Robust adaptive leaderless consensus of unknown non-minimum phase linear multi-agent systems subject to disturbances and/or unmodeled dynamics

This article investigates the problem of robust adaptive leaderless consensus for heterogeneous uncertain nonminimumphase linear multi-agent systems over directed communication graphs. Each agent is assumed tobe of unknown nominal dynamics and also subject to external disturbances and/or unmodeled dynamics. Anovel distributed robust adaptive control strategy is proposed. It is shown that the robust adaptive leaderlessconsensus problem is solved with the proposed control strategy under some sufficient conditions. Two examplesare provided to demonstrate the efficacy of the proposed control strategy.

Distributed Adaptive Output Consensus of Unknown Heterogeneous Non-Minimum Phase Multi-Agent Systems

This article addresses the leader-following output consensus problem of heterogeneous linear multi-agent systems with unknown agent parameters under directed graphs.The dynamics of followers are allowed to be non-minimum phase with unknown arbitrary individual relative degrees.This is contrary to many existing works on distributed adaptive control schemes where agent dynamics are required to be minimum phase and often of the same relative degree.A distributed adaptive pole placement control scheme is developed,which consists of a distributed observer and an adaptive pole placement control law.It is shown that under the proposed distributed adaptive control scheme,all signals in the closed-loop system are bounded and the outputs of all the followers track the output of the leader asymptotically.The effectiveness of the proposed scheme is demonstrated by one practical example and one numerical example.

Output-feedback Dynamic Surface Control for a Class of Nonlinear Non-minimum Phase Systems

In this paper, an output-feedback tracking controller is proposed for a class of nonlinear non-minimum phase systems.To keep the unstable internal dynamics bounded, the method of output redefinition is applied to let the stability of the internal dynamics depend on that of redefined output, thus we only need to consider the new external dynamics rather than internal dynamics in the process of designing control law. To overcome the explosion of complexity problem in traditional backstepping design, the dynamic surface control(DSC) method is firstly used to deal with the problem of tracking control for the nonlinear non-minimum phase systems. The proposed outputfeedback DSC controller not only forces the system output to asymptotically track the desired trajectory, but also drives the unstable internal dynamics to follow its corresponding bounded and causal ideal internal dynamics, which is solved via stable system center method. Simulation results illustrate the validity of the proposed output-feedback DSC controller.

AN IMPROVEMENT OF THE RECURSIVE CLOSED-FORM ALGORITHM FOR NON-MINIMUM PHASE FIR SYSTEM IDENTIFICATION

An improved algorithm which is based on the recursive closed-form algorithm fornon-minimum phase FIR system identification via higher order statistics is presented.In order toincrease the parametric estimation accuracy,the improved algorithm uses the optimal iterativemethod to seek the nonlinear least-square solution.Finally,the simulation examples are alsogiven.

Optimized Model Based Controller with Model Plant Mismatch for NMP Mitigation in Boost Converter

In this paper,an optimized Genetic Algorithm(GA)based internal model controller-proportional integral derivative(IMC-PID)controller has been designed for the control variable to output variable transfer function of dc-dc boost converter to mitigate the effect of non-minimum phase(NMP)behavior due to the presence of a right-half plane zero(RHPZ).This RHPZ limits the dynamic performance of the converter and leads to internal instability.The IMC PID is a streamlined counterpart of the standard feedback controller and easily achieves optimal set point and load change performance with a single filter tuning parameterλ.Also,this paper addresses the influences of the model-based controller with model plant mismatch on the closed-loop control.The conventional IMC PID design is realized as an optimization problem with a resilient controller being determined through a genetic algorithm.Computed results suggested that GA–IMC PID coheres to the optimum designs with a fast convergence rate and outperforms conventional IMC PID controllers.

