PREDICTIVE VARIABLE STRUCTURE CONTROL FOR A CLASS OF NONLINEAR SYSTEM

Nonlinear sliding mode predictive controller is designed for a class of nonlinear system with unmodeled dynamic characteristics and nonlinear term. The method is based on nonlinear optimal predictive control. The variable structure control law minimizes the quadratic index of a predictive sliding mode, which contains the cost function of control preventing the control effect from saturation for in most practical implementation the control inputs are bounded by physical constraints and energy constraints. According to the immeasurable states, the variable structure observer for nonlinear systems is adapted. The variable structure system method is apt to the realization of observer with variable parameters and uncertainty. The proof shows that the states of the observer asymptotically convergence to the real states of the system although it is of uncertainty and nonlinear terms. Finally, the digital simulation results prove the effectiveness of the proposed method.     

RESEARCH OF THE SWITCHED RELUCTANCE STARTER/GENERATOR SYSTEMS

This paper focuses on the simulation and test of the switched reluctance starter/generator systems. Through the emulational analysis of the initial starting torque, the optimal turn-on section of the power switches is discovered. The fundamental theory of the generating operation is analyzed with the linearity model, and a new method is presented based on voltage pulse width modulation for the generating mode control. Through the steady-state and optimized emulation of the output power and system efficiency, the optimizational control approach for the generating mode over a wide speed range is introduced. At last, the test of the 3KW prototype system shows that the dynamic and static performance of this system is fine.     

基于T-S模型的飞控系统跟踪控制器设计

提出了用PDC跟踪控制器设计飞控系统的方法,给出了稳定性和极点配置定理,将控制器的参数求取问题转化为求解线性矩阵不等式族的问题,所设计的控制器不仅具有全局渐近稳定性,还具有较好的鲁棒性。对用该方法设计的俯仰角跟踪控制器进行了仿真和鲁棒性验证。仿真结果表明,所设计的控制器能够满足性能品质和鲁棒性要求。     

满足二次稳定及干扰抑制性能指标的航空发动机H∞控制器设计

对于一类状态及输出矩阵存在结构参数摄动的对象,本文提出了闭环系统满足二次稳定性及干扰抑制性能的动态输出反馈控制器的理论设计方法,随后进行的仿真结果表明,所设计的控制器满足要求。      

双马来酰亚胺／E—玻璃布复合材料的研制

研究了用于雷达罩的改性双马来酰亚胺（ＢＭＩ）／Ｅ－玻璃布复合材料板的介电性能、温度对材料力学性能的影响以及耐热性能,并采用波导法测定了改性ＢＭＩ／Ｅ－玻璃布复合材料雷达罩的透波率。结果表明,这种材料能够满足雷达罩的介电性和耐热性要求。     

Integrated method of guidance,control and morphing for hypersonic morphing vehicle in glide phase

The morphing technology of hypersonic vehicle improved the flight performance by changing aerodynamic characteristics with shape deformations, but the design of guidance and control system with morphing laws remained to be explored. An Integrated of Guidance, Control and Morphing (IGCM) method for Hypersonic Morphing Vehicle (HMV) was developed in this paper. The IGCM method contributed to an effective solution of morphing characteristic to improve flight performance and reject the disturbance for guidance and control system caused by the morphing system for HMV in gliding phase. The IGCM models were established based on the motion models and aerodynamic models of the variable span vehicle. Then the IGCM method was designed by adaptive block dynamic surface back-stepping method with stability proof. The parallel controlled simulations’ results showed the effectiveness in accomplishing the flight mission of IGCM method in glide phase with smaller terminal errors. The velocity loss of HMV was reduced by 32.8% which inferred less flight time and larger terminal flight velocity than invariable span vehicle. Under the condition of large deviations of aerodynamic parameters and atmospheric density, the robustness of IGCM method with variable span was verified.     

高性能飞机发展对控制理论的挑战

根据笔者30余年来飞行试验研究的实践,从实际飞行的角度简要综述了影响飞行安全的大迎角过失速机动、超低空重载空投、飞行器突发故障和无人机控制方法研究。描述了操纵稳定性飞行试验获取飞机模型的手段和通常飞行控制器设计对模型的近似,给出了8个飞行鲁棒控制的研究问题;对超低空重载空投控制方法进行了描述,并给出了飞行器出现故障时突变模型和容错控制方法;同时,描述了测量对飞行控制特别是对保障无人机飞行安全的重要性,指出了飞行控制方法研究存在的部分问题,并建议有关高校研究单位从稳定性很好的四旋翼转向固定翼或单旋翼战术无人机等高层次研究。     

