The Non-Singular Fast Terminal Sliding Mode Control of Interior Permanent Magnet Synchronous Motor Based on Deep Flux Weakening Switching Point Tracking

This paper presents a novel non-singular fast terminal sliding mode control(NFTSMC)based on the deep flux weakening switching point tracking method in order to improve the control performance of permanent interior magnet synchronous motor(IPMSM)drive systems.The mathematical model of flux weakening(FW)control is established,and the deep flux weakening switching point is calculated accurately by analyzing the relationship between the torque curve and voltage decline curve.Next,a second-order NFTSMC is designed for the speed loop controller to ensure that the system converges to the equilibrium state in finite time.Then,an extended sliding mode disturbance observer(ESMDO)is designed to estimate the uncertainty of the system.Finally,compared with both the PI control and sliding mode control(SMC)by simulations and experiments with different working conditions,the method proposed has the merits of accelerating convergence,improving steady-state accuracy,and minimizing the current and torque pulsation.

网联车辆队列有限时间终端滑模控制

本文研究在模型参数不确定及未知干扰的情况下的车队控制问题,该方法可保证车队系统在有限时间内稳定.针对前车-跟随(PF)、双向(BD)的信息拓扑结构,引入一种新的二次间距策略,保证车队系统的交通流稳定性.然后,提出两种基于非线性终端滑模控制和有限时间理论的分布式协同控制算法,分别保证了系统的队列稳定性和强队列稳定性,同时设计自适应律来处理系统中不确定参数和外源性扰动的影响,通过构造Lyapunov函数分析系统的有限时间稳定性与队列稳定性.最后通过数值仿真结果,证明了所提出的控制算法的有效性.结果表明,本文所提的方法能保证队列稳定性、交通流稳定性、并保证闭环系统中的所有信号都是有限时间稳定的.

Dual sliding mode coordinated control of manipulator grasping system with visual assistance

The operation efficiency of the manipulator is placed in the primary position in automatic production. This paper proposes a coordinated control strategy for joint servo and visual servo to enable timely transfer and accurate gripping in the working area. Aiming at the issues of chattering and slow convergence of traditional sliding mode controller, a fast variable power reaching rate on the basis of the non-singular fast terminal sliding mode controller is proposed, which can effectively reduce the convergence time and chattering. For the purpose of addressing the problem that the traditional visual servo control method is sensitive to the environment, a visual servo controller based on integral sliding mode is proposed, to ensure the favorable positioning accuracy of the manipulator. Based on the two proposed controllers mentioned above, a coordinated control strategy is used to implement the control of the manipulator. Finally, the upper computer software is developed using the C# programming language to monitor the workstation. The feasibility of the above-mentioned method is verified through multiple simulations and experiments.

侧窗探测动能拦截器末段轨控方案

针对侧窗探测动能拦截器(SWDKKV)的末段轨控问题,基于变结构控制理论提出了一种新的轨控方案。首先考虑侧窗约束,建立了三维空间下的轨控模型。随后,针对侧窗探测动能拦截器只能输出定常开关推力及具有姿态定向约束的特点,提出了一种新型变结构滑模面,基于所提出的滑模面设计了适合于末段拦截的bang-bang形式的轨控方案,采用Lyapunov稳定性理论严格证明了所提出方案的稳定性。为了降低喷气消耗,设计了滑模死区,且研究了能够保证命中精度的滑模死区的参数取值范围。仿真结果表明,所设计的轨控方案可确保动能拦截器直接撞击目标,设置滑模死区可以在保证命中精度的同时降低喷气消耗。

弹载电动舵机幂次滑模反演控制

针对高频响弹载电动舵机系统存在的齿隙非线性、参数时变、未知扰动等问题,提出一种幂次型快速Terminal滑模反演控制策略.设计连续可微函数逼近齿隙非线性环节的死区模型,建立拟合系统的状态空间模型并划分为3个子系统进行控制设计.采用反演控制思想设计快速幂次Terminal滑模控制器,内环采用直接转矩控制控制策略,提高响应速度.应用Lyapunov方法证明闭环系统跟踪误差的有限时间收敛特性,实现了对齿隙非线性的精确补偿.实验结果验证了所提出控制策略的有效性,与反演控制和PID控制策略相比,弹载电动舵机的控制精度、收敛速度及鲁棒性有显著提高.

