多谐振软开关全桥Boost变换器

提出一种利用多谐振实现开关管软开关的全桥Boost变换器.其将变压器漏感作为谐振电感,利用电感与电容谐振实现桥臂开关管和箝位开关管的软开关.桥臂开关管工作于零电流开通与零电压关断状态.有源箝位电路既可抑制变换器工作时可能出现的振荡电压,又可将箝位电容吸收的能量返还回主电路,且箝位开关管工作于零电压开通与零电流关断状态.最后利用硬件实验验证了其多谐振软开关特性.     

基于准谐振型软开关的高频开关电源变换器

传统高频开关电源变换电路采用硬开关技术,电路功耗大,承受电压、电流应力高。为了克服硬开关技术中开关管在有电流通过的情况下被强制关断,有电压情况下被强制导通而带来的各种不利因素,采用准谐振型软开关技术,即零电流开关（ZCS）准谐振变换器、零电压开关（ZVS）准谐振变换器,由电感、电容组成谐振回路,利用电感、电容之间的能量交换,使主开关管在零电压下导通或零电流下截止,达到了减少开关损耗及电磁干扰的目的。软开关技术在新型开关电源中广泛采用。     

新型容性整流ZVZCS三电平直流变换器

提出一种新型零电压零电流(ZVZCS)飞跨电容型不对称PWM半桥三电平变换器,该变换器原边开关器件的电压应力为输入电压的一半;所有开关器件在较宽负载范围内实现软开关,其中超前管实现ZVS开通,ZCS关断;滞后管实现ZCS开通,ZVS关断,从而降低开关损耗;副边采用容性整流,在续流阶段将原边电流降至0,使得开关器件的电流分布更加均衡并减小飞跨电容的电流应力;与此同时,消除二极管反向恢复损耗。文中讨论了电路的结构、工作原理和基础特性,为证明理论正确性,搭建一台500W实验样机来验证。     

新型单相全桥无源软开关逆变器

为改善单相全桥逆变器的运行效率,设计出了一种新型单相全桥无源软开关逆变器,在每个开关周期的换流过程中,利用逆变器的低损耗辅助谐振电路,使开关器件实现软切换以节约电能.辅助谐振电路只含有电感、电容和二极管等无源器件,不会使逆变器的控制变复杂.此外,在逆变器处于死区状态下,负载电流可通过辅助电路进行续流,减小了死区状态对逆变器输出电流波形的不利影响.文中分析了电路的工作过程,在功率为3kW的单相样机上的实验结果表明开关器件能实现软开关,逆变器输出电流波形的畸变率得到了改善.因此,该拓扑结构对于研发高性能单相全桥逆变器具有重要参考价值.     

无源器件辅助换流的单相全桥软开关逆变器

为提高单相全桥逆变器的转换效率,提出了一种无源器件辅助换流的单相全桥软开关逆变器拓扑结构,通过在逆变器桥臂上增加辅助谐振电路,实现了开关器件的软开关动作.辅助谐振电路中无辅助开关器件,只含有电感、电容和二极管等少量无源器件,这有利于降低辅助电路的成本,而且不会使逆变器的控制策略复杂化.此外,在逆变器处于死区状态时,负载电流能通过辅助谐振电路续流,可以改善逆变器输出电流波形的畸变率,减小了死区的不利影响.文中详细分析了电路的工作过程,在功率为4kW的单相实验样机上进行了实验验证,获得的实验结果表明在轻载和满载时逆变器的开关器件都能实现软开关,逆变器输出电流波形的畸变率都得到了改善.因此,该无源器件辅助换流的单相全桥软开关拓扑结构对于提高逆变器的性能具有重要意义.     

具有低电压应力的单开关、高升压比DC-DC变换器

提出一种适用于可再生能源应用场景的单开关、高升压、非隔离式DC-DC变换器。所提变换器由耦合电感、无源钳位电路、开关电容和升压电路组成。无源钳位电路可回收耦合电感的漏感能量,并限制开关管上的电压尖峰。此外,无源钳位和开关电容电路的有效整合增加了电压增益。简言之,宽连续导通模式(CCM)工作范围、耦合电感的低匝数比、开关上的低电压应力、近似零电流开关(ZCS)、二极管上的低电压应力、漏电感能量回收、和低占空比下的高电压增益是该变换器的优点。讨论和分析了变换器在连续导通模式(CCM)和非连续导通模式(DCM)下的稳态运行。最后,搭建了200 W的实验样机来验证所提变换器理论分析的正确性和可行性。     

DC-DC变换器中双开关网络的平均模型及其应用

根据电感上电流的断续情况,开关变换器可以工作在连续导电模式(CCM)和断续导电模式(DCM).开关网络的等效变比μ(t)可以被认为是CCM开关网络占空比d(t)的另一种表达式.因此,以CCM变换器为例的模型结果还可以用在其他工作模式,甚至可以使用于其他结构的变换器,需要处理的只是用μ(t)代替d(t).等效变比可以用作判断工作模式的标准.在这个仿真电路中,用平均开关模型子电路CCM-DCM代替了由功率场效应功率管和二极管组成的开关网络.     

