基于柔顺机构的新型可变形机翼设计方法研究

机翼翼型变体技术可以根据任务和环境自适应地改变机翼形状、厚度、弯度等重要参数,使飞机在不同飞行状态下都能取得较理想的气动特性。柔顺机构是实现机翼蒙皮光滑变形的驱动装置,相比传统液压机构具备质量特性好的优势。采用鱼骨型柔性钢架与四连杆机构实现了机翼前缘上下蒙皮向内收缩、前缘形状由钝变尖的弹性变形过程。通过设计“撞块”机构实现驱动行程的有效分解,解决了前缘尖端开口处蒙皮回收与机翼变形控制所需的驱动行程不一致的内在矛盾。变形后翼型与目标翼型误差最大位置不超过4 mm,变形过程中结构最大应力小于材料许用应力值。相比传统采用纯液压机构驱动的变形机翼设计方案,该基于柔顺机构的变体机翼结构减质14.1%。     

SO(3)上航天器自适应反步姿态跟踪控制

针对刚体航天器姿态跟踪控制问题,提出了一种自适应反步控制方法。首先,考虑模型不确定性和外部干扰影响,通过引入一个非负定的势函数来描述姿态跟踪误差,在特殊正交李群SO(3)上建立描述航天器姿态运动的相对动力学方程,所建立的动力学模型有效地避免了用修正罗德里格参数或四元数描述航天器姿态时引起的奇异和退绕等问题;其次,设计的自适应反步控制器可保证闭环控制系统最终一致有界收敛,并用李亚普诺夫理论严格证明了闭环系统的稳定性;此外,设计的自适应控制律可以有效地处理系统总干扰;最后,针对航天器姿态跟踪控制场景进行数值仿真分析。结果表明:与传统PD控制器相比,所设计的控制器可以有效地提高控制性能。     

T-Mac激光跟踪系统动态性能分析

针对基于视觉测量技术的六自由度激光跟踪仪,阐述了其工作原理及动态性能的测试方法,着重考核了T-Mac激光跟踪系统动态姿态角测量准确度。     

交互多模型PHD滤波跟踪多目标方法

在机动多目标跟踪问题中,目标数未知或随时间而变化,概率假设密度（PHD）滤波可以在每一时间步估计多目标状态和目标数,但单模型方法不能给出精确的估计。提出了一种交互多模型PHD滤波方法,建立多模型描述多目标运动方式,利用PHD滤波结合多模型跟踪目标运动轨迹。同时,给出了多传感器交互多模型PHD滤波方法,以提高目标跟踪精度。     

Acceleration tracking control for a spinning glide guided projectile with multiple disturbances

A novel acceleration tracking controller is proposed in this paper, for a Spinning Glide Guided Projectile (SGGP) subject to cross-coupling dynamics, external disturbances, and parametric uncertainties. The cross-coupled dynamics for the SGGP are formulated with mismatched and matched uncertainties, and then divided into acceleration and angular rate subsystems via the hierarchical principle. By exploiting the structural property of the SGGP, model-assisted Extended State Observers (ESOs) are designed to estimate online the lumped disturbances in the acceleration and angular rate dynamics. To achieve a rapid response and a strong robustness, integral sliding mode control laws and sigmoid-function-based tracking differentiators are integrated into the ESO-based Trajectory Linearization Control (TLC) framework. It is proven that the acceleration tracking controller can guarantee the ultimate boundedness of the signals in the closed-loop system and make the tracking errors arbitrarily small. The superiority and effectiveness of the proposed control scheme in its decoupling ability, accurate acceleration tracking performance and anti-disturbance capability are validated through comparisons and extensive simulations.     