基于S3C2440嵌入式系统主板的电磁兼容性设计

为解决嵌入式高速主板存在的电磁兼容性问题,以基于S3C2440的嵌入式系统主板为平台,结合EMIStream,Hyperlynx仿真软件,对整个主板设计进行板极电磁干扰控制,采用源端串联端接阻抗的方法有效地减小了共模辐射和差模辐射干扰对整个主板产生的电磁兼容性影响。结合仿真,采用源端端接阻抗的方法可消除潜在电磁干扰问题,减小了开发周期和开发成本。

基于扰动观测器和新型非奇异快速终端的PMSM滑模控制

针对永磁同步电机矢量控制系统中传统的PI控制存在超调量大,鲁棒性差等缺点,在速度环采用了一种新型非奇异快速终端控制算法的同时引入一种高增益扩张观测器实时观测系统的负载扰动并补偿。相比于传统的非奇异快速终端算法则不需要微分状态且可调参数更少。为进一步改善系统的动态响应性能,再在电流环引入一种无差拍电流预测控制。仿真结果表明,所提控制方法可有效改善系统鲁棒性差且滑模抖阵过大的问题。

电力需求侧管理对终端设备的影响

阐述了提高终端设备能效和建立能效标识制度的重要性,以及实现终端设备分时控制对优化用电方式的重要作用,指出我国节电产品生产厂家亟需采取相应对策以提高终端用电效率和优化用电方式。

永磁同步电机自适应非奇异终端滑模控制

针对永磁同步电机（Permanent Magnet Synchronous Motor，PMSM）运行在低速轻载条件时存在的转速脉动及电磁转矩脉动问题，提出了一种自适应变速非奇异终端滑模速度控制器。首先建立了包含参数不确定性及负载扰动的PMSM数学模型，同时为了解决传统指数趋近律存在的缺点，设计了一种自适应变速指数趋近律算法，该方法能够根据系统状态距离平衡点的远近而自适应调整等速趋近律速度。应用此方法设计PMSM滑模速度控制器，并与常规滑模控制器和PI控制器进行仿真比较，结果表明该算法不仅提高了系统的响应速度，减小了稳态误差，同时也有效地抑制了脉动现象。

两端电源供电交直流混合配电网直流侧故障特征和接地方式

交直流混合配电网是从交流配电网向直流配电网过渡的有效解决方案。为提升交直流混合配电网传输容量与供电可靠性,多端供电结构逐渐被广泛采用。从两端电源供电结构入手,研究当发生单极接地故障时的直流侧故障特征及接地方式。通过对故障回路的分析,研究了发生故障后电流的阶段性特性,推导故障电压与电流的时间表达式,并通过数学简化得到故障过电流峰值与达到峰值时刻的简单计算式。在此基础上,通过实例给出了选择接地电阻阻值的方法。研究分析了当两侧回路参数不对称时的故障电流振荡现象和规律,并提出基于等效拆分法的四阶微分方程回路计算方法进行故障电流计算。仿真结果表明,所提出的计算方法和接地方式适用于两端电源供电的交直流混合配电网的直流侧,有助于交直流混合配电网的安全、稳定、可靠运行。

两种接线金具型式下的特高压变压器高压侧套管接线柱受力分析

在特高压变压器高压侧套管引上线与避雷器T接线方式下,高压套管接线端子普遍采用"U"型与"一"字型两种接线方式,对高压套管引线接线端子进行受力分析与计算,得出"一"字型接线方式下,接线柱根部的应力值较小,有利于设备的安全稳定运行。

Active fault-tolerant control scheme of aerial manipulators with actuator faults

In this paper,an active fault-tolerant control(FTC)strategy of aerial manipulators based on non-singular terminal sliding mode(NTSM)and extended state observer(ESO)is proposed.Firstly,back-stepping technology is adopted as the control framework to ensure the global asymptotic stability of the closed-loop system.Next,the NTSM with estimated parameters of actuator faults is used as main robustness controller to deal with actuator faults.Then,the ESO is utilized to estimate and compensate the complex coupling effects and external disturbances.The Lyapunov stability theory can guarantee the asymptotic stability of aerial manipulators system with actuator faults and external disturbances.The proposed FTC scheme considers both actuator fault and modelling errors,combined with the adaptive law of actuator fault,which has better performance than traditional FTC scheme,such as NTSM.Finally,several comparative simulations are conducted to illustrate the effectiveness of the proposed FTC scheme.