Adaptive fault-tolerant control for non-minimum phase hypersonic vehicles based on adaptive dynamic programming

In this paper,a novel adaptive Fault-Tolerant Control(FTC)strategy is proposed for non-minimum phase Hypersonic Vehicles(HSVs)that are affected by actuator faults and parameter uncertainties.The strategy is based on the output redefinition method and Adaptive Dynamic Programming(ADP).The intelligent FTC scheme consists of two main parts:a basic fault-tolerant and stable controller and an ADP-based supplementary controller.In the basic FTC part,an output redefinition approach is designed to make zero-dynamics stable with respect to the new output.Then,Ideal Internal Dynamic(IID)is obtained using an optimal bounded inversion approach,and a tracking controller is designed for the new output to realize output tracking of the nonminimum phase HSV system.For the ADP-based compensation control part,an ActionDependent Heuristic Dynamic Programming(ADHDP)adopting an actor-critic learning structure is utilized to further optimize the tracking performance of the HSV control system.Finally,simulation results are provided to verify the effectiveness and efficiency of the proposed FTC algorithm.

氯化锂、氯化钠在NMP中溶解度的测定与关联

为了回收聚苯硫醚生产中的助剂氯化锂,对氯化锂、氯化钠在溶剂NMP（N-甲基吡咯烷酮）中的溶解性能进行了研究。利用激光衍射辅助法在297.95～364.75 K温度范围内对氯化锂、氯化钠在NMP中的溶解度进行了测定,并用经验方程、λh方程、改进的NRTL方程对氯化锂在NMP中的溶解度数据进行关联。结果证明,改进的NRTL方程的拟合结果最好,平均相对偏差仅为0.41%,可适用于较高温度下氯化锂-NMP体系溶解度的数据估计。

P84共聚聚酰亚胺/NMP/乙二醇体系三元相图的计算

分别通过基团贡献(UNIFAC)法和Hansen溶度参数公式计算了乙二醇-N-甲基吡咯烷酮(NMP)、乙二醇-P84共聚聚酰亚胺和NMP-P84共聚聚酰亚胺的相互作用参数g12,χ13和χ23.基于二元相互作用参数和Flory-Huggins高分子溶液理论,计算出P84共聚聚酰亚胺/NMP/乙二醇体系的理论三元相图.与浊点试验三元相图比较发现:χ13=1.27,χ23=0.37时,模拟的理论三元相图与试验相图较吻合.

水平管外TFE/NMP部分膜状冷凝热、质耦合传递过程研究

通过对水平管外双组分 ( TFE/NMP为三氟乙醇 /氮甲基吡咯烷酮 )部分膜状冷凝过程特点的分析 ,建立起部分膜状冷凝过程中热质传递过程的物理模型。以双膜理论为基础 ,利用部分膜状冷凝的特点 ,通过对界面传质、液膜内质量平衡、界面相平衡、界面能量平衡和汽膜截面能量平衡的分析计算 ,得到汽相温度和界面温度分布、汽相及液相 NMP质量分数分布 ,由此进一步计算出冷凝膜厚分布、液膜传热系数分布和热流密度的分布。计算的热流密度与相关实验作了比较 ,发现与实验能较好的吻合。

液固相变吸收剂的CO_(2)吸收性能及相分离行为机理研究

以N-甲基二乙醇胺(MDEA)+哌嗪(PZ)水溶液作为复合吸收剂的化学吸收法是捕集二氧化碳(CO_(2))的重要手段之一,但该复合吸收剂再生能耗较高,限制了其在碳捕集领域的应用。为克服该缺点,在该复合吸收剂中加入某种溶剂形成相变吸收剂,可减少吸收剂进入解吸单元的总量,从而降低再生能耗。设计了一种组成为MDEA+PZ+N-甲基吡咯烷酮(NMP)+水(H_(2)O)的液固相变吸收剂,并考察了其吸收CO_(2)的性能,测定了NMP、PZ质量分数对液固相变吸收剂CO_(2)溶解度的影响,分析了相分离行为机理。结果表明,该吸收剂的CO_(2)溶解度随着NMP质量分数的增加而降低,随着PZ质量分数的增加而增加;当吸收剂中NMP、PZ的质量分数分别达到50%、3%及以上时,吸收CO_(2)后生成PZ-氨基甲酸酯达到饱和析出形成固相,固相先随CO_(2)溶解度增加而增加,后随着CO_(2)溶解度继续增加,生成更易溶于水的PZ-二氨基甲酸酯,导致固相减少。

