过载受限的变结构制导律滑动模态稳定域分析

针对实际导弹过载受限问题,基于到达条件,分析和确定了三维变结构制导律中滑动模态的稳定域.根据末端三维弹目相对运动学关系,建立了三维制导系统的数学模型,并以纵向平面模型和变结构控制中到达条件为基础,引入分段光滑连续函数,以三维平面间的耦合关系为出发点,从两个方面分析并确定了过载受限变结构制导律的滑动模态吸引区,证明其制导系统的稳定性.最后,针对零化视线角速率而设计的变结构制导律,确定了它的滑动模态吸引区,验证了理论分析方法的有效性.     

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。     

基于偏置比例导引的垂直攻击滑模制导律

为了提高空地导弹毁伤效果,需要对地面固定目标采用大角度乃至垂直打击方式。针对这一需求,设计了一种基于偏置比例导引的垂直攻击滑模制导律。首先在传统的比例导引制导律的基础上增加了一个角度约束偏置项,并结合滑模变结构理论使其滑模变结构化。然后运用自适应滑模趋近律,并采用准滑动模态控制削弱了抖振的影响。仿真结果表明:此制导律控制落角能力较强,同时具有较高的命中精度。整个攻击过程中的弹目视线角速度变化较小,最后以垂直落角攻击目标。     

基于时间约束的无人机避障研究

对无人机避开障碍物这一热点问题展开了研究。在极坐标系下,基于无人机与障碍物之间的几何关系,建立了无人机与障碍物之间的运动学方程。通过设计滑模变结构有限时间收敛制导律,使连接无人机与避障点的视线角速率快速收敛到零,相对速度方向收敛到期望的避障方向,保证了无人机能够顺利避开运动障碍物。通过有限时间收敛分析,得到了相对速度收敛到期望的避障方向时间与制导律参数的表达式。通过选择合适的参数,可使收敛时间小于到达避障点的时间,保证了避障的完成,也确定了制导律参数的取值范围。最后对设计的避障算法进行了仿真,仿真结果验证了算法的有效性。     

基于Lyapunov稳定性的扩展比例制导律设计

基于一般弹目平面运动模型,以视线角、视线角速率为状态变量将弹目运动关系转换为二阶控制系统状态空间表达,把制导律设计转化为系统控制律的设计问题.在此控制模型的基础之上,利用Lyapunov稳定性定理,以视线角速率平方项作为能量函数设计了一种新型的扩展比例导引律,与其他扩展比例导引律相比,该导引律不需要增加任何制导观测信息,可以有效抑制噪声影响,并将基于Lyapunov稳定性的末制导律设计方法推广到有终端角约束的制导律设计中.仿真结果比较表明,该制导律可以提高制导精度、有效减小制导信息中的噪声影响.     

滑模方法在空空导弹制导律中的应用

针对空中机动目标,采用滑模变结构方法设计了一种空空导弹三维制导律.在考虑三维拦截的情况下,建立了导弹与目标之间的空间相对运动方程.基于滑模变结构控制理论,推导得到了俯仰和偏航通道的末制导律.对于滑模制导律固有的抖振问题,用饱和函数sta(s)代替理想滑动模态中的s印(s)函数来实现准滑动模态控制,即在边界层外采用切换控制,在边界层内采用线性化反馈控制,有效地减小了抖振的发生.数值仿真结果表明,所设计的制导律相对于比例制导律,对机动目标有更好的拦截效果.     

基于有限时间理论的临近空间拦截器末制导律PWPF调节器研究

针对拦截临近空间高速机动目标,基于有限时间理论,设计了有限时间收敛末制导律和脉冲宽度脉冲频率（PWPF）调节器。首先,介绍了加入PWPF调节器的末制导数学模型及工作原理;其次,设计了有限时间收敛制导律,应用有限时间理论证明了收敛条件和性质,并推广到推力受限条件下;最后,考虑视线（LOS）角速率快速收敛和发动机最小工作时间要求,设计了PWPF调节器参数。仿真结果表明,视线角速率在制导结束前的有限时间收敛至零,对目标机动具有鲁棒性,具有较高的制导精度,避免了发动机频繁开启,节省了燃料。     

基于模糊RBF网络的自适应变结构制导律设计

针对空中高速、大机动目标的拦截问题,传统的滑模变结构制导律虽然对外界干扰和参数摄动具有较好的鲁棒性,但是存在视线角速率抖振及参数不易确定等缺点.对此,在变结构控制理论的基础上,提出了三维自适应变结构制导律,将目标加速度视为外界干扰,设计了一种快速趋近律,并利用模糊RBF网络的高效自学习能力对变结构项的增益进行了在线自适应调节.仿真结果表明,该制导律能够有效削弱系统抖振,提高制导精度,并对拦截大机动目标具有很强的自适应性.     

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。     

高速再入飞行器带落角约束末制导律研究

针对高速再入飞行器以预定角度攻击地面目标的要求,提出了一种基于Lyapunov稳定性定理的具有终端落角约束的末制导律.该制导律在纵向平面内将视线角及其角速率视为状态变量,合理构造Lyapunov函数,通过调节Lyapunov函数的系数,保证以期望的落角击中目标.该导引律不需增加任何制导观测信息,就可以有效满足落角约束要求.最后,以CAV-H为对象进行了三维仿真.仿真结果表明,该制导律能有效提高制导精度,并且多项性能指标均优于最优制导律.     

