One step to generate quantum controlled phase-shift gate using a trapped ion

This paper presents a very simple scheme for generating quantum controlled phase-shift gate with only one step by using the two vibrational modes of a trapped ion as the two qubits. The scheme couples two vibration degrees of freedom coupled with a suitable chosen laser excitation via the ionic states.

Study of the EAST Fast Control Power Supply Based on Carrier Phase-Shift PWM

EAST （experimental advanced superconducting tokamak） fast control power supply is a high-capacity single-phase AC/DC/AC inverter power supply, which traces the displacement signal of plasma, and excites coils in a vacuum vessel to produce a magnetic field that realizes plasma stabilization. To meet the requirements of a large current and fast response, the multi- ple structure of the carrier phase-shift three-level inverter is presented, which realizes parallelled multi-inverters, raises the equivalent switching frequency of the inverters and improves the per- formance of output waves. In this work the design scheme is analyzed, and the output harmonic characteristic of parallel inverters is studied. The simulation and experimental results confirm that the scheme and control strategy is valid. The power supply system can supply a large current, and has a perfect performance on harmonic features as well as the ability of a fast response.

Highly Efficient and Stable Hybrid White Organic Light Emitting Diodes with Controllable Exciton Behavior by a Mixed Bipolar Interlayer

Highly efficient and stable hybrid white organic light-emitting diodes （HWOLEDs） with a mixed bipolar interlayer between fluorescent blue and phosphorescent yellow emitting layers are demonstrated. The bipolar interlayer is a mixture of p-type diphenyl （l0-phenyl-lOH-spiro [acridine-9,9＇-fluoren]-3Lyl） phosphine oxide and n-type 2＇,2- （1,3,5-benzinetriyl）-tris（1-phenyl-l-H-benzimidazole）. The electroluminance and Commission Internationale de l＇Eclairage （CIE1931） coordinates＇ characteristics can be modulated easily by adjusting the ratio of the hole- predominated material to the electron-predominated material in the interlayer. The hybrid WOLED with a p-type：n-type ratio of 1：3 shows a maximum current efficiency and power efficiency of 61.1 ed/A and 55.8 lm/W, respectively, with warm white CIE coordinates of （0.34, 0.43）. The excellent efficiency and adaptive CIE coordi- nates are attributed to the mixed interlayer with improved charge carrier balance, optimized exciton distribution, and enhanced harvesting of singlet and triplet excitons.

Research on the Intelligent Control Strategy of the Fuel Cell Phase-Shifting Full-Bridge Power Electronics DC-DC Converter

focus of all countries.As an effective new energy,the fuel cell has attracted the attention of scholars.However,due to the particularity of proton exchange membrane fuel cell(PEMFC),the performance of traditional PI controlled phase-shifted full-bridge power electronics DC-DC converter cannot meet the needs of practical application.In order to further improve the dynamic performance of the converter,this paper first introduces several main topologies of the current mainstream front-end DC-DC converter,and analyzes their performance in the fuel cell system.Then,the operation process of the phase-shifted fullbridge power electronics DC-DC converter is introduced,and the shortcomings of the traditional PI control are analyzed.Finally,a double closed-loop adaptive fuzzy PI controller is proposed,which is characterized by dynamically adjusting PI parameters according to different working states to complete the intelligent control of phase-shifted full-bridge DC-DC converter.The simulation results in MATLAB/Simulink show that the proposed algorithm has good a control effect.Compared with the traditional algorithm,the overshoot and stabilization time of the system are shorter.The algorithm can effectively suppress the fluctuation of the output current of the fuel cell converter,and is a very practical control method.

Research on Phase-Shifted Full-Bridge Circuit Based on Frequency and Phase-Shift Synthesis Modulation Strategy

The full-bridge converters usually use transformer leakage inductance and parallel resonant capacitors to achieve smooth current commutation and soft switching functions,which can easily cause problems such as energy leakage and significant duty cycle loss.This paper designs a novel full-bridge zero-current(FB-ZCS)converter with series resonant capacitors and proposes a frequency and phase-shift synthesis modulation(FPSSM)control strategy based on this topology.Compared with the traditional parallel resonant capacitor circuit,the passive components used are significantly reduced,the structure is simple,and there is only a slight energy loss.By controlling the charging time of the capacitor,it can be achieved without additional switches or auxiliary circuits.The automatic control of capacitor energy based on input current addresses the low efficiency of the traditional control strategies.This paper introduces its principle in detail and verifies it through simulation.Finally,an experimental prototype was built further to demonstrate the feasibility of the theory through experiments.The module can be applied to a photovoltaic DC collection system using input parallel output series(IPOS)cascade to provide a new topology for large-scale,long-distance DC transmission.