溶剂对FOX-7晶体相变和热性能的影响

采用重结晶法在二甲基甲酰胺（DMF）/H2O、二甲基亚砜（DMS）O/H2O和N-甲基吡咯烷酮（NMP）/H2O等不同溶剂体系中得到FOX-7晶体,用扫描电子显微镜（SEM）测试晶体的形貌、变温X-射线粉末衍射（XRD）分析晶型和相变、差示扫描量热仪（DSC）测试其热性能。结果表明,不同溶剂重结晶得到的FOX-7晶体形貌有较大差别,在DMSO/H2O溶剂中得到的晶体质量要优于其他两种;3种溶剂中得到FOX-7晶体的晶型和相变过程相同,即常温下FOX-7的晶型为α晶型,在120℃时,FOX-7完成α→β相变,至185℃时,完成β→γ相变;重结晶的FOX-7晶体5s爆发点温度提高了4~9℃,说明热稳定性增强。

一种自适应逆控制管道有源消声系统及其实现

在前馈有源噪声控制中 ,由于次级通道传递函数往往是非最小相位系统 ,直接使用传统的FXLMS算法时 ,导致系统的性能下降。提出一种基于NMP逆控制的自适应前馈有源噪声控制FXLMS算法 ,在电机、风机、通风管道系统上进行实时ANC实验 ,结果表明较传统的前馈FXLMS算法ANC系统消声性能有明显的改进。

基于非最小相位系统自适应逆控制的有源消声研究

前馈有源噪声控制(active noise control,ANC)方法可在较宽的频带有效。在前馈有源噪声控制中,直接使用传统的FXLMS算法时,由于次级通道传递函数往往是非最小相位系统(non-minimum phase,NMP),导致系统的性能下降。本文提出一种基于NMP逆控制的自适应前馈有源噪声控制FXLMS算法,用带宽随机噪声信号作为噪声源进行仿真实验研究,在一通风管道上进行了实时ANC实验,结果表明较传统的FXLMS算法有明显的改进。

非最小相位系统自适应模型逆技术研究

针对非最小相位系统中的轨迹跟踪控制问题,基于非最小相位系统的闭环注入体系结构,对非最小相位系统的前馈控制器设计方法、模型逆技术以及自适应控制进行了研究。首先,采用非最小相位零点忽略技术、零相位误差跟踪控制技术和零幅度误差跟踪控制技术设计了系统的前馈控制器,并对3种模型逆技术进行了分析;在此基础上针对系统中非最小相位零点的偏移问题,采用遗忘因子最小二乘法实现了前馈控制器的自适应;最后进行了仿真和试验。研究结果表明:相对于使用零相位误差跟踪控制技术和非最小相位零点忽略技术,采用零幅度误差跟踪控制技术设计的前馈控制器能够更有效地提高非最小相位系统的跟踪精度,系统的轨迹跟踪误差分别减少了61.45%和56.27%;使用自适应算法能够实现对系统参数变化的自适应控制,提高了系统的抗干扰性能。

Analysis and improvement of missile three-loop autopilots

The non-minimum phase feature of tail-controlled missile airframes is analyzed. Three selection strategies for desired performance indexes are presented. An acceleration autopilot design methodology based on output feedback and optimization is proposed. Performance and robustness comparisons between the two-loop and classical three-loop topologies are made. Attempts to improve the classical three-loop topology are discussed. Despite the same open-loop structure, the classical three-loop autopilot shows distinct characteristics from a two-loop autopilot with PI compensator. Both the two-loop and three-loop topologies can stabilize a static unstable missile. However, the finite actuator resource is the crucial factor dominating autopilot function.

