Low switching loss and increased short-circuit capability split-gate SiC trench MOSFET with p-type pillar

A split-gate SiC trench gate MOSFET with stepped thick oxide, source-connected split-gate(SG), and p-type pillar(ppillar) surrounded thick oxide shielding region(GSDP-TMOS) is investigated by Silvaco TCAD simulations. The sourceconnected SG region and p-pillar shielding region are introduced to form an effective two-level shielding, which reduces the specific gate–drain charge(Q_(gd,sp)) and the saturation current, thus reducing the switching loss and increasing the short-circuit capability. The thick oxide that surrounds a p-pillar shielding region efficiently protects gate oxide from being damaged by peaked electric field, thereby increasing the breakdown voltage(BV). Additionally, because of the high concentration in the n-type drift region, the electrons diffuse rapidly and the specific on-resistance(Ron,sp) becomes smaller.In the end, comparing with the bottom p~+ shielded trench MOSFET(GP-TMOS), the Baliga figure of merit(BFOM,BV~2/R_(on,sp)) is increased by 169.6%, and the high-frequency figure of merit(HF-FOM, R_(on,sp) × Q_(gd,sp)) is improved by310%, respectively.

A New Switching Sequences of SVPWM for Six-Phase Induction Motor with Features of Reduced Switching Losses

In this paper,new SVPWM switching sequences for six-phase asymmetrical induction motor drives are derived with the aim to reduce inverter’s switching losses.Total three switching sequences are introduced in this paper.These sequences are derived such that the phases get continuously clamped when a current of the phases is around its peak magnitude and hence reduced switching losses are recorded.The comparative performances of these modulation techniques are studied with two existing switching sequences.Simulation,analytical and experimental results are presented.Based on these results,it is found that new switching sequences reduce switching losses effectively in dual three phase inverters.

A super junction SiGe low-loss fast switching power diode

This paper proposes a novel super junction （S J） SiGe switching power diode which has a columnar structure of alternating p- and n- doped pillar substituting conventional n- base region and has far thinner strained SiGe p＋ layer to overcome the drawbacks of existing Si switching power diode. The SJ SiGe diode can achieve low specific on-resistance, high breakdown voltages and fast switching speed. The results indicate that the forward voltage drop of SJ SiGe diode is much lower than that of conventional Si power diode when the operating current densities do not exceed 1000 A/cm^2, which is very good for getting lower operating loss. The forward voltage drop of the Si diode is 0.66V whereas that of the SJ SiGe diode is only 0.52V voltages are 203 V for the former and 235 V for the latter. at operating current density of 10A/cm^2. The breakdown Compared with the conventional Si power diode, the reverse recovery time of SJ SiGe diode with 20 per cent Ge content is shortened by above a half and the peak reverse current is reduced by over 15%. The SJ SiGe diode can remarkably improve the characteristics of power diode by combining the merits of both SJ structure and SiGe material.

Low working loss Si/4H-SiC heterojunction MOSFET with analysis of the gate-controlled tunneling effect

A silicon (Si)/silicon carbide (4H-SiC) heterojunction double-trench metal-oxide-semiconductor field effect transistor (MOSFET) (HDT-MOS) with the gate-controlled tunneling effect is proposed for the first time based on simulations. In this structure, the channel regions are made of Si to take advantage of its high channel mobility and carrier density. The voltage-withstanding region is made of 4H-SiC so that HDT-MOS has a high breakdown voltage (BV) similar to pure 4H-SiC double-trench MOSFETs (DT-MOSs). The gate-controlled tunneling effect indicates that the gate voltage (V_(G)) has a remarkable influence on the tunneling current of the heterojunction. The accumulation layer formed with positive VG can reduce the width of the Si/SiC heterointerface barrier, similar to the heavily doped region in an Ohmic contact. This narrower barrier is easier for electrons to tunnel through, resulting in a lower heterointerface resistance. Thus, with similar BV (approximately 1770 V), the specific on-state resistance (R_(ON-SP)) of HDT-MOS is reduced by 0.77 mΩ·cm^(2) compared with that of DT-MOS. The gate-to-drain charge (Q_(GD)) and switching loss of HDT-MOS are 52.14% and 22.59% lower than those of DT-MOS, respectively, due to the lower gate platform voltage (V_(GP)) and the corresponding smaller variation (ΔV_(GP)). The figure of merit (Q_(GD)×R_(ON-SP)) of HDT-MOS decreases by 61.25%. Moreover, the heterointerface charges can reduce RON-SP of HDT-MOS due to trap-assisted tunneling while the heterointerface traps show the opposite effect. Therefore, the HDT-MOS structure can significantly reduce the working loss of SiC MOSFET, leading to a lower temperature rise when the devices are applied in the system.

Simulation realization of skip cycle mode integrated control circuit in the switching power supply with low standby loss

This paper explores and proposes a design solution of an integrated skip cycle mode （SCM） control circuit with a simple structure. The design is simulated and implemented with XD10H-1.0μm modular DIMOS 650 V process. In order to meet the requirement of a wide temperature range and high yields of products, the schematic extracted from the layout is simulated with five process corners at 27℃ and 90℃. Simulation results demonstrate that the proposed integrated circuit is immune to noise and achieves skipping cycle control when switching mode power supply （SMPS） works with low load or without load.

输入电压波动下变模态宽增益谐振变换器研究

针对传统LLC谐振变换器在宽输入下开关损耗过大、增益范围较窄、难以保持输出稳定的问题,研究一种变模态宽增益谐振变换器。该变换器及其控制策略能够依据输入电压的大小,在全桥和半桥两种模态之间自由切换,有效拓宽电压增益范围。通过对变换器谐振腔结构的优化,进一步拓宽增益,减小能量循环、降低开关管损耗,同时能够在电流传输中引入三次谐波,降低损耗。利用基波近似法对电压增益进行推导,绘制增益曲线图,分析谐振参数对电压增益的影响,根据需求设计合适的参数,并运用变频控制,通过调节输入电压,使得变换器运行在不同模态,实现电压平稳输出。搭建一台55~220 V输入、30 V输出的300 W实验样机,实验结果证明了所提变换器控制策略的有效性。

并联IGBT占空比的温度特性建模与分析

并联IGBT是解决托卡马克(Tokamak)装置中等离子体垂直位移快速控制电源容量逐渐增大问题的有效途径。而并联IGBT之间的结温平衡是并联系统安全稳定运行的关键因素之一。因此,研究结温对并联IGBT功率损耗差异的影响对提高并联系统的稳定性至关重要。然而现有的研究成果主要集中在单个器件损耗模型或者是并联IGBT的最佳工作频率范围而未涉及对并联IGBT最佳工作占空比范围的讨论。研究发现,当IGBT工作在正温度系数区间时,结温差异造成的通态损耗差异与开关损耗差异呈不同的温度特性。因此,提出零温度-占空比的概念来估计并联IGBT之间结温失配趋势。该文建立零温度-占空比模型,并以此来分析电路设计参数、IGBT器件参数以及结温差异对并联IGBT最佳工作占空比范围的影响。实验结果表明,通过零温度-占空比模型可以对并联IGBT的可靠性、电路设计参数以及器件选型提供可行的参考。

适用于中点箝位型三电平逆变器的多目标调制策略

为同时实现中点箝位型三电平逆变器的中点电压平衡和共模电压降低,分别分析了基于载波脉宽调制(CBPWM)和基于虚拟空间矢量脉宽调制(VSVPWM)的中点电压平衡和共模电压降低方法。基于CBPWM提出一种可以降低共模电压的载波脉宽调制(RCMV_CBPWM)策略,可将大多数工作区域的共模电压限制在直流侧电压的1/6以内。为了实现上述2个目标,同时不过分增加开关损耗,在RCMV_CBPWM基础上提出了一种多目标调制(MOPWM)策略,在全调制度和全负载功率因数范围内,共模电压可限制在直流侧电压的1/6以内并实现中点电压平衡,且其开关损耗低于VSVPWM。比较了MOPWM、RCMV_CBPWM和VSVPWM在中点电压控制、共模电压降低和开关损耗降低方面的性能。实验结果验证了MOPWM的可行性和优越性。

Atom-loss-induced quantum optical bi-stability switch

We investigate the nonlinear dynamics of a system composed of a cigar-shaped Bose-Einstein condensate and an optical cavity with the two sides coupled dispersively.By adopting discrete-mode approximation for the condensate,taking atom loss as a necessary part of the model to analyze the evolution of the system,while using trial and error method to find out steady states of the system as a reference,numerical simulation demonstrates that with a constant pump,atom loss will trigger a quantum optical bi-stability switch,which predicts a new interesting phenomenon for experiments to verify.

具有自适应浮空分裂栅IGBT的特性研究

为降低传统绝缘栅双极型晶体管(IGBT)开关损耗E_(SW),提出了一种具有自适应浮空分裂栅的IGBT结构(AFSG-IGBT),并进行了仿真研究。此结构在传统载流子存储沟槽栅双极晶体管结构(CSTBT)的基础上,在沟槽栅中集成了分裂栅和P型结型场效应晶体管(JFET)。栅极与P型JFET相互耗尽,可以大幅降低米勒电容C_(GC),并且降低E_(SW)。在AFSG-IGBT导通时,P型JFET的沟道被夹断,使分裂栅保持在浮空状态,从而保证足够的注入增强效应。仿真结果表明,相比于CSTBT,AFSG-IGBT在高集电极电压下C_(GC)降低了79.7%,栅极电荷Q_(g)降低了52.6%。在导通压降(V_(ON))为1.4 V和集电极电流为100 A/cm^(2)的条件下,AFSG-IGBT的开通损耗E_(on)和关断损耗E_(off)分别比CSTBT低了37.1%和28.5%,并且该结构在驱动电阻分别为5Ω和10Ω时都显示出更优良的V_(ON)-E_(SW)折中关系。

基于全桥型MMC的开关序列切换方法及IGBT开路故障诊断策略

全桥型模块化多电平换流器(modular multilevel converter,MMC)因具备直流故障穿越能力受到广泛关注,但全桥子模块(full-bridge submodule,FBSM)中更多的开关器件数量对MMC的运行可靠性带来了巨大挑战。针对于此,首先提出了基于全桥型MMC的开关序列(switching sequence,SS)切换方法,通过增加一种子模块(submodule,SM)切除状态,能在不额外增加开关损耗的基础上,使所有类型IGBT开路故障均能够体现故障特性。进一步,分析了所提SS切换方法下的故障特点,并提出了IGBT开路故障诊断策略。所提策略通过判断SS计数是否超出阈值对故障进行检测,并定位故障SM,之后基于SS计数的正负或电容电压变化值进一步辨别故障类型。所提故障诊断策略能够准确检测出IGBT故障,定位出发生IGBT开路故障的SM,并辨别其故障类型,有利于主动运维。此外,所提策略无需额外硬件,并可在一个工频周期(20 ms)内完成对所有故障的准确诊断。最后通过硬件在环平台验证了所提SS切换方法及IGBT开路故障诊断策略的有效性。

兼顾共模电压抑制与中性点电压平衡的T型三电平逆变器DPWM策略

为提升T型三电平逆变器的可靠性与效率,提出1种可抑制共模电压的非连续脉宽调制RCVDPWM(reduced-common-mode-voltage pulse width modulation)策略,同时能够降低开关损耗。根据T型三电平拓扑开关序列对共模电压作用机理,总结出5种实现共模电压抑制的非连续脉宽调制DPWM(discontinuous pulse width modulation)钳位方式。分析表明,在任意调制度和相角下,至少存在1种实现共模电压抑制的钳位方式。对于部分相角区间存在的多种钳位方式,优先选取电流绝对值最大相的开关管进行钳位,以降低开关损耗。同时,所提RCVDPWM策略可保证中性点电压直流分量为0,具有中性点自平衡能力。实验结果验证了RCVDPWM策略的可行性与有效性。

10.4~28 GHz的超宽带6位数字衰减器设计

基于中芯国际40 nm CMOS工艺设计并实现了一种超宽带6位数字衰减器,其工作频率为10.4~28 GHz。该衰减器采用内嵌式开关型结构,6位衰减单元的设计采用T型、桥T型和π型三种拓扑结构。该6位衰减器可以实现0.5 dB的衰减步进,31.5 dB的动态衰减范围。采用大衰减量幅度补偿电路和高匹配特性的衰减位级联结构,衰减器在10.4~28 GHz的频段范围内具有平坦的64态衰减量,衰减器的整体前仿真插入损耗为1.73~2.08 dB,后仿真插入损耗为4.32~6.31 dB,64态的输入输出回波损耗均小于-10 dB。

基于器件复用的电流型软开关光伏全桥逆变器

提出了一种新颖的适用于分布式光伏的无源无损软开关全桥逆变器,用以减小逆变器高频开关的损耗。该电路保留了传统双降压全桥逆变器高效可靠的优点,在此基础上通过器件复用的方式,增加了无源无损吸收电路,并通过无源器件自身的谐振过程改善功率器件的开关状况实现软开关的功能,同时使无源无损吸收电路的能量得到有效转移,使得所提无源无损软开关全桥逆变器具有较高的可靠性。实验验证了所提无源无损吸收电路有效减小了开关损耗,提高了系统效率。

