航机陆用动力装置控制系统的一种设计方法

本文以内部模型控制(IMC)算法为出发点,阐述了航机陆用动力装置的控制系统的设计方法。文中讨论了内部模型的原理及特点,滞后系统辨识的特殊性及解决方法,最后又把IMC控制器与经典反馈系统的控制器比较。并对内部模型系统进行了仿真计算,用IMC算法设计的系统可简便地通过盏线调整一个参数来实现ISE最小及较好的过渡过程性能指标。     

Application of neural networks for the design of flight control algorithms. II Adaptive tuning of neural network control law

In this paper, we consider different approaches for the neural network controller tuning in the flight control system. Two of the most common tuning approaches in the adaptive control theory are applied. The first one uses parameter identification technique and consists in solving a real-time regression problem for the control law. The second approach is based on the Lyapunov direct method, which utilizes a tracking error as an absolute measure of tuning performance. The neural network control law are designed for the three-axis flight control problem and tested on the full nonlinear model of a fighter aircraft. Closed loop simulation results are presented and two adaptation algorithms are compared in the case of abrupt change of aircraft dynamics.     

基于CFD降阶模型的阵风减缓主动控制研究

飞行器飞行时会受到大气紊流的影响,降低飞行品质。阵风减缓控制是改善飞行器飞行性能的关键技术。现有的阵风响应分析多以离散阵风为研究对象,对更加真实描述大气紊流的连续型阵风时域分析关注较少。采用成形滤波器方法将频域形式给出的大气紊流信号转换为时域信号。在跨声速区域内,利用系统辨识技术,基于计算流体力学(CFD)方法建立阵风激励下的气动载荷状态空间降阶模型(ROM)。为方便控制器设计,借助平衡模态法进行模型的进一步降阶。使用模型预测控制(MPC)算法通过控制操纵面偏转实现阵风减缓主动控制。以AGARD445.6标模作为仿真算例,验证基于ROM设计的阵风减缓控制律的有效性。仿真结果表明,在跨声速飞行状态下,模型预测控制器能够在满足操纵面偏转范围的约束下,对连续阵风激励下的翼根弯矩输出进行有效抑制。     

航空发动机虚拟自学习控制方法研究

随着人工智能技术的发展，智能航空发动机逐渐成为当今航空领域研究的热点。传统的航空发动机控制对发动机模型的依赖性过强，而基于发动机气热动力学公式的机理建模会引入较大的建模误差，给控制器设计带来困难。对此，提出一种基于强化学习的航空发动机控制虚拟自学习方法，首先利用航空发动机的试验数据通过LSTM 神经网络建立虚拟学习环境，然后采用深度强化学习TD3 算法，在虚拟环境中训练智能控制器，最后采用JT9D 发动机模型验证智能控制器的性能。结果表明：相比于传统PID 控制，智能控制器产生的超调量更小，调节时间更短。     

Gain self-scheduled H_∞ control for morphing aircraft in the wing transition process based on an LPV model

This article investigates gain self-scheduled H 1 robust control system design for a tailless fold- ing-wing morphing aircraft in the wing shape varying process. During the wing morphing phase, the aircraft’s dynamic response will be governed by time-varying aerodynamic forces and moments. Nonlinear dynamic equations of the morphing aircraft are linearized by using Jacobian linearization approach, and a linear parameter varying (LPV) model of the morphing aircraft in wing folding is obtained. A multi-loop controller for the morphing aircraft is formulated to guarantee stability for the wing shape transition process. The proposed controller uses a set of inner-loop gains to provide stability using classical techniques, whereas a gain self-scheduled H 1 outer-loop controller is devised to guarantee a specific level of robust stability and performance for the time-varying dynamics. The closed-loop simulations show that speed and altitude vary slightly during the whole wing folding process, and they converge rapidly after the process ends. This proves that the gain self-scheduled H 1 robust controller can guarantee a satisfactory dynamic performance for the morphing aircraft during the whole wing shape transition process. Finally, the flight control system’s robustness for the wing folding process is verified according to uncertainties of the aerodynamic parameters in the nonlinear model.     

神经网络及模糊控制在飞机防滑刹车系统中的应用

提出了一种新的神经网络 -模糊逻辑刹车系统控制方案。利用神经网络解决刹车系统中存在的非线性识别问题,实现刹车过程的轨迹跟踪;利用模糊控制克服参数变化和环境因素造成的不利影响,同时避免不精确建模造成的误差,最后利用所设计的控制器对某型飞机进行了仿真研究。结果表明 :新的控制方案能极大的改善飞机的刹车性能。     

Simple adaptive control for aircraft control surface failures

This work extends the so-called simple adaptive control approach to direct model reference adaptive control of multi-input multi-output systems to include loss of control effectiveness failures. It is proven that all signals are bounded for loss of control effectiveness failures during a bounded input disturbance. A state space approach is introduced for computing the feedforward compensator that is required by the stability result. The adaptive algorithm is applied to a three input model of the linearized lateral dynamics of the F/A-18 aircraft. Simulation results are obtained with single, double, and triple control effectiveness failures of 88% during the occurrence of a lateral gust. These results show that the adaptive controller exhibits improved model following as compared with a fixed gain eigenstructure assignment controller.     