On ADRC for non-minimum phase systems： canonical form selection and stability conditions

Active disturbance rejection control （ADRC）, as proposed by Prof. Jingqing Han, reduces first the plant dynamics to its canonical form, normally in the form of cascade integrators, for which the standard controller can be employed to meet the design specifications. This paper concerns with the selection of the canonical form for non-minimum phase systems. In particular, it is shown that, by employing the well known controllable canonical form, the uncertainties of such systems can be divided into two terms in the state space model, one in the control channel and the other in the output channel. The necessary and sufficient condition is obtained for the stability of the closed-loop system with the proposed canonical form and ADRC. Also, by showing the necessity of the detectability of the extended system as well as certain information of the system-s ＂zeros＂, we present the fundamental guidelines of design ADRC for non-minimum phase uncertain systems.

Recent developments on applications of sequential loop closing and diagonal dominance control schemes to industrial multivariable system

With a focus on an industrial multivariable system, two subsystems including the flow and the level outputs are analysed and controlled, which have applicability in both real and academic environments. In such a case, at first, each subsystem is distinctively represented by its model, since the outcomes point out that the chosen models have the same behavior as corresponding ones. Then, the industrial multivariable system and its presentation are achieved in line with the integration of these subsystems, since the interaction between them can not actually be ignored. To analyze the interaction presented, the Gershgorin bands need to be acquired, where the results are used to modify the system parameters to appropriate values. Subsequently, in the view of modeling results, the control concept in two different techniques including sequential loop closing control(SLCC) scheme and diagonal dominance control(DDC) schemes is proposed to implement on the system through the Profibus network, as long as the OPC(OLE for process control) server is utilized to communicate between the control schemes presented and the multivariable system. The real test scenarios are carried out and the corresponding outcomes in their present forms are acquired. In the same way, the proposed control schemes results are compared with each other, where the real consequences verify the validity of them in the field of the presented industrial multivariable system control.

Neural Network Based Feedback Linearization Control of an Unmanned Aerial Vehicle

This paper presents a flight control design for an unmanned aerial vehicle （UAV） using a nonlinear autoregressive moving average （NARMA-L2） neural network based feedback linearization and output redefinition technique. The UAV investigated is non- minimum phase. The output redefinition technique is used in such a way that the resulting system to be inverted is a minimum phase system. The NARMA-L2 neural network is trained off-line for forward dynamics of the UAV model with redefined output and is then inverted to force the real output to approximately track a command input. Simulation results show that the proposed approaches have good performance.

Robust Stabilization of Non-minimum Phase Switched Nonlinear Systems with Uncertainty

This paper investigates the problem of robust stabilization of a class of switched nonlinear system with uncertain dynamics where each subsystem represents a non-minimum phase.The authors first construct a stabilizing sliding mode controller for each subsystem to stabilize individually its own unstable internal dynamics.Then,a switching strategy is introduced to select the most appropriate diffeomorphism through an infinity of diffeomorphisms.Sufficient conditions are specifically given for the exponential stability and the exponential upper bound of the trajectory of the switched subsystem,which guarantees the global asymptotical stability of the resulting switched system.Obviously,the proposed control approach can improvemore the transient state,compared to a feedback linearization based on only one diffeomorphism.Simulation studies illustrate the effectiveness of the suggested approach.

ROBUST SMITH PREDICTIVE CONTROLLER FOR PROCESS WITH INVERSE RESPONSE

Smith predictor known as the time delay compensator was extended to control the process with inverse response.Modern robust control theory was employed to design the robust controller,which has only one parameter to be determined with compromise among the rise time,undershoot,robustness and capability to reject disturbance of the closed loop system.The former two specifications can be assessed quantitatively and the latter two qualitatively.Examples show that the proposed method has significant improvements and wide applicable ranges for inverse response process.