Guaranteed performance based adaptive attitude tracking of spacecraft with control constraints

The guaranteed performance control problem of spacecraft attitude tracking with control constraint, disturbance and time-varying inertia parameters is investigated. A new saturation function is designed to satisfy different magnitude constraints by introducing a piecewise smooth asymmetric Gauss error function. Based on the mean-value theorem, the constrained problem is transformed into an unconstrained control design subject to an unknown bounded coefficient matrix. To satisfy the constraints by performance functions, a tracking error constrained control is developed based on a hyperbolic arc-tangent asymmetric barrier Lyapunov function (BLF). In the backstepping framework, an adaptive robust control law is proposed by employing a smooth robust term simultaneously counteracting the parametric and non-parametric uncertainties, where the unknown coefficient matrix resulting from the control constraint is compensated by a Nussbaum function matrix. Rigorous stability analysis indicates that the proposed control law realizes the asymptotically tracking of spacecraft attitude and that the tracking error remains in a prescribed set which implies the achievement of the guaranteed transient performance. Numerical simulations validate the proposed theoretical results.     

轨迹跟踪伺服系统的鲁棒复合控制

针对控制输入饱和受限且带有未知扰动的电机伺服系统,提出一种实现曲线轨迹准确跟踪的鲁棒复合控制方案。该方案引入一个参考信号生成器和一个扩展状态观测器,其中参考信号生成器可根据目标轨迹信号构造出对应的状态量,扩展状态观测器用于对系统的状态量和扰动进行估计, 采用反馈与前馈相结合构成最终的控制律。利用Lyapunov理论对闭环系统的稳定性进行了严格分析。在MATLAB中进行了仿真研究,随后在一个DSP控制的永磁直线电机二维伺服平台进行了试验验证。结果表明:所提的控制方案能在轨迹跟踪任务中取得优越的瞬态性能和稳态准确性,而且对目标轨迹和扰动的幅值差异具有较好的鲁棒性。     

High precision attitude dynamic tracking control of a moving space target

On-orbit spacecraft face many threats, such as collisions with debris or other spacecraft.Therefore, perception of the surrounding space environment is vitally important for on-orbit spacecraft.Spacecraft require a dynamic attitude tracking ability with high precision for such missions.This paper aims to address the above problem using an improved backstepping controller.The tracking mission is divided into two phases: coarse alignment and fine alignment.In the first phase,a traditional saturation controller is utilized to limit the maximum attitude angular velocity according to the actuator's ability.For the second phase, the proposed backstepping controller with different virtual control inputs is applied to track the moving target.To fulfill the high precision attitude tracking requirements, a hybrid attitude control actuator consisting of a Control Moment Gyro(CMG) and Reaction Wheel(RW) is constructed, which can simultaneously avoid the CMG singularity and RW saturation through the use of an angular momentum optimal management strategy, such as null motion.Finally, five simulation scenarios were carried out to demonstrate the effectiveness of the proposed control strategy and hybrid actuator.     

基于Doppler估计的弹载接收机抗欺骗干扰研究

GNSS接收机在军用方面尤其是高精度制导武器中的应用日益增强.针对卫星信号易受敌方欺骗信号干扰的问题,设计一种基于Doppler频率估计的弹载接收机抗欺骗干扰的方法.首先分析了欺骗干扰和真实信号的Doppler变化特点;然后在捕获阶段利用残留信号检测存在欺骗干扰的卫星编号;最后根据弹载的高动态特性,在跟踪阶段采取扩展 Kalman 滤波器(EKF)进行载波Doppler频率估计,并根据Doppler变化的相似性提取出欺骗信号.通过仿真实验验证,该方法可以有效排除欺骗信号的干扰.     

时延遥操作系统的非对称双通道波变量补偿法

为保证遥操作系统在时延条件下的稳定性,以及减少传统波变量方法的跟踪误差,提出一种非对称双通道波变量补偿法。该方法在前向通道波变量补偿法的基础上,采用能量整定器对反向通道的波变量进行补偿。通过调节波阻抗、滤波器和能量整定器的相关参数可以充分保证遥操作系统的稳定性和跟踪性能。实验结果表明该方法在保证时延遥操作系统稳定性的基础上,速度跟踪平均误差比传统波变量法减少70%以上,力跟踪平均误差比前向通道波变量补偿法减少60%以上。为了比较不同时延下本方法的效果,设计时延分别为3s和0.6s的2种实验。结果表明本方法在不同时延条件下均可以取得较好的效果。