基于自适应滑模的侧窗制导控制一体化设计研究

针对侧窗导弹末制导问题,提出了一种侧窗探测视场约束条件下的制导控制一体化设计方法。基于弹目相对运动模型分析了侧窗导弹运动规律,建立侧窗导引头探测视场角范围与导弹姿态角的约束关系,采用基于滑模控制理论的反步法设计导弹的制导控制一体化模型,给出了自适应滑模制导律:根据姿态角与侧窗视线角的约束关系,切换选择含约束和不含约束的自适应滑模控制。控制策略为:当弹目视线不满足侧窗探测范围约束时,在控制量中加入自适应俯仰角补偿项,使目标始终处于导弹侧窗视线范围内,解决了侧窗末制导过程中存在的目标跟踪视场角不对称约束问题;当弹目视线满足侧窗探测范围约束时,控制无需引入姿态角约束项,可直接应用自适应滑模控制律。仿真结果表明:在末制导过程中目标始终处在侧窗范围内,且对不同的初始条件有较好的鲁棒性。

A novel MPTC sensorless control strategy for ANFTSMC with ESO to control PMSM

Aiming at the problem that the traditional control strategy of permanent magnet synchronous motor(PMSM)for electric vehicles has low control performance,a novel adaptive non-singular fast terminal sliding mode control(ANFTSMC)model predictive torque control(MPTC)strategy is proposed.A new adaptive exponential approach rate is designed,and the traditional switching function sgn()is replaced by the hyperbolic tangent function tanh().A new ANFTSMC with extended state observer(ESO)is constructed as the speed regulator of the system,and ESO can observe disturbances.This improved method weakens chattering and improves the robustness of the system.To realize sensorless control of the speed control system,an ESO speed observer based on tanh(Fal)is constructed.Compared with the traditional ESO based on Fal function,the observation error is smaller,and the observation accuracy is higher.Finally,aiming at the model predictive torque control strategy used,a new objective function construction method is proposed,which avoids the design of weight coefficient,and the traditional voltage vector selection method is improved and optimized,which reduces the calculation amount of the algorithm.

基于干扰观测器的不确定非线性系统终端滑模控制器设计

考虑系统遭受复合干扰影响,针对一类不确定非线性系统的控制问题展开研究.首先,提出一种n阶超螺旋干扰观测器,对系统干扰进行估计;然后,结合系统的结构特点和滑模控制理论构造积分滑模面,并与二阶快速终端滑模控制理论相结合,设计基于干扰观测器的滑模控制器,通过引入反曲函数降低抖振,利用Lyapunov理论证明闭环系统的稳定性;最后,将该方法应用到磁悬浮系统的稳定性控制并进行仿真实验,结果表明了所提出方法的有效性.

Accelerated Landweber iteration based control allocation for fault tolerant control of reusable launch vehicle

This paper presents a novel Fault Tolerant Control(FTC)scheme based on accelerated Landweber iteration and redistribution mechanism for a horizontal takeoff horizontal landing reusable launch vehicle(RLV).First,an adaptive law based on fixed-time non-singular fast terminal sliding mode control(NFTSMC),which focuses on the attitude tracking controller design for RLV in the presence of model couplings,parameter uncertainties and external disturbances,is proposed to produce virtual control command.On this basis,a novel Control Allocation(CA)based on accelerated Landwber iteration is presented to realize proportional allocation of virtual control command among the actuators according to the effective gain as well as the distance from the current position of actuator to corresponding saturation limit.Meanwhile a novel redistribution mechanism is introduced to redistribute oversaturated command among healthy actuators(non-faulty or redundant).The proposed method can be applied to a real-time FTC system so that the controller reconfiguring is not required in case of actuator faults.Finally,the effectiveness of the proposed method is demonstrated by numerical simulations.

Distributed game strategy for unmanned aerial vehicle formation with external disturbances and obstacles

We investigate a distributed game strategy for unmanned aerial vehicle(UAV)formations with external disturbances and obstacles.The strategy is based on a distributed model predictive control(MPC)framework and Levy flight based pigeon inspired optimization(LFPIO).First,we propose a non-singular fast terminal sliding mode observer(NFTSMO)to estimate the influence of a disturbance,and prove that the observer converges in fixed time using a Lyapunov function.Second,we design an obstacle avoidance strategy based on topology reconstruction,by which the UAV can save energy and safely pass obstacles.Third,we establish a distributed MPC framework where each UAV exchanges messages only with its neighbors.Further,the cost function of each UAV is designed,by which the UAV formation problem is transformed into a game problem.Finally,we develop LFPIO and use it to solve the Nash equilibrium.Numerical simulations are conducted,and the efficiency of LFPIO based distributed MPC is verified through comparative simulations.