Three-dimensional finite-time cooperative guidance for multiple missiles without radial velocity measurements

In order to simultaneously attack a target with impact angle constraint in threedimensional(3-D) space, a novel distributed cooperative guidance law for multiple missiles under directed communication topologies is proposed without radial velocity measurements. First, based on missiles-target 3-D relative motion equations, the multiple missiles cooperative guidance model with impact angle constraint is constructed. Then, in Line-of-Sight(LOS) direction, based on multiagent system cooperative control theory, one guidance law with directed topologies is designed with strict proof, which can guarantee finite time consensus of multiple missiles' impact times. Next, in elevation direction and azimuth direction of LOS, based on homogeneous system stability theory and integral sliding mode control theory, two guidance laws are proposed respectively with strict proof, which can guarantee LOS angles converge to desired values and LOS angular rates converge to zero in finite time. Finally, the effectiveness of the designed cooperative guidance law is demonstrated through simulation results.     

Three-dimensional guidance law based on adaptive integral sliding mode control

For the terminal guidance problem of missiles intercepting maneuvering targets in the three-dimensional space, the design of guidance laws for non-decoupling three-dimensional engage-ment geometry is studied. Firstly, by introducing a finite time integral sliding mode manifold, a novel guidance law based on the integral sliding mode control is presented with the target acceler-ation as a known bounded external disturbance. Then, an improved adaptive guidance law based on the integral sliding mode control without the information of the upper bound on the target accel-eration is developed, where the upper bound of the target acceleration is estimated online by a designed adaptive law. The both presented guidance laws can make sure that the elevation angular rate of the line-of-sight and the azimuth angular rate of the line-of-sight converge to zero in finite time. In the end, the results of the guidance performance for the proposed guidance laws are pre-sented by numerical simulations. Although the designed guidance laws are developed for the con-stant speed missiles, the simulation results for the time-varying speed missiles are also shown to further confirm the designed guidance laws.     

Finite-time composite guidance law with input constraint and dynamics compensation

Guidance laws are proposed for a near space interceptor with on–off type thrust as output. The target-interceptor engagement kinematics is integrated with the first-order dynamics of thruster to design guidance laws. The bang-bang type guidance law with linear sliding mode is proposed to deal with thruster dynamics, and the sufficient condition for finite time convergence is rigorously proved based on the finite-time convergence theory. According to the sufficient condition, a sliding mode guidance law with hysteresis-band switching is introduced to reduce the switching frequency of thruster. Then two guidance laws are combined into a composite guidance law to improve the guidance performance. Simulation results show that the line-of-sight angular rate can converge to a neighborhood of the equilibrium point before the final time of the guidance process, and the composite guidance law has better performance than typical guidance laws.     

滚转舰炮制导炮弹的空间多约束导引与控制一体化设计

在大口径舰炮制导炮弹打击近岸机动目标的末段,考虑攻击角、控制受限、视线（LOS）角速率测量受限等约束,提出了一种基于块动态面与扩张状态观测器（BDSESO）的多约束空间导引与控制一体化设计（IGC）方法。构建了滚转制导炮弹的空间导引与控制一体化的严块反馈串级模型,运用扩张状态观测器估计视线角速率和目标机动、建模误差、风等系统内外不确定干扰。为了在有限时间内零化视线角跟踪误差与视线角速率,采用自适应指数趋近律设计非奇异终端滑模,通过自适应动态面控制有效镇定串级系统并避免微分膨胀,引入自适应Nussbaum增益函数补偿控制受限的饱和非线性。通过Lyapunov理论证明了视线角跟踪误差、视线角速率的有限时间收敛性与全系统状态的一致最终有界性。半实物仿真实验表明：该方法使制导炮弹在打击具有不同机动形式的目标时,均具备较好的末制导性能。     

带空间协同的多导弹时间协同制导律

针对多导弹在平面内从期望的弹目视线（LOS）相对方向同时击中固定目标问题,提出了一种带空间协同的多导弹时间协同制导律。基于平面内的导弹-目标相对运动方程,建立了带空间协同的多导弹时间协同制导模型;基于多智能体协同控制理论,在视线方向设计了分布式时间协同制导律,可保证所有导弹的打击时刻在有限时间内达到一致,在视线法向方向设计了分布式空间协同制导律,可保证所有导弹的相对视线角在有限时间内收敛到期望值;最后,通过仿真验证了所设计的协同制导律可使多导弹从期望的弹目视线相对方向同时击中目标。     

Three-dimensional time-varying sliding mode guidance law against maneuvering targets with terminal angle constraint

This paper deals with the problem of intercepting maneuvering targets with terminal angle constraints for missiles subjected to three-dimensional non-decoupling engagement geometry.To achieve the finite-time interception and satisfactory overload characteristics, a time varying sliding mode control methodology is developed based on a time base generator function. The main feature of the proposed guidance law guarantees the Line-of-Sight(LOS) angles to converge to small neighborhoods of the desir...     

STUDY OF OPTIMAL SLIDING-MODE GUIDANCE LAW

An optimal guidance law based on missile-target line-of-sight (LOS) angular rate is presented for intercepting a nonmaneuvering target. It is then integrated with sliding-mode control theory by using reaching-law of sliding-mode, in order to derive an optimal sliding-mode guidance law for intercepting a maneuvering target. The new guidance method's robustness against target maneuvers and good miss distance performance are proved by the second method of Lyapunov and simulation results. The presented guidance law is simple to implement in practical applications.     

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。