飞控系统模糊控制器设计及稳定性分析

建立了飞控系统的Ｔａｋａｇｉ－Ｓｕｇｅｎｏ（Ｔ－Ｓ）模糊模型;给出了设计模糊状态反馈控制器,保证闭环系统全局渐近稳定、具有一定衰减率稳定的两个充分条件;提出了采用线性矩阵不等式（ＬＭＩ）方法,将该充分条件转化为对线性矩阵不等式族寻求ＬＭＩ可行解的凸优化问题,得到了稳定性分析和模糊状态反馈控制器设计的新方法。仿真结果表明,所提出的设计方法方便有效,控制器鲁棒性好。     

基于μ理论的飞机俯仰姿态控制

针对飞机飞行条件变化引起的模型不确定性问题,基于μ控制理论设计鲁棒的俯仰姿态控制系统.首先,根据干扰抑制原理将俯仰姿态控制系统设计转化为μ综合的一般框架,合理地选择加权函数确定广义被控对象,通过引入虚拟的不确定块将鲁棒性能问题转化为广义系统的鲁棒稳定性问题.然后,利用D-K迭代算法求解得到14阶的μ控制器,基于平衡截断...     

基于机载实时模型的发动机执行机构 故障状态参数估计

为了对发动机的主燃烧室供油量控制器、喷管喉部面积控制器、风扇进口可调导叶角度控制器、压气机进口可调导叶角度控制器进行故障诊断,建立了基于简化n+1残量方法的非线性机载实时模型,并结合常增益扩展卡尔曼滤波器建立执行机构控制参数估计器,利用非线性部件级模型模拟飞行包线内发动机执行机构的软故障.仿真结果表明:执行机构控制参数估计器在飞行包线内能实现较高精度估计,且具有较好的稳定性.     

过失速机动飞机的鲁棒非线性控制律设计

 采用非线性动态逆和结构奇异值综合方法设计了过失速飞行条件下飞控系统控制律,解决了飞控设计中面临的非线性和鲁棒性问题。应用非线性动态逆的目的就是对过失速机动飞行条件下高度非线性的飞机动力学进行线化;从而围绕线性的快逆回路应用结构奇异值综合方法设计相应的鲁棒控制器,以提供对驾驶员指令的鲁棒跟踪。所设计的飞控系统将达到期望的飞行品质,确保系统对过失速机动飞行过程中因非定常气动力效应引起的系统参数摄动鲁棒性良好。高逼真度、非线性的仿真验证了这一点。     

单兵火箭弹简易制导控制方法研究

为降低单兵制导火箭弹的成本,同时确保其具有较远的作用距离和较高的命中精度,针对静止目标,设计了单兵火箭弹简易制导控制律.首先,将飞行弹道进行分段设计,以瞄准线作为基准弹道,采用虚拟目标导引法实现对基准弹道的跟踪;然后,进行STr控制器的设计,基于典型设计点处控制器的参数插值,得到实时飞行过程中的控制器参数,确保火箭弹在整个飞行过程中具有较高的控制精度;最后,进行了仿真计算,通过仿真结果分析可知,所设计的制导控制系统具有较高的鲁棒性.     

微小型直升机非线性鲁棒控制器设计

针对含有未建模动态的微小型直升机非线性模型,设计了基于反步法和自适应模糊系统的自主飞行控制器.该控制器包含两个回路:航迹控制外回路和姿态控制内回路.外回路通过旋转矩阵实现对内回路姿态的控制,而非传统的欧拉角或姿态四元数.控制器采用自适应Takagi-Sugeno(TS)模糊系统在线补偿系统未建模动态的影响,并利用反步法完成控制器综合.所设计的算法在确保整个控制系统稳定性的同时又可保证系统能够有效应对未建模动态的影响.系统仿真结果表明,在盘旋上升飞行模态下控制系统能够快速准确地跟踪预设轨迹,并且具有良好的鲁棒性能.     

自适应滑模容错跟踪飞行控制律的设计

当飞行控制系统操纵面发生卡死或控制效率损伤故障时,采用自适应滑模控制方法进行容错跟踪飞行控制律的设计。采用单位向量法进行滑模控制器的设计,利用李雅普诺夫理论和Barbalat引理设计自适应滑模调节规律,同时能够保证闭环系统的渐近稳定性。利用某型飞机线性化模型进行仿真,结果表明,带有自适应调节规律的滑模控制方法不仅适合于正常情况下飞行控制律的设计,而且对操纵面损伤和卡死故障情况具有较强的适应能力,具有很好的跟踪控制效果和强鲁棒性。     

战斗机超机动飞行自抗扰控制器设计

提出了一种利用自抗扰控制器算法在大包线范围内设计超机动飞行控制系统的新方法。根据奇异摄动理论和自抗扰控制器能够动态补偿系统模型扰动和外扰的特性,在超机动飞行的快慢子回路中分别引入自抗扰控制器,实现了快变量和慢变量的动态解耦控制。控制律设计直接依据超机动飞行的强耦合、强非线性模型,在很大的包线范围内不需要改变控制器的结构和参数,大大简化了设计过程。大包线范围内的大迎角机动仿真结果表明,系统具有良好的动态和稳态性能,控制器具有很强的鲁棒性,为解决大包线范围内的超机动飞行控制问题提供了一种新的途径。     