Study on Rotor IGBT Chopper Control for Induction Motor Drive

Rotor chopper control is a simple and effective drive method for induction motor. This paper presents a novel IGBT chopper topology,which can both adjust rotor resistance and protect IGBT efficiently. Investigation on the quasi transient state of the rotor rectifying circuit is made, and a nonlinear mapping between the equivalent resistance and the duty cycle is deduced. Furthermore, the method for determining the magnitude of the external resistor is introduced.

A 4H-SiC trench IGBT with controllable hole-extracting path for low loss

A novel 4H-Si C trench insulated gate bipolar transistor(IGBT)with a controllable hole-extracting(CHE)path is proposed and investigated in this paper.The CHE path is controlled by metal semiconductor gate(MES gate)and metal oxide semiconductor gate(MOS gate)in the p-shield region.The grounded p-shield region can significantly suppress the high electric field around gate oxide in Si C devices,but it weakens the conductivity modulation in the Si C trench IGBT by rapidly sweeping out holes.This effect can be eliminated by introducing the CHE path.The CHE path is pinched off by the high gate bias voltage at on-state to maintain high conductivity modulation and obtain a comparatively low on-state voltage(VON).During the turn-off transient,the CHE path is formed,which contributes to a decreased turn-off loss(EOFF).Based on numerical simulation,the EOFFof the proposed IGBT is reduced by 89%compared with the conventional IGBT at the same VONand the VONof the proposed IGBT is reduced by 50%compared to the grounded p-shield IGBT at the same EOFF.In addition,the average power reduction for the proposed device can be 51.0%to 81.7%and 58.2%to 72.1%with its counterparts at a wide frequency range of 500 Hz to 10 k Hz,revealing a great improvement of frequency characteristics.

Efficiency Improvement and High-performance Control of Dual-active-bridge DC-DC Converter with Triple-phase-shift Modulation

This paper analyzes the optimal switching modes of the dual-active-bridge(DAB)DC-DC converter to minimize losses in DC-DC converters that exhibit a wide voltage range,high efficiency,and high performance.By solving the multiobjective constrained conditional extremums with the Karush-KuhnTucker(KKT)method,a triple-phase-shift(TPS)optimal modulation with full range of operation,global continuity,and simple calculation is obtained.By adopting TPS modulation,the DAB can decrease reactive power when dc voltages are mismatched and obtain global optimization of conduction loss and soft-switching in the full range of operation.Generation of dc-offset current in the ac link is analyzed.Static and dynamic dc-offset currents are suppressed based on TPS modulation.With direct-power feed-forward,high-dynamic control is used to improve system response to external disturbances.The digital control strategy of the whole system is designed,and optimal modulation and high-performance control are verified on the experimental prototype.

Digital control system for pulsed MIG welding power based on STM32

Digital control system for pulsed MIG welding power based on STM32 is set up with 32-bit STM32FlO3ZET6 directing against the pulse waveform modulation of pulsed MIG welding. High-frequency inverter and medium-low frequency pulse waveform modulation of pulsed MIG welding are realized by using the integrated PWM module within STM32 to generate PWM signals of phase-shifted full-bridge soft-switching and constant-current control of output current is achieved by means of anti-windup PI control algorithm to improve the stability and reliability of control system. Experimental results demonstrate that the designed digital control system based on STM32 can achieve pegrect pulsed MIG welding technique with stable welding process and good weld appearance, fully demonstrating the advantages of digital control based on STM32.

