自适应严格收敛非奇异终端滑模制导律

针对机动目标的末制导拦截问题，设计了一种带终端角度约束的有限时间收敛终端滑模制导律。首先，分析了现有非奇异终端滑模制导律存在的滑模面不能严格有限时间收敛的问题，进而构造了一种新型的非奇异终端滑模面。其次，设计了一种对目标机动上界的自适应估计，提出了一种自适应严格收敛非奇异终端滑模制导律的设计方法。最后，基于Lyapunov稳定性理论，证明了设计的制导律能够使得制导系统在有限时间内收敛到零，并且保证了滑模面在收敛过程中不存在非收敛因子，是严格有限时间收敛的。仿真实验验证了该制导律能够有效地拦截机动目标，同时和与现有的非奇异终端滑模制导律以及基于转换滑模面的非奇异制导律相比，拦截时间更短，终端攻击角度精度更高，导弹机动消耗的能量更少。     

考虑落角约束的制导炸弹有限时间控制制导律

为了提高制导炸弹对目标的毁伤能力,更加有效地约束终端落角,利用终端滑模变结构控制理论和有限时间收敛性理论,在选取自适应趋近律和建立弹目相对运动模型的基础上,提出了一种考虑落角约束的制导炸弹有限时间控制制导律。然后,利用Lyapunov理论证明了所选取的滑模面和趋近律是有限时间收敛的。通过仿真实验验证了所提算法的有效性。仿真结果表明:与比例制导律相比,所提制导律既能使制导炸弹在有限时间内收敛到所期望的入射约束角附近,又能使炸弹的视线角及其角速度收敛的更快,具有一定的工程应用价值。     

带攻击角度约束的有限时间收敛制导律

针对航空制导武器带有攻击角度约束打击地面目标的制导问题,提出了基于快速非奇异终端滑模的有限时间收敛制导律.通过引入非奇异终端滑模面,避免了制导过程中可能产生的奇异问题,该制导律具有快速收敛的特性,能够满足攻击角度约束的要求.基于Lyapnov稳定理论证明了有限时间收敛的特性,并给出了收敛时间表达式.仿真结果表明,该制导律具有快速收敛特性,能够满足脱靶量和末端攻击角度的要求,相比传统带落角约束制导律,具有一定的优越性.     

基于终端角度约束的二阶滑模制导律设计

针对空地导弹具有终端角度约束条件的制导律设计问题,提出了一种在有限时间内稳定的新型二阶滑模制导律。首先,在弹目相对运动学模型基础上,将终端弹道倾角约束转化为终端视线(LOS)角度约束,作为制导系统的终端控制目标。其次,通过选取一种新型二阶滑模面,结合螺旋控制算法的思想,设计了一种二阶滑模变结构制导律,来抑制系统中的不确定性因素,从而满足零化视线角速率和制导系统的终端角度约束条件的要求。采用一种新的Lyapunov函数,基于Lyapunov稳定性理论,严格证明了制导系统在有限时间内的稳定性。最后,对空地导弹制导系统进行数字仿真,通过和一阶传统滑模制导律以及基于超螺旋算法的二阶滑模制导律进行对比分析,验证了所设计的制导律在保证制导精度的同时,更能在有限时间内提高终端约束角度的精度,并且避免了超螺旋算法中参数选取较多的问题。     

基于快速非奇异终端滑模的姿态控制技术

针对存在执行器故障与外部干扰的刚体飞行器姿态控制系统,提出一种基于快速非奇异终端滑模(NSFTSM)的姿态容错控制方法.控制方法不仅保证姿态机动过程的快速性,而且避免了传统的终端滑模面所带来的奇异性问题.采用二阶鲁棒精确微分器估计执行器故障与外部干扰,采用快速非奇异终端滑模技术设计姿态容错控制律,根据Lyapunov稳定性理论证明了方法的稳定性.稳定性分析表明,通过引入新型快速非奇异终端滑模,控制器使得闭环系统能够快速收敛到滑模面的微小邻域内,进而收敛到系统平衡点的微小邻域内,并且系统对外部干扰具有较强的鲁棒性.数值仿真结果验证了方法在姿态跟踪控制中的有效性.     