航空发动机多变量模糊PID控制

普通PID控制器以其简单、实用、易于实现,在经典控制中倍受青睐。但是,对于像航空发动机这样复杂的非线性系统,这种控制器的控制效果就不够理想了。模糊控制理论的建立为这种问题的解决奠定了基础。本文针对航空发动机难于建立精确数学模型的特点,提出了发动机模糊PID参数自适应控制方案,并且对某型航空发动机进行了全包线内的数字仿真。仿真结果表明发动机模糊PID控制不仅不依赖于精确的对象模型,而且具有满意的动、静态性能。      

基于多模型的飞控系统自适应重构技术研究

针对飞控系统执行器故障引起参数大范围跳变的问题,提出了一种基于多模型的自适应重构控制方法。建立了执行器故障参数模型,根据故障的特征模型设计一系列并行的辨识模型,采用固定模型与自适应模型相结合的方式,依据转换标准选择与当前飞机状态最匹配的辨识模型所对应的控制器。通过对某型飞机侧向控制系统进行仿真,表明在执行器严重受损的情况下,飞机仍能保持良好的性能。     

Active fault-tolerant control strategy of large civil aircraft under elevator failures

Aircraft longitudinal control is the most important actuation system and its failures would lead to catastrophic accident of aircraft. This paper proposes an active fault-tolerant control(AFTC) strategy for civil aircraft with different numbers of faulty elevators. In order to improve the fault-tolerant flight control system performance and effective utilization of the control surface, trimmable horizontal stabilizer(THS) is considered to generate the extra pitch moment. A suitable switching mechanism with performance improvement coefficient is proposed to determine when it is worthwhile to utilize THS. Furthermore, AFTC strategy is detailed by using model following technique and the proposed THS switching mechanism. The basic fault-tolerant controller is designed to guarantee longitudinal control system stability and acceptable performance degradation under partial elevators failure. The proposed AFTC is applied to Boeing 747-200 numerical model and simulation results validate the effectiveness of the proposed AFTC approach.     

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。     

模型跟踪和涡流控制在飞翼布局飞机上的应用

为增加小展弦比飞翼类布局飞机的操纵特性,并满足其对隐身性能的要求,将模型跟踪控制器和涡流控制器进行综合使用.模型跟踪是一种提高系统闭环响应并跟踪驾驶员指令的方法,通过此方法可使动态特性较差的飞机对动态特性较好的飞机输出进行跟踪,由此来改善飞机的动态特性.增加涡流控制可以进一步扩展模型跟踪控制的作用效果,涡流控制器使用变步长神经网络进行训练.结果表明,两种方法的综合使用可以有效地提高飞机的动态特性,通过增加涡流控制后,进一步增加了模型跟踪控制的作用效果.     

基于Kalman滤波的变体飞行器T-S模糊控制

针对变体飞行器的跟踪控制问题,提出了一种基于Kalman滤波的T-S模糊控制方法。考虑飞行器系统状态不可测,引入惯导数据作为辅助信息,利用Kalman滤波算法融合飞控信息与惯导信息实现状态估计。由于变体飞行器在不同变形结构下气动特性变化较大,为便于控制器设计,采用小扰动线性化方法得到飞行器在不同平衡点处的局部线性模型,并通过状态反馈方法设计局部控制器,局部线性模型和局部控制器通过模糊集和模糊规则聚合成一个连续光滑的全局T-S模糊模型和T-S模糊控制器。通过综合Kalman滤波器与T-S模糊控制器得到一个基于Kalman滤波的T-S模糊控制器。仿真结果表明,该控制器在变形过程中能够实现状态估计,保证飞机的跟踪性能。     

基于无味卡尔曼滤波的飞机防滑刹车模糊神经网络控制

根据对飞机刹车过程动力学分析与建模,本文提出了一种基于无味卡尔曼滤波(UKF)的模糊神经网络控制律。本控制律结合了无味卡尔曼滤波对机体速度的良好估计效果和模糊神经网络控制器对不同系统参数的适应能力,能够很好完成对最佳滑移率的追踪任务。Matlab仿真试验结果显示,基于无味卡尔曼滤波的模糊神经网络控制器可以准确的估计飞机滑跑时的速度,改善飞机防滑刹车系统性能,提高刹车效率。     

自适应模糊-滑模控制在重构飞行控制中的应用

 论述了综合运用非线性动态逆、自适应模糊系统和滑模控制的优点进行飞行控制律设计的方法。运用非线性动态逆理论对非线性系统进行近似线性化 ,用模糊自适应系统来抵消近似非线性逆带来的误差 ,最终的残差由滑模控制项补偿。根据李亚普诺夫稳定性理论推导了自适应系统权值的调整规律 ,从而保证了闭环系统的稳定性。将此方法应用于带推力矢量飞机重构飞行控制 ,对两类故障的仿真结果表明 :即使系统未检测到故障 ,在较大的舵面损伤情况下 ,飞控系统性能仍能得到很好的保持。     