Integrated Movable System of Fuel Cell with Replaceable Fiber Bipolar Plate

It is important for the fuel cell integrated movable system to operate voltage and current using safety control technology. In order to work at the convenient condition of the fuel cell system, high performance fuel cell stack with replaceable fiber bipolar plate should be arranged with the integrated subsystem and appropriate working process. The parameters which affect the performance of PEMFC consisting of relative humidity, reaction temperature, gas inlet temperature, gas inlet pressure, and hydrogen and air flow rate. This study is to develop the integrated movable system on distributed power generation and backup power application, such as oxidant supply system, fuel supply system, heat management system, water management system, and power conditioning system. It comprises a novel PLC (Programmable Logic Control) system and human-machine interface. The controller is developed to control fuel cell system and record the operation data by using data acquisition system. The controller can be applied to high performance stack and system to obtain the best performance. The easy-taken high capacity hydrogen barrel embedded into steel plate of this movable system and more convenient than other fuel cell system.

结温导向的牵引变流器寿命优化控制

结温是影响绝缘栅双极型晶体管(IGBT)寿命的主要因素。为了提高地铁两电平牵引变流器寿命,提出一种降低结温的异步牵引电机双矢量模型预测转矩控制(DVMPTC)策略。将传统DVMPTC的第二个电压矢量选择范围缩小在与第一个电压矢量不切换或仅切换一次的范围,降低IGBT开关损耗的同时减小系统计算量;在代价函数中约束IGBT及其反并联二极管的损耗,动态加入损耗因子,并赋予权重系数,使得最优矢量的选择兼顾控制性能与降低损耗。通过仿真分析,本文所提方法相较于传统基于分段调制算法的直接转矩控制策略,降低了结温及其波动,提高了牵引变流器寿命。

高频链矩阵变换器直接功率反步控制策略

针对高频链矩阵变换器(HFLMC)电路前后级耦合导致系统动态性能和鲁棒性降低的问题,提出一种基于直接功率的非线性反步控制策略(BS-DPC)。首先,建立HFLMC非线性数学模型和有功、无功功率动态模型,分析双极性电流空间矢量调制策略;然后,在考虑系统不确定性情况下引入2个解耦控制分量,设计直流输出电流和无功功率反步控制器,实现电池不同工况下输出电流参考值的快速跟踪控制;最后,根据李雅普诺夫稳定性理论证明HFLMC闭环系统全局渐进稳定性,并对比传统PI直接功率控制和BS-DPC策略。仿真和实验结果表明,所提BS-DPC策略控制HFLMC提高了输出电流的动态性能和电网波动及直流滤波电感变化下的鲁棒性,响应时间减少了约78%,网侧THD降低了0.98%。

IGBT并联应用均流控制技术综述

绝缘栅双极型晶体管IGBT(insulated-gate bipolar transistor)在现代电力电子技术中应用广泛,在某些单个器件性能达不到设计要求的工作场合,IGBT的并联使用成为一种经济可行的方法。多模块IGBT并联应用可以简化电路结构,增大变流器输出功率,提高装置功率密度。IGBT并联应用过程中,器件本体的动、静态特性及结温的差异,驱动电路结构及功率回路不对称性,伴随IGBT长期使用出现的老化或失效等问题,都会引起并联IGBT支路电流的不均衡,影响系统的可靠性和稳定性。对国内外IGBT并联应用所关注的研究热点进行了调研分析,总结了IGBT并联动、静态电流不均衡产生的原理及影响,分析了电流均衡控制原理的差异。从功率回路均流控制和驱动回路均流控制两个方面,对IGBT并联应用均流控制的工作特性进行了分析总结和技术对比,并对IGBT并联均流技术的发展方向进行了展望。

基于DAC阵列的光交叉芯片控制驱动系统

为标定光交叉芯片驱动电压,控制光交叉芯片实现光路由功能,提出并搭建了基于多通道DAC(Digital to Analog Converter)阵列的控制驱动电路系统。系统主要由控制系统模块、多路驱动电路模块及上位机控制模块构成。控制电路和驱动电路具有调校简单、可双极性输出、输出路数多、加电精确度较高的特点,解决了当前驱动电路工作繁琐、加电极性单一、加电路数少、精度差的问题。上位机控制模块除了可控制驱动电路施加控制电压外,还可接收来自数据采集装置采集到的光功率信号作为控制驱动系统的反馈信号。通过分析控制电压与光功率之间的关系,可得到最佳的光交叉芯片控制驱动电压。系统测试实验结果表明,该系统能提供高精确度的双极性驱动电压,有效地对光交叉芯片进行驱动。可在较短的时间内标定出光开关的控制电压,完全可以满足有源光交叉芯片控制中对驱动电压的需求。该系统在光交叉芯片控制方面具有一定的应用价值。

