The distributed AC microgrid(MG) voltage restoration problem has been extensively studied. Still, many existing secondary voltage control strategies neglect the co-regulation of the voltage at the point of common coup...The distributed AC microgrid(MG) voltage restoration problem has been extensively studied. Still, many existing secondary voltage control strategies neglect the co-regulation of the voltage at the point of common coupling(PCC) in the AC multi-MG system(MMS). When an MMS consists of sub-MGs connected in series, power flow between the sub-MGs is not possible if the PCC voltage regulation relies on traditional consensus control objectives. In addition, communication faults and sensor faults are inevitable in the MMS. Therefore, a resilient voltage regulation strategy based on containment control is proposed.First, the feedback linearization technique allows us to deal with the nonlinear distributed generation(DG) dynamics, where the PCC regulation problem of an AC MG is transformed into an output feedback tracking problem for a linear multi-agent system(MAS) containing nonlinear dynamics. This process is an indispensable pre-processing in control algorithm design. Moreover, considering the unavailability of full-state measurements and the potential faults present in the sensors, a novel follower observer is designed to handle communication faults. Based on this, a controller based on containment control is designed to achieve voltage regulation. In regulating multiple PCC voltages to a reasonable upper and lower limit, a voltage difference exists between sub-MGs to achieve power flow. In addition, the secondary control algorithm avoids using global information of directed communication network and fault boundaries for communication link and sensor faults. Finally, the simulation results verify the performance of the proposed strategy.展开更多
Dependability analysis is an important step in designing and analyzing safety computer systems and protection systems.Introducing multi-processor and virtual machine increases the system faults' complexity,diversi...Dependability analysis is an important step in designing and analyzing safety computer systems and protection systems.Introducing multi-processor and virtual machine increases the system faults' complexity,diversity and dynamic,in particular for software-induced failures,with an impact on the overall dependability.Moreover,it is very different for safety system to operate successfully at any active phase,since there is a huge difference in failure rate between hardware-induced and softwareinduced failures.To handle these difficulties and achieve accurate dependability evaluation,consistently reflecting the construct it measures,a new formalism derived from dynamic fault graphs(DFG) is developed in this paper.DFG exploits the concept of system event as fault state sequences to represent dynamic behaviors,which allows us to execute probabilistic measures at each timestamp when change occurs.The approach automatically combines the reliability analysis with the system dynamics.In this paper,we describe how to use the proposed methodology drives to the overall system dependability analysis through the phases of modeling,structural discovery and probability analysis,which is also discussed using an example of a virtual computing system.展开更多
三电平Buck-Boost变流器具有双向馈能和能量传输高效的特点。针对直流电容器容值衰退和IGBT开路故障两种典型失效模式,提出了一种利用变流器自身传感器同时对直流电容容值衰退和IGBT开路故障非侵入式在线监测的方法。首先,分析了三电平B...三电平Buck-Boost变流器具有双向馈能和能量传输高效的特点。针对直流电容器容值衰退和IGBT开路故障两种典型失效模式,提出了一种利用变流器自身传感器同时对直流电容容值衰退和IGBT开路故障非侵入式在线监测的方法。首先,分析了三电平Buck-Boost变流器开关运行模态及其切换顺序。然后,采用特定开关模态消除直流电容等效串联电阻(equivalent series resistance,ESR)影响,分别推导了子模块电容的容值特征解析表达式。最后,利用每个开关周期计算出的等效容值特征检测和定位IGBT开路故障。仿真和实验结果表明:利用开关模态容值特征能够同时监测三电平Buck-Boost变流器直流电容状态和IGBT开路故障,平均容值监测误差小于1%且可以消除ESR的影响,利用容值特征畸变能够在2~3个开关周期内检测出IGBT开路故障。展开更多
基金supported in part by the National Key R&D Program of China(2018YFA0702200)the National Natural Science Foundation of China(62073065,U20A20190)。
文摘The distributed AC microgrid(MG) voltage restoration problem has been extensively studied. Still, many existing secondary voltage control strategies neglect the co-regulation of the voltage at the point of common coupling(PCC) in the AC multi-MG system(MMS). When an MMS consists of sub-MGs connected in series, power flow between the sub-MGs is not possible if the PCC voltage regulation relies on traditional consensus control objectives. In addition, communication faults and sensor faults are inevitable in the MMS. Therefore, a resilient voltage regulation strategy based on containment control is proposed.First, the feedback linearization technique allows us to deal with the nonlinear distributed generation(DG) dynamics, where the PCC regulation problem of an AC MG is transformed into an output feedback tracking problem for a linear multi-agent system(MAS) containing nonlinear dynamics. This process is an indispensable pre-processing in control algorithm design. Moreover, considering the unavailability of full-state measurements and the potential faults present in the sensors, a novel follower observer is designed to handle communication faults. Based on this, a controller based on containment control is designed to achieve voltage regulation. In regulating multiple PCC voltages to a reasonable upper and lower limit, a voltage difference exists between sub-MGs to achieve power flow. In addition, the secondary control algorithm avoids using global information of directed communication network and fault boundaries for communication link and sensor faults. Finally, the simulation results verify the performance of the proposed strategy.
基金This work was supported in part by National Natural Science Foundation of China under grant No.61272411 and National 973 Basic Research Program of China under grant No.2014CB340600
文摘Dependability analysis is an important step in designing and analyzing safety computer systems and protection systems.Introducing multi-processor and virtual machine increases the system faults' complexity,diversity and dynamic,in particular for software-induced failures,with an impact on the overall dependability.Moreover,it is very different for safety system to operate successfully at any active phase,since there is a huge difference in failure rate between hardware-induced and softwareinduced failures.To handle these difficulties and achieve accurate dependability evaluation,consistently reflecting the construct it measures,a new formalism derived from dynamic fault graphs(DFG) is developed in this paper.DFG exploits the concept of system event as fault state sequences to represent dynamic behaviors,which allows us to execute probabilistic measures at each timestamp when change occurs.The approach automatically combines the reliability analysis with the system dynamics.In this paper,we describe how to use the proposed methodology drives to the overall system dependability analysis through the phases of modeling,structural discovery and probability analysis,which is also discussed using an example of a virtual computing system.
基金supported by Youth Project of National Natural Science Foundation of China“The discrete isoperimetric problem of graphs and the study of weierstrass type functions with extremely related conditional connectivity”(12101528)。
文摘三电平Buck-Boost变流器具有双向馈能和能量传输高效的特点。针对直流电容器容值衰退和IGBT开路故障两种典型失效模式,提出了一种利用变流器自身传感器同时对直流电容容值衰退和IGBT开路故障非侵入式在线监测的方法。首先,分析了三电平Buck-Boost变流器开关运行模态及其切换顺序。然后,采用特定开关模态消除直流电容等效串联电阻(equivalent series resistance,ESR)影响,分别推导了子模块电容的容值特征解析表达式。最后,利用每个开关周期计算出的等效容值特征检测和定位IGBT开路故障。仿真和实验结果表明:利用开关模态容值特征能够同时监测三电平Buck-Boost变流器直流电容状态和IGBT开路故障,平均容值监测误差小于1%且可以消除ESR的影响,利用容值特征畸变能够在2~3个开关周期内检测出IGBT开路故障。