考虑扰流的舰载机终端进场线性模型

回收舰载机需要精确的终端路径和姿态控制,舰载机线性小扰动模型是这一阶段系统分析和控制器设计的必要工具,它需要足够准确地描述在主要操纵输入和进场路径大气紊流作用下舰载机的动态特性。首先使用代数线性化方法建立舰载机终端进场纵向运动的小扰动模型,仿真证明该模型能精确描述无风条件下进场舰载机对控制指令的响应,但通常的建模气流扰动影响的方法不能正确反映舰尾大气紊流对舰载机进场速度的干扰。针对该问题,重点研究了垂向风引起的进场舰载机轨迹方向上的力瞬变,提出了量化舰载机地速扰动的表达式以优化线性模型参数。最后,通过完成舰载机动力学模型在不同风场下的开环仿真以及在舰尾流场中的终端进场闭环仿真,验证了改进的线性模型的有效性,表明它适用于复杂流场下着舰控制系统的性能分析和设计。     

模糊自适应过失速飞行控制

研究了带推力矢量飞机过失速非线性飞机控制问题。根据奇异摄动理论将受控变量分为快变量和慢变量，然后分别对内环和外环进行设计，外环利用滑动面控制进行设计，内环利用模糊逻辑系统的万能特性来抵消近似非线性动态逆所带来的误差，根据李亚谱诺夫稳定性理论了模糊系统权值的自适应调整规律，从而保证闭环系统的稳定性。数字仿真结果表明：在存在较大的模型不确定性以及飞机动力学对状态和控制输入均为非线性的情况下，该控制方案能对指令进行良好的跟踪。     

Robust adaptive fault-tolerant control of a tandem coaxial ducted fan aircraft with actuator saturation

This paper is concerned with the robust adaptive fault-tolerant control of a tandem coaxial ducted fan aircraft under system uncertainty, mismatched disturbance, and actuator saturation. For the proposed aircraft, comprehensive controllability analysis is performed to evaluate the controllability of each state as well as the margin to reject mismatched disturbance without any knowledge of the controller. Mismatched disturbance attenuation is ensured through a structured H-infinity controller tuned by a non-smooth optimization algorithm. Embedded with the H-infinity controller, an adaptive control law is proposed in order to mitigate matched system uncertainty and actuator fault. Input saturation is also considered by the modified reference model. Numerical simulation of the novel ducted fan aircraft is provided to illustrate the effectiveness of the proposed method. The simulation results reveal that the proposed adaptive controller achieves better transient response and more robust performance than classic Model Reference Adaptive Control (MRAC) method, even with serious actuator saturation.     

Damage-mitigating control of aircraft for enhanced structuraldurability

The concept and a design methodology for robust damage-mitigating control (DMC) of aircraft is presented. The goal of DMC is to simultaneously achieve high performance and structural durability and the design procedure is based on damage mitigation at critical structures and retention of the flight performance. An aeroelastic model of the wings has been formulated and is incorporated into a nonlinear rigid-body model of aircraft flight-dynamics. Robust damage-mitigating controllers are then designed using the H_∞-based structured singular value (μ) synthesis method based on a linearized model of the aircraft. In addition to penalizing the error between the ideal performance and the actual performance of the aircraft, frequency-dependent weights are placed on the strain amplitude at the root of each wing, Using each controller in turn, the control system is put through an identical sequence of maneuvers, and the resulting (varying amplitude cyclic) stress profiles are analyzed using a fatigue crack growth model that incorporates the effects of varying-amplitude cyclic loading. Comparisons are made to determine the impact of different strain-amplitude weights on the resulting flight performance and fatigue crack damage in the wings. The results of simulation experiments show significant savings in fatigue life of the wings while retaining the dynamic performance of the aircraft     

考虑预设性能约束的运输机姿态容错控制

针对运输机舵面故障情况下的姿态容错控制问题,提出了一种考虑预设性能约束的自适应指令滤波增量反步(Adaptive Command-filtered Incremental Backstepping,ACFIBS)容错控制器。首先,构造运输机故障模型,在反步控制设计结构下,通过构造预设性能函数,保证外回路姿态角跟踪误差的动态性能。然后,考虑舵机偏转速率和幅值限制,引入受限指令滤波器和补偿信号,综合考虑气动参数不确定性,采用增量方法设计反步内环控制律。在此基础上,进一步考虑舵面故障情况,引入自适应方法及低通滤波器改进增量反步控制器。最后,通过理论推导和仿真试验验证了控制方法的有效性。仿真结果表明,所设计的控制器具有良好的容错性能,在不同舵面故障条件下均可实现对指令信号的预设性能跟踪,且在参数摄动情况下具有较强的鲁棒性。