Non-fragile switching tracking control for a flexible air-breathing hypersonic vehicle based on polytopic LPV model

This article proposes a linear parameter varying (LPV) switching tracking control scheme for a flexible air-breathing hypersonic vehicle (FAHV). First, a polytopic LPV model is constructed to represent the complex nonlinear longitudinal model of the FAHV by using Jacobian linearization and tensor-product (T-P) model transformation approach. Second, for less conservative controller design purpose, the flight envelope is divided into four sub-regions and a non-fragile LPV controller is designed for each parameter sub-region. These non-fragile LPV controllers are then switched in order to guarantee the closed-loop FAHV system to be asymptotically stable and satisfy a specified performance criterion. The desired non-fragile LPV switching controller is found by solving a convex constraint problem which can be efficiently solved using available linear matrix inequality (LMI) techniques, and robust stability analysis of the closed-loop FAHV system is verified based on multiple Lypapunov functions (MLFs). Finally, numerical simulations have demonstrated the effectiveness of the proposed approach.     

Fuzzy adaptive tracking control within the full envelope for an unmanned aerial vehicle

Motivated by the autopilot of an unmanned aerial vehicle（UAV） with a wide flight envelope span experiencing large parametric variations in the presence of uncertainties, a fuzzy adaptive tracking controller（FATC） is proposed. The controller consists of a fuzzy baseline controller and an adaptive increment, and the main highlight is that the fuzzy baseline controller and adaptation laws are both based on the fuzzy multiple Lyapunov function approach, which helps to reduce the conservatism for the large envelope and guarantees satisfactory tracking performances with strong robustness simultaneously within the whole envelope. The constraint condition of the fuzzy baseline controller is provided in the form of linear matrix inequality（LMI）, and it specifies the satisfactory tracking performances in the absence of uncertainties. The adaptive increment ensures the uniformly ultimately bounded（UUB） predication errors to recover satisfactory responses in the presence of uncertainties. Simulation results show that the proposed controller helps to achieve high-accuracy tracking of airspeed and altitude desirable commands with strong robustness to uncertainties throughout the entire flight envelope.     

基于小波神经网络的自适应飞/推控制系统设计

基于小波神经网络提出了一种H∞自适应控制方法。控制器由等效控制器和H∞控制器两部分组成。用小波神经网络逼近非线性函数,并把逼近误差引入到权值的自适应律中用以改善系统的动态性能。H∞控制器用于减弱外部及神经网络的逼近误差对跟踪的影响。所设计的控制器不仅保证了闭环系统的稳定性,而且使外部干扰及神经网络的逼近误差对跟踪的影响减小到给定的性能指标。最后基于所设计的控制方法对新一代歼击机设计了飞/推控制系统,并对飞机作大迎角机动仿真。仿真结果表明所设计的飞/推控制系统是有效的,同时验证了所设计的非线性控制方法是有效性的。      

Dynamics modeling and control of a transport aircraft for ultra-low altitude airdrop

The nonlinear aircraft model with heavy cargo moving inside is derived by using the separation body method, which can describe the influence of the moving cargo on the aircraft attitude and altitude accurately. Furthermore, the nonlinear system is decoupled and linearized through the input–output feedback linearization method. On this basis, an iterative quasi-sliding mode(SM)flight controller for speed and pitch angle control is proposed. At the first-level SM, a global dynamic switching function is introduced thus eliminating the reaching phase of the sliding motion.At the second-level SM, a nonlinear function with the property of ‘‘smaller errors correspond to bigger gains and bigger errors correspond to saturated gains' ' is designed to form an integral sliding manifold, and the overcompensation of the integral term to big errors is weakened. Lyapunovbased analysis shows that the controller with strong robustness can reject both constant and time-varying model uncertainties. The performance of the proposed control strategy is verified in a maximum load airdrop mission.     

H_∞控制理论在飞行力学中的应用

 对 H_∞ 控制理论在飞行力学中的应用进行了研究。以典型战斗机的横航向飞行机动为例,介绍了将飞行控制系统设计问题转化为标准的 H_∞ 控制问题,继而进行 H_∞ 控制器设计,以提高其机动特性的鲁棒性。采用显模型跟踪技术,飞行品质的要求包含在反映状态变量侧滑角、稳定轴角速率对指令输入响应的理想模型中,通过使理想模型输出和实际对象输出之间的加权误差最小,同时保证控制面不饱和来达到控制的目的。计算结果表明,在飞机模型气动参数存在不确定性的情况下,增广系统达到了期望的性能指标,显示出良好的鲁棒性。