攻击时间约束下的三维制导律

基于三维空间内导弹-目标的相对运动方程,针对固定目标,提出了一种攻击时间约束下的多导弹协同攻击的三维制导律。俯仰通道设计了滑模变结构制导律,偏航通道基于动态逆控制理论,采用机动控制,调整导弹的攻击时间,使其趋于指定值,并与在俯仰通道采用推导的增广比例制导律作了比较。最后,仿真结果表明,该制导律最终能使攻击的剩余时间误差趋于零,能够满足对制导精度和攻击时间的要求,证明了算法的正确性和优越性。     

基于自适应反演滑模的末制导律设计

针对三维导弹-目标相对运动模型,结合反演控制、滑模控制和自适应技术,设计了一种新的自适应反演滑模末制导律。针对目标机动加速度上界难以获取的问题,将目标机动加速度视作模型的干扰,设计了一种自适应律对其进行在线估计,并将估计值补偿到制导律中。运用李亚普诺夫稳定性理论证明了系统的全局渐进稳定性和误差的收敛性。仿真结果证明了所设计的自适应反演滑模末制导律对机动目标的鲁棒性和有效性。     

VTHL运载器再入返回预设时间滑模控制

针对模型参数不确定和存在外部干扰的垂直起飞水平着陆（VTHL）可重复使用运载器再入返回姿态跟踪控制问题，提出一种新型预设时间滑模控制方法，使姿态控制误差收敛时间上界与再入初始状态无关且可预先设定。首先基于反正切函数设计预设时间非奇异滑模面，状态量在滑模面可在预设时间内收敛；其次预设时间滑模控制律，引入正弦补偿函数避免控制量出现奇异，以保证滑动模态在预设时间内到达；为提高控制系统鲁棒性并减弱抖振，采用预设时间扩张状态观测器对扰动进行估计和补偿；最后基于Lyapunov理论，证明了控制律可使姿态控制误差在预设时间内收敛；通过数值仿真验证了所提方法的有效性。     

攻击角度约束下打击机动目标的制导律

针对某些导弹要求限制末端攻击角度的作战要求,基于滑模变结构控制理论,面向机动目标,设计了一种同时满足脱靶量和攻击角度约束要求的制导律.采用自适应滑模趋近律,并将目标机动视为干扰,利用线性变结构制导律推导出目标加速度的估计方程,并通过仿真证实了其有效性.所设计的制导律形式简单、实用.仿真结果表明,该制导律能够以期望的攻击角度命中目标,并对所提出制导律的性能进行了分析,具有一定的工程应用价值.     

基于SDRE法的非线性鲁棒滑模末制导律设计

从智能控制理论出发,针对拦截机动目标的燃料最优问题,提出将状态相关黎卡提方程法(SDRE)和滑模控制相结合的末制导律设计方法,即利用前者将非线性模型转化为基于状态系数的线性结构后设计次优制导律,利用后者实现对机动目标引起的不确定干扰项的补偿。仿真结果表明,与自适应滑模末制导律相比,该方法具有制导精度更高、更加节省燃料的优势。     

Three-dimensional adaptive finite-time guidance law for intercepting maneuvering targets

To intercept maneuvering targets at desired impact angles, a three-dimensional terminal guidance problem is investigated in this study. Because of a short terminal guidance time, a finitetime impact angle control guidance law is developed using the fast nonsingular terminal sliding mode control theory. However, the guidance law requires the upper bound of lumped uncertainty including target acceleration, which may not be accurately obtained. Therefore, by adopting a novel reaching law, an adaptive sliding mode guidance law is provided to release the drawback. At the same time, this method can accelerate the convergence rate and weaken the chattering phenomenon to a certain extent. In addition, another novel adaptive guidance law is also derived; this ensures systems asymptotic and finite-time stability without the knowledge of perturbations bounds.Numerical simulations have demonstrated that all the three guidance laws have effective performances and outperform the traditional terminal guidance laws.     

