终端滑模控制.     

MIMO仿射型极值搜索系统的输出反馈滑模控制

针对一类多输入多输出(MIMO)仿射型非线性极值搜索系统的控制问题,提出了一种输出反馈滑模控制方法。将原系统分解为若干个单输入单输出(SISO)极值搜索子系统,并针对每个极值搜索子系统,考虑到系统状态量不可测的特点,以斜坡函数作为新系统输出量的参考跟踪信号,采用输出跟踪误差以及该误差符号函数的积分值建立切换函数,设计得到基于输出反馈的滑模极值搜索控制律。稳定性分析证明:在任意初始条件下,本文方法可使系统的输出量全局收敛至期望极值的任意小邻域内,并且所有状态量均一致范数有界。仿真结果验证了本文方法的有效性。      

Nonlinear attitude tracking control for spacecraft formation with multiple delays

This paper addresses the attitude tracking control for spacecraft formation with delay free and communication delays. With help of the idea of sliding control, an adaptive attitude synchronization control architecture is established. Furthermore, by introducing a nonsmooth feedback function, a new class of nonlinear controllers for the attitude tracking of spacecraft is developed. Both parameter uncertainties and unknown external disturbances are dealt with via the kind of controllers. Finally, some simulation results are given to demonstrate the effectiveness and advantages of the proposed results.     

一种翻滚非合作航天器抵近绕飞避障轨迹规划和跟踪控制方法

针对空间无人在轨服务任务中翻滚非合作航天器抵近、绕飞和避障问题，在目标特征部位本体坐标系，建立了轨道和姿态相对运动模型.设计了抵近和绕飞策略，以抵近轨迹的燃料和时间最优为目标函数，考虑规避障碍物情况，结合动力学和路径等约束条件进行轨迹规划，最后采用高斯伪谱法对连续最优控制问题进行离散转化，对转化后的非线性规划问题进行求解，得出最优路径.同时基于轨道和姿态协同的六自由度轨迹跟踪误差模型，设计了全状态反馈轨迹跟踪控制律，在相对运动姿态和轨道模型的基础上，对控制过程进行了闭环仿真验证，结果表明了姿轨耦合轨迹跟踪控制律的有效性和稳定性.     

Matching trajectory optimization and nonlinear tracking control for HALE

This paper concerns optimal trajectory generation and nonlinear tracking control for stratospheric airship platform of VIA-200. To compensate for the mismatch between the point-mass model of optimal trajectory and the 6-DOF model of the nonlinear tracking problem, a new matching trajectory optimization approach is proposed. The proposed idea reduces the dissimilarity of both problems and reduces the uncertainties in the nonlinear equations of motion for stratospheric airship. In addition, its refined optimal trajectories yield better results under jet stream conditions during flight. The resultant optimal trajectories of VIA-200 are full three-dimensional ascent flight trajectories reflecting the realistic constraints of flight conditions and airship performance with and without a jet stream. Finally, 6-DOF nonlinear equations of motion are derived, including a moving wind field, and the vectorial backstepping approach is applied. The desirable tracking performance is demonstrated that application of the proposed matching optimization method enables the smooth linkage of trajectory optimization to tracking control problems.     

广义正交多项式在时变系统跟踪问题中的应用

采用广义正交多项式的展开技术,利用其积分、乘积运算阵,对于时变线性系统最优控制中的跟踪问题,直接从最优控制的性能泛函入手,将最优控制问题转化为代数极值问题,从而避免了求解非线性Riccati方程,得到了一个较为简便的算法,并结合实例说明了方法的可行性.      

Multi-agent Q-Learning control of spacecraft formation flying reconfiguration trajectories

This paper presents a novel approach based on multi-agent reinforcement learning for spacecraft formation flying reconfiguration tracking problems. In this scheme, spacecrafts learn the control strategy via transfer learning. For this matter, a new generalized discounted value function is introduced for the tracking problems. Due to the digital nature of spacecraft computer systems, local optimal controllers are developed for the spacecrafts in discrete-time. The stability of the controller is proven. Two Q-learning algorithms are proposed, in each of which the optimal control solution is learned on-line without knowledge about the system dynamics. In the first algorithm, each agent learns the optimal control independently. In the second one, each agent shares the learned information with other agents. Next, the collision avoidance capability is provided. The effectiveness of the presented schemes is verified through simulations and compared with each other.     