双U/f下垂控制下双极MMC-HVDC系统交流阻抗建模及稳定性分析

基于模块化多电平换流器的高压柔性直流输电系统(modular multilevel converter-based high voltage direct current,MMC-HVDC)常采用双极接线方式以提高系统功率输送能力和可靠性。然而目前对于风电场经柔直外送系统的稳定性研究集中于单极接线方式,孤岛直驱风电场与采用不同双极协调控制的双极MMC-HVDC互联系统小信号稳定性问题还有待进一步探究。该文首先考虑频率耦合特性、参考系初相位和直流侧耦合特性的影响,分别建立了采用双U/f下垂控制和定U/f-P/Q控制的双极MMC-HVDC系统交流侧等效SISO阻抗模型,并详细分析了金属回线阻抗和双极间功率均分度对交流阻抗特性的影响。接着对比研究了两种协调控制中共有控制环路和特有控制环路对交流侧负电阻特性及互联系统稳定性的影响规律。最后,孤岛直驱风电场经两种双极协调控制下双极MMC-HVDC外送系统Matlab/Simulink时域仿真结果和硬件在环半实物实时仿真实验结果验证了所提出的小信号阻抗模型的精确性和稳定性分析结论的有效性。

双极性直流微电网的改进型高阶滑模自抗扰控制

针对双极性直流微电网中分布式新能源的系统功率波动、负载侧负荷频繁投切等不确定因素所引起母线电压波动问题,以基于风光互补含混合储能的双极性直流微电网为研究对象,提出一种双闭环改进型高阶滑模自抗扰控制策略。首先,依据自抗扰理论将控制系统拟合为一阶系统模型,转化为自抗扰控制系统范式。其次,设计了改进型超螺旋滑模控制器代替传统自抗扰控制中的线性控制器,引入了具有快速收敛性的级联有限时间扩张状态观测器代替线性扩张状态观测器,既能通过高阶滑模控制算法抑制抖振,又能提高对系统集总扰动的估计精度,从而利用非线性控制策略的优势改善系统动态响应过程及抗扰性能。然后,通过Lyapunov理论证明控制系统的稳定性。最后,基于Matlab/Simulink仿真软件以及搭建实验平台对3种不同控制策略进行对比验证,实验表明所提控制能够很好地抵抗扰动和提高系统的暂态性能。

受端电网故障下真双极柔性直流输电系统电压协同控制方法

盈余功率积累可能诱发基于模块化多电平换流器的高压柔性直流输电系统(high-voltage direct current based on the modular multilevel converter,MMC-HVDC)过压闭锁,乃至引发海上风电场机组失步或受端电网低频减载。现有降压或升频等直流电压控制方法仅针对伪双极接线,缺乏讨论不同控制模式的换流器间协同原则;且控制参考值未能自适应受端电网的故障严重程度,导致海上风电场有功功率调节过量。该文基于受端电网故障下MMC-HVDC平均值模型,解析了海上正负极换流器和风电场的功率耦合特性,提出了交流母线电压控制极换流器平衡换流站间有功功率,有功和无功功率控制极换流站抑制极间不平衡的协同原理。通过解析海上风电场在交流母线电压控制极换流器降压作用下的功率外特性,提出了恰好避免直流电压越限的临界交流母线电压计算方法。通过解析使得受端换流站有功电流受限的交流母线电压作为启动门槛,提出了受端电网故障下真双极MMC-HVDC电压协同控制方法。理论分析和仿真结果表明,所提方法令海上正负极换流器分别运行于临界交流母线电压和抑制极间不平衡的有功功率,可在避免直流电压越限的前提下,最大限度提升MMC-HVDC在受端电网故障工况下的有功功率传输能力。