基于终端角度约束的滑模制导律设计

针对打击地面目标的制导问题,提出了一种新的具有终端角度约束的鲁棒滑模制导律。在建立地面目标和导弹的相对运动学关系的基础上,基于零化弹目视线角速率的思想,采用变结构控制理论的方法,通过选择理想的终端角度确定一个光滑的非线性滑动模态,代替传统末制导律设计的滑动模态,利用Lyapunov稳定理论设计得到了具有鲁棒性的滑模末制导律,实现了在有限时间精确打击目标,满足终端角度的要求。数字仿真表明,这种制导律对目标的运动具有很好的鲁棒性和适应性,并能获得良好的制导精度和指定的终端角度要求。     

Fixed-time position coordinated tracking control for spacecraft formation flying with collision avoidance

In this paper, the fixed-time stability of spacecraft formation reconfiguration (position tracking) is studied. Firstly, a novel nonsingular terminal sliding mode surface is designed and based on which a fixed-time coordinated controller is designed to keep the closed-loop system states have a finite settling time bounded by some predefined constants. Secondly, another nonsingular terminal sliding mode surface is designed by combining the artificial potential function and the aforementioned sliding surface, which meets the mutual distance constraint during transition process among spacecraft when it is bounded. Then another coordinated controller with fixed-time observer considering mutual distance constraint is presented, which guarantees the closed-loop system states stable also in bounded settling time. Finally, simulation results are shown to validate the correctness of the proposed theorems. It is worth mentioning that the control schemes also work even though there is a properly limit on the control input.     

An adaptive fast fixed-time guidance law with an impact angle constraint for intercepting maneuvering targets

Sliding mode guidance laws based on a conventional terminal sliding mode guarantees only finite-time convergence, which verifies that the settling time is required to be estimated by selecting appropriate initial launched conditions. However, rapid convergence to a desired impact angle within a uniform bounded finite time is important in most practical guidance applications. A uniformly finite-time/fixed-time convergent guidance law means that the convergence (settling) time is predefined independently on initial conditions, that is, a closed-loop convergence time can be estimated a priori by guidance parameters. In this paper, a novel adaptive fast fixed-time sliding mode guidance law to intercept maneuver targets at a desired impact angle from any initial heading angle, with no problems of singularity and chattering, is designed. The proposed guidance law achieves system stabilization within bounded settling time independent on initial conditions and achieves more rapid convergence than those of fixed-time stable control methods by accelerating the convergence rate when the system is close to the origin. The achieved acceleration-magnitude constraints are rigorously enforced, and the chattering-free property is guaranteed by adaptive switching gains. Extensive numerical simulations are presented to validate the efficiency and superiority of the proposed guidance law for different initial engagement geometries and impact angles.     

攻击角约束的拦截弹制导控制一体化设计

针对拦截弹的攻击角约束制导问题,提出了一种基于反演滑模和扩张状态观测器(ESO)的制导控制一体化(IGC)设计方法。首先,基于弹目相对运动方程和拦截弹的非线性动力学方程,建立了拦截弹IGC模型,设计了ESO估计目标加速度和自动驾驶仪回路的干扰;在此基础上,基于干扰估计值和反演滑模方法,设计了IGC算法获取虚拟控制力矩,同时基于李雅普诺夫理论分析了闭环系统的稳定性;然后,利用动态控制分配技术将所获取的期望控制力矩分配到实际执行机构;最后,通过仿真结果验证了所设计的IGC+ESO算法的有效性。     

Sliding mode control based guidance law with impact angle constraint

The terminal guidance problem for an unpowered lifting reentry vehicle against a sta- tionary target is considered. In addition to attacking the target with high accuracy, the vehicle is also expected to achieve a desired impact angle. In this paper, a sliding mode control （SMC）-based guidance law is developed to satisfy the terminal angle constraint. Firstly, a specific sliding mode function is designed, and the terminal requirements can be achieved by enforcing both the sliding mode function and its derivative to zero at the end of the flight. Then, a backstepping approach is used to ensure the finite-time reaching phase of the sliding mode and the analytic expression of the control effort can be obtained. The trajectories generated by this method only depend on the initial and terminal conditions of the terminal phase and the instantaneous states of the vehicle. In order to test the performance of the proposed guidance law in practical application, numerical simulations are carried out by taking all the aerodynamic parameters into consideration. The effec- tiveness of the proposed guidance law is verified by the simulation results in various scenarios.     

基于零化相对速度偏角的变结构末制导律设计

针对拦截问题,选取导弹和目标的相对速度矢量与导弹—目标视线之间的夹角（即相对速度偏角）作为滑模面,无须对导弹—目标相对运动学方程进行归一化,且不对弹目速度比进行限制,将有关目标运动的加速度和方位信息视为干扰量,应用变结构理论设计了一种变结构末制导律,并应用Lyapunov理论进行了稳定性分析。仿真结果表明,所设计的导引律对目标机动具有很强的鲁棒性。