Constrained adaptive fault-tolerant attitude tracking control of rigid spacecraft

A saturated fault-tolerant attitude tracking controller for disturbed rigid spacecraft is derived using nonlinear state feedback control method. The proposed controller achieves the constraints of control inputs by directly using the bounded function instead of the traditional saturation compensator technique, and the active tolerance to the partial loss of actuator effectiveness is also achieved by directly using the known bounds of the actuator faults in the controller. Specifically, compared with the traditional saturated control methods, a continuously bounded nonlinear function in the proposed controller is used to guarantee that the actuator outputs are smoothly bounded under the prescribed constraints. Based on some properties of the attitude tracking dynamics, the proposed controller can ensure the attitude tracking errors converge to small neighborhoods of zero via stability analysis in the Lyapunov framework. Simulation results are presented to illustrate the effectiveness of the control scheme.     

电磁航天器编队位置跟踪自适应协同控制

通过引入一致性理论针对电磁航天器编队相对位置协同控制问题设计了自适应协同控制器。分析了电磁航天器编队的基本原理,建立了电磁航天器编队相对运动精确的非线性动力学方程。基于电磁力远场计算模型的不确定性,对相对运动动力学模型进行了修正。在电磁力计算模型不确定和航天器间存在通信时延的条件下,对位置跟踪控制的目标设计了自适应协同控制器。考虑到电磁航天器磁矩产生能力的不同,给出了通过优化进行磁矩分配的方案。通过仿真表明:所设计的自适应协同控制器不仅实现了对期望轨迹的准确跟踪,而且相比人工势函数法,暂态维持编队构型的能力提高了4.9倍,并且所给出的磁矩分配方案实现了磁矩的合理分配。     

基于事件触发的多机编队目标跟踪控制

为解决多机编队目标跟踪过程中存在的机间通信和控制更新频繁的问题，提出了一种具有事件触发机制的多机编队目标跟踪控制算法。首先，给出了一种具有事件触发策略的编队队形描述与目标跟踪一体化算法，简化了算法设计的复杂度，并使触发机制的工作过程更加直观；其次，给出了分布式目标跟踪控制律，并仅利用状态估计信息设计了事件触发函数，使无人机间通信与控制更新问题转换为判别触发函数的取值问题，同时设计了最小触发间隔系数，避免了可能存在的"Zeno行为"；最后，以编队不同的运动模式对算法进行了仿真验证。研究结果表明:所提算法能使无人机编队在机间通信与控制更新次数明显减少的情况下跟踪上目标。      

6-DOF formation keeping control for an invariant three-craft triangular electromagnetic formation

Spacecraft relative motion with inter-craft electromagnetic force has distinct advantages, and its invariant shapes that are convenient for formation keeping ensure some potential significant applications. However, the electromagnetic actuators affect both the relative trajectory and attitude motion, complicating related researches on issues of invariant shape design and formation control. In this paper, the formation keeping problem for an invariant three-craft triangular electromagnetic formation is investigated on the basis of a 6-DOF full nonlinear dynamic model. Moreover, a combined control scheme consisting of feed-forward and feed-back control components is proposed to handle the high nonlinearity, strong coupling, model uncertainties and external disturbances. The feed-forward component is obtained through desired invariant shape design which is complicated by the coupling and superposition effects of any two distinct magnetic dipoles, and the feed-back component is developed with a combination of linear feed-back controller by the LQR method and active disturbance rejection by the extended state observer. Finally, the numerical simulation is presented to verify the feasibility and validity of the proposed 6-DOF combined control scheme.     

一种用于目标跟踪的UT-BLUE滤波方法

雷达机动目标跟踪问题中,通常目标运动模型可精确地在直角坐标系下建模,但大多数情形下模型是非线性的,同时在传感器坐标系下所获得目标量测又是直接可用的.通过将无迹变换与最优线性无偏滤波器有机结合,提出一种新的BLUE(Best Linear Unbiased Estimator) 滤波算法,以便解决上述非线性跟踪问题.首先,该算法利用无迹变换对经由直角坐标系下非线性目标运动模型得到的目标状态及其协方差作出预测,然后在保持传感器坐标系(极坐标系)下所固有的量测误差的同时,直接对它们作出状态估计.在算法推导及Monte-Carlo仿真过程中,将新的BLUE滤波算法和EKF(Extended Kalman Filter)、UKF(Unscented Kalman Filter)滤波算法进行比较,结果表明新算法的有效性和适用性.      