基于dv/dt参数提取的变流器IGBT驱动自调节技术

绝缘栅双极晶体管(IGBT)作为轨道交通变流器关键部件,对其驱动的调节可以显著改善dv/dt、开关损耗等影响变流器运行的重要参数。为此提出了一种基于dv/dt参数提取的变流器IGBT驱动自调节技术。首先基于IGBT驱动等效电路建立数学模型,分析了dv/dt、门极电阻、开关损耗三者之间的数学关系。其次以dv/dt参数的限制为主要优化目标,开关损耗的平衡为约束条件,提出一种基于Bang-Bang控制的自调节控制策略从而实现门极电阻主动切换,并在双脉冲测试中整定控制策略重要参数。最后通过有无自调节技术对比试验测试,验证了本技术的有效性。

稳定期双相障碍Ⅰ型患者的认知功能及相关因素

目的:探讨稳定期双相障碍Ⅰ型患者认知功能损害及其相关因素。方法:纳入来自广州市精神病医院门诊和住院部的符合美国精神障碍诊断与统计手册第四版双相障碍Ⅰ型诊断标准的稳定期患者160例,以及来自本院或其他单位/学校的正常对照145名。采用数字符号、连线测验A(TrailMakingTestA,TMT-A)、数字广度(顺背)、视觉再生检测受试者的注意、记忆功能,用连线测验B(TrailMakingTestB,TMT-B)和数字广度(倒背)检测执行功能,特别是工作记忆和认知灵活性。结果:(1)患者组数字符号[(46.3±11.9)vs.(57.3±12.5)]、数字广度[顺背:(7.7±1.3)vs.(8.1±1.5)、倒背:(4.8±1.3)vs.(5.6±1.8)、总分:(12.5±2.2)vs.(13.68±2.9)]、视觉再生[(9.3±3.1)vs.(10.26±3.3)]、TMT-A[(54.1±19.0)vs.(42.6±16.9)]、TMT-B[(81.8±30.7)vs.(67.0±28.0)]成绩均差于正常对照组(Ps<0.01)。(2)按有(n=98)和无(n=62)精神病性症状将患者组进一步分层分析,方差分析显示组间差异有统计学意义(P<0.05),经LSD检验,2个患者亚组的数字广度(倒背、总分)、TMT-A、TMT-B成绩均差于正常对照组(P<0.05);有精神病性症状患者组的数字符号、数字广度(顺背)、视觉再生成绩也差于正常对照组(P<0.05)。(3)相关分析显示,患者组上述认知指标均与汉密尔顿抑郁量表和/或Young躁狂量表评分弱相关(|r|=0.15～0.26,Ps<0.05),数字符号与病程评分弱相关(r=-0.18,P<0.05);未发现发病年龄和稳定期时间与任何认知功能指标相关(P>0.05)。结论:稳定期双相障碍Ⅰ型患者存在明显的注意、记忆和执行功能损害,并与临床症状等临床特征无明显相关或相关性不强。

双相障碍抑郁发作患者氧化应激水平

目的:探讨自由基、抗氧化酶在双相障碍抑郁发作病理机制中的作用。方法:采用病例-对照研究设计,对56例符合美国精神障碍诊断与统计手册第4版诊断标准的门诊及住院双相障碍抑郁发作患者(包括双相Ⅰ型组23例及双相Ⅱ型组33例)以汉密尔顿抑郁量表(Hamilton Depression Scale,HAMD)评定抑郁症状,并检测血浆丙二醛(malondialdehyde,MDA)、超氧化物歧化酶(superoxide dismutase,SOD)、过氧化氢酶(catalase,CAT)以及谷胱甘肽过氧化物酶(glutathione peroxidase,GSH-Px)含量,选择32名正常健康人作为对照(对照组),使用单因素方差分析以及多元线性回归分析比较各参数在组间差异及其与HAMD评分之间的关系。结果:双相Ⅰ型和Ⅱ型组MDA水平均高于对照组,SOD、CAT及GSH-Px水平低于对照组,差异均有统计学意义;多因素分析显示,在控制身高、体质量指数和年龄等因素后HAMD评分与血浆MDA水平呈正相关(β=0.46,P<0.05),与SOD(β=-0.27,P<0.05)、CAT(β=-0.41,P<0.05)和GSH-PX(β=-0.34,P<0.05)水平呈负相关。结论:氧化应激反应可能参与双相障碍抑郁发作的发生过程,疾病严重程度可能与氧化应激反应失衡有关。