一种碳化硅与硅器件混合型三电平有源中点钳位零电压转换软开关变流器

该文提出一种碳化硅与硅(SiC&Si)器件混合型三电平有源中点钳位零电压转换(3L-ANPC ZVT)变流器拓扑。该拓扑中每相主电路采用两个SiC MOSFET器件工作在高频,其余主电路开关为Si器件工作在低频,通过辅助电路使得SiC器件工作在ZVT软开关条件下,进一步降低SiC MOSFET高频开关损耗和开关应力。拓扑中辅助电路开关采用Si器件且仅在主器件换相过程工作,具有额定电流小且无开关损耗的特点。该文首先介绍该软开关变流器的电路拓扑结构和工作原理,并给出辅助电路参数的优化设计过程。然后基于双脉冲测试数据对变流器进行损耗建模,分析对比不同开关频率下硬开关和软开关有源中点钳位三电平变流器的损耗分布和效率变化,揭示所提出的软开关变流器拓扑在高开关频率下可以有效改善变流器的效率。最后通过搭建的单相变流器实验平台验证上述分析结论的正确性。

有限双极性软开关焊接电源仿真研究

有限双极性全桥软开关克服了移相全桥软开关过程中的占空比丢失和软开关负载范围小等问题,减小了全桥逆变电路的开关损耗,而焊接过程中的电弧负载存在空载状态,有限双极性全桥软开关空载时难以实现零电压开关。ISOP拓扑结构能够降低开关管的压降,从而选取低耐压的开关管,进一步降低电路的损耗。基于有限双极性控制策略,选取ISOP拓扑结构,采用倍流整流电路以实现全负载范围内的软开关,通过PSpice仿真软件对该电路软开关情况以及超前臂关断损耗进行仿真研究,为实际电路提供研究依据。搭建的焊接电源在全负载范围内实现软开关,同时对比了电源在硬开关和软开关工作情况下的温升情况,空载情况下硬开关温升较小,重载情况下软开关温升较小。

基于各向异性导电膜的射频SP8T开关无损测试

为了解决射频器件无损测试的难点,基于各向异性导电膜Z轴(ACF-Z)连接结构,设计并实现了射频器件无损测试技术。针对表面贴装式GaAs金属半导体场效应晶体管(MESFET)单刀八掷(SP8T)开关,该测试技术使用ACF-Z轴连接结构实现器件与测试板的无损连接,通过矢量网络分析仪对GaAs MESFET SP8T开关性能进行测试,最多可同时测试SP8T开关的8个通道。测试结果显示,1~8 GHz内,器件的插入损耗为-15~-35 dB,回波损耗为-15~-35 dB,测试过程中未对器件造成损伤。

MMC低开关频率的自适应降损控制策略

针对半桥型模块化多电平换流器(MMC),本文提出了一种低开关频率的自适应降损策略,解决了最近电平逼近调制(NLM)策略和基于排序算法的电容均压控制策略导致的换流阀功率器件开关损耗较高的问题。首先,分析了MMC内部悬浮电容均压效果与其开关频率间的制约关系,明确实际工程应用对子模块电容电压均衡性的要求,为后续低开关频率的自适应降损控制策略提供理论依据。其次,基于所设置子模块电容电压动态限值、流经子模块的电流方向以及子模块工作状态,确定每个周期内子模块投入优先级,从而减少非必要的子模块附加投切动作,降低子模块开关频率。然后,利用线性插值方法,实现不同系统传输功率下子模块电容电压动态限值的自适应调整,进一步降低子模块开关频率。最后,基于在Matlab搭建的MMC仿真模型,验证了本文所提方法。

新一代安全型道岔控制电路研制

ZDJ9道岔控制电路存在2DQJ继电器第一、二组加强接点拉弧灼烧氧化,导致的接点接触不良现象。因2DQJ第一组前接点与第二组后接点为表示共用接点,接点氧化可导致道岔失表故障;同时,道岔表示二极管存在被瞬间启动电流击穿的风险,也会导致道岔失表故障。现对道岔控制电路原理进行分析、调整电路逻辑,并对ZDJ9交流五线制道岔控制电路进行优化研究,避免道岔失表故障,来提高道岔设备的整体可靠性。

一种实现能量重复利用的SiC MOSFET谐振驱动电路

针对传统SiC MOSFET驱动电路的驱动电阻导致损耗较高的问题,提出了一种SiC MOSFET谐振驱动电路。详细分析了提出的谐振驱动电路的工作原理,通过控制驱动电路中各开关管的通断,使电感与SiC MOSFET的输入电容产生谐振,从而重复利用输入电容中的能量,减小了驱动损耗。相较于传统驱动电路,该谐振驱动电路的驱动损耗主要包括新增开关管及其续流二极管导通时的导通损耗和SiC MOSFET内阻所产生的损耗,而非驱动电阻导致的损耗。搭建仿真模型和实验平台,对提出的谐振驱动电路在高频和不同占空比下的驱动性能进行验证,结果表明提出的谐振驱动电路具有良好的驱动性能,能够在高频工作条件下保证SiC MOSFET的通断。