航天器姿态指向跟踪的一种自适应滑模控制方法

航天器姿态指向跟踪(APT)技术是近年来引起深入研究的关键技术之一,设计一种自适应滑模控制律,通过设计自适应律考虑有界干扰力矩和转动惯量不确定因素的影响,同时使用滑模控制设计方法保证控制算法的鲁棒性,用双曲正切函数代替符号函数来克服滑模控制中存在的抖振问题,实现受控航天器的某个指向(相机或天线)保持对运动目标的跟踪.控制方案采用修正罗德里格斯参数(MRP)描述航天器姿态,用喷气推力器作为航天器的姿态执行机构.仿真结果显示了控制律的有效性.     

输入受限的编队卫星分布式姿态协同控制

研究了跟踪时变参考姿态情况下的编队飞行卫星协同控制问题,提出了一种非线性饱和的分布式协同控制器。在控制器中引入了一个双曲正切函数向量,保证了连续控制输入的有界性。采用Barbalat引理对姿态跟踪情况下闭环协同控制系统的稳定性进行了分析,得出了系统渐近稳定的结论。通过对各种条件下的仿真,验证了算法的有效性,并确立了编队卫星信息流图的拓扑结构和控制器增益等因素与暂态过程中相对姿态保持性能的关系。     

Robust optimal sliding mode control for the deployment of Coulomb spacecraft formation flying

Inter-spacecraft electrostatic force (Coulomb force) is desirable for close formation flying control because of its propellant-less and free contaminate characteristics attributed to the propellant exhaust emission. This paper presents robust optimal sliding mode control to deal with the problem of thruster saturation in tracking the formation trajectory for Coulomb spacecraft formation flying. The robust controller design is based on optimal control theory as a linear quadratic system, and it is augmented with an integral sliding mode control technique. The stability of the closed-loop system is guaranteed using the second Lyapunov method. The developed controller outperforms the existing ones, because it has a higher degree of fine-tuning to cope with the uncertainty. Numerical simulations are employed to confirm the efficiency of the developed controller.     

月球精确软着陆制导轨迹在轨鲁棒跟踪

为实现在月球表面期望的着陆点进行精确软着陆(PPL),在开环制导规划出的最优标称轨迹基础上,考虑动力下降过程中的干扰和不确定性,对在轨闭环轨迹跟踪制导方法进行研究.针对月球PPL三维球体非线性轨道动力学模型,充分考虑自主制导的鲁棒性、实时性要求,采用动态平面控制技术的思想,解决退步法存在的"计算复杂性膨胀"问题,并证明了闭环系统的稳定性.仿真算例表明,该方法不仅算法简单,过渡过程能够实现快速跟踪,而且能够保证稳态跟踪误差在预先给定的范围之内且可以自由调节.     

二阶多智能体系统自抗扰编队跟踪与避撞控制

在多智能体编队的目标跟踪任务中，智能体受环境中的障碍物的遮挡作用会丢失目标，而外部扰动会影响系统的时变编队跟踪的控制效果。为此，研究了这两种因素同时存在情况下的二阶多智能体系统时变编队跟踪和避撞控制。采用基于目标跟踪优先级的切换拓扑控制策略以实现在障碍物遮挡环境中对目标的持续跟踪，根据自抗扰理论设计包含扰动补偿项的编队跟踪控制器。首先，基于一致性方法提出切换拓扑下自抗扰时变编队跟踪控制协议，并给出一种基于跟踪微分器的编队指令生成方法；其次，设计了求解控制参数的算法并给出协议作用下系统的稳定性分析和证明；然后，基于人工势场法设计避撞控制协议；最后，提出障碍物遮挡环境下自抗扰时变编队跟踪控制协议。仿真实验结果表明:所设计的控制协议在上述两种因素存在时仍具有良好的控制效果。      

Backstepping sliding-mode control of stratospheric airships using disturbance-observer

In the presence of unknown disturbances and model parameter uncertainties, this paper develop a nonlinear backstepping sliding-mode controller (BSMC) for trajectory tracking control of a stratospheric airship using a disturbance-observer (DO). Compared with the conventional sliding mode surface (SMS) constructed by a linear combination of the errors, the new SMS manifold is selected as the last back-step error to improve independence of the adjustment of the controller gains. Furthermore, a nonlinear disturbance-observer is designed to process unknown disturbance inputs and improve the BSMC performances. The closed-loop system of trajectory tracking control plant is proved to be globally asymptotically stable by using Lyapunov theory. By comparing with traditional backstepping control and SMC design, the results obtained demonstrate the capacity of the airship to execute a realistic trajectory tracking mission, even in the presence of unknown disturbances, and aerodynamic coefficient uncertainties.