一种同步BUCK变换器反向限流电路的设计

同步BUCK变换器在轻载模式下会出现电感电流倒灌现象.若是反向电流过大,将会增加系统的导通损耗,降低芯片的效率.针对这一问题,设计了一款反向限流电路,该电路利用NMOS开关管的体效应二极管将负载的能量转移给输入电源,从而有效地限制了电流的倒灌.该反向限流电路基于0.5μm BCD工艺,在HSPICE上进行系统仿真.仿真结果证明,轻载时与不加反向限流电路的系统相比效率提高了2%.     

一种新型交错并联单输入高升压DC/DC变换器设计

针对传统的交错并联升压直流变换器输出电压低,开关器件电压应力高等不足之处,提出一种新型交错并联单输入高升压直流变换器.通过开关电感单元替代传统电感、变换器后级增加电容和二极管构成升压单元,提高变换器输出电压.所提DC/DC变换器中开关器件电压应力和二极管电压应力有效降低,升压增益有效提高.同时,该变换器具有元器件简单对...     

基于LPC2214的ZVZCS-PWM全桥变换控制器的研究

针对传统ZVZCS-PWMDC／DC全桥变换器在实现滞后桥臂开关管零电流开关过程中,存在着辅助谐振电路附加损耗较大,软开关实现方式复杂,功率开关管电压应力和电流应力高等缺点,介绍了一种新型次级箝位移相控制的ZVZCSPWMDC／DC全桥变换器。文中分析了该变换器实现软开关的原理,同时设计了变换器数字控制系统,控制器采用LPC2214型ARM芯片,并通过一台实验样机验证了这种软开关变换器相关理论的正确性以及该数字控制系统的可行性。     

采用分段式自适应PWM/PFM调制的Buck型DC-DC转换器设计北大核心

为了在轻重负载条件下获得更高的转换效率，采用分段式结构和导通电阻更小的NMOS作为输入级，并采用PWM/PFM双调制方式，设计了一种Buck型DC-DC转换器。为解决PWM/PFM调制信号切换问题，采用零电流检测方式进行切换。利用断续导通模式(DCM)和连续导通模式(CCM)下端NMOS管导通时电感电压的不同，检测下端NMOS在导通时电感电压大于零的周期。当电感电压大于零的周期大于2时，则处于DCM模式并自动采用PFM调制模式，关闭一部分功率管以减小开关频率和功率管寄生电容，优化轻载效率；反之则处于CCM模式并采用PWM调制。仿真结果表明，在负载电流10～1 000 mA范围内，该电路可以在两种调制模式平稳切换，在800 mA时峰值效率可提升到96%以上。     

Interpreting small signal behavior of the synchronous buck converter at light load

The pulse-width-modulation (PWM) buck converter with synchronous rectifiers operating at light load is usually modeled by its continuous conduction mode (CCM) model. However, the actual power-stage small-signal control-to-output response shows a different behavior from what the traditional CCM model predicts, specifically, more damping around the double-pole frequency, instead of more resonance. This paper presents a modified small-signal light-load model for a synchronous buck converter. The developed model accurately predicts the actual small-signal behavior of a PWM converter at light load. The derived averaged switch model for light load can also be used for the small-signal models of the other basic PWM converters operating in CCM at light load.     

Study and implementation of a low conduction loss zero-current resonant switch

Zero-current (ZC) resonant switches allow one to reduce the switching losses in high-frequency DC/DC switched mode power supplies. ZC resonant switches can be either unidirectional (half-wave) or bidirectional (full-wave). If a conventional power MOSFET is chosen to implement the ZC resonant switch, the turn-on of the slow intrinsic diode has to be avoided. This is usually done with a fast blocking diode, which is connected in series with the MOSFET. Furthermore, an antiparallel fast diode is added when a FW ZC resonant switch is required. The conduction losses are relevant in this implementation, owing to the threshold voltage and to the series resistances of the two diodes. In this paper, a low-conduction-loss FW ZC resonant switch has been proposed. Its implementation is based on a power MOSFET and a single antiparallel Schottky diode. The possibility of an implementation with a power MOSFET alone is also discussed. A control circuit suitable for the proposed ZC resonant switch has been described. The experimental results obtained from a ZCS-QR buck converter are discussed.<>     

A digitally controlled PWM/PSM dual-mode DC/DC converter

A digitally controlled pulse width modulation/pulse skip modulation(PWM/PSM) dual-mode buck DC/DC converter is proposed.Its operation mode can be automatically chosen as continuous conduction mode (CCM) or discontinuous conduction mode(DCM).The converter works in PSM at DCM and in 2 MHz PWM at CCM.Switching loss is reduced at a light load by skipping cycles.Thus high conversion efficiency is realized in a wide load current.The implementations of PWM control blocks,such as the ADC,the digital pulse width modulator(DPWM) and the loop compensator,and PSM control blocks are described in detail.The parameters of the loop compensator can be programmed for different external component values and switching frequencies, which is much more flexible than its analog rivals.The chip is manufactured in 0.13μm CMOS technology and the chip area is 1.21 mm~2.Experimental results show that the conversion efficiency is high,being 90%at 200 mA and 67%at 20 mA.Meanwhile,the measured load step response shows that the proposed dual-mode converter has good stability.     

A feedback loop regulated bootstrap driver circuit with improved drive capability for high voltage buck DC–DC converter

A novel bootstrap driver circuit applied to high voltage buck DC–DC converter is proposed. The gate driver voltage of the high side switch is regulated by a feedback loop to obtain accurate and stable bootstrapped voltage. The charging current of bootstrap capacitor is provided by the input power of the DC–DC converter directly instead of internal low voltage power source, so larger driver capability of the proposed circuit can be achieved. The bootstrap driver circuit starts to charge the bootstrap capacitor before the switch node SW drop to zero voltage at high-side switch off-time. Thus inadequate bootstrap voltage is avoided. The proposed circuit has been implemented in a high voltage buck DC–DC converter with 0.6 µm 40 V CDMOS process. The experimental results show that the bootstrap driver circuit provides 5 V stable bootstrap voltage with higher drive capability to drive high side switch. The proposed circuit is suitable for high voltage, large current buck DC–DC converter.     

峰值电流模式控制的非理想Buck变换器的建模

在 Ridley 峰值电流模式控制的 Buck 变换器模型的基础上,提出一个包含传导损耗的修正模型.运用平均开关建模法,建立非理想PWM开关的非线性大信号平均模型.包含全部寄生电阻和二极管的正向压降.围绕某一稳态工作点,扰动并线性化平均模型,导出非理想Buck变换器的功率级在连续工作模式下的直流模型和线性小信号模型.在此基础上.修正峰值电流模式控制部分的小信号模型参数.最终建立整个峰值电流模式控制的非理想Buck变换器的线性小信号模型.推导小信号动态的解析结果.给出修正的补偿斜坡信号斜率.在Simetrix/simplis开关电源软件包中进行了仿真分析,结果显示新模型能更准确地预测系统性能.     

Characterization and comparison of noise generation forquasi-resonant and pulsewidth-modulated converters

A buck converter with a given output filter is operated with pulse-width modulated and quasi-resonant switching schemes at the same nominal load and switching frequency. Electromagnetic interference generated by the natural switching action of the converter is examined by spectral analysis. Interference caused by excitation of parasitic elements is examined experimentally. Quasi-resonant converters are found to have a lower switching frequency harmonic bandwidth than the equivalent pulse-width modulated converter, even with switching frequency control. The most significant parasitic responses are the turn-on current and turn-off voltage of the catch diode and the gate current of the MOSFET. A significant decrease in radiated and conducted noise occurs when the gate drive voltage rise and fall times are increased, which is possible without loss of efficiency using quasi-resonant switching     

DCM,FSM,dead time and width controllers for a high frequency high efficiency buck DC-DC converter over a wide load range

This paper presents a width controller,a dead time controller,a discontinuous current mode(DCM) controller and a frequency skipping modulation(FSM) controller for a high frequency high efficiency buck DC-DC converter. To improve the efficiency over a wide load range,especially at high switching frequency,the dead time controller and width controller are applied to enhance the high load efficiency,while the DCM controller and FSM controller are proposed to increase the light load efficiency.The proposed D...     

An improved automotive power distribution system using nonlinearresonant switch converters

An improved automotive electrical system is proposed in which the generator is a high-efficiency AC machine connected to the battery by an AC-DC converter. The electrical loads are isolated from the battery by a DC-DC converter. This will allow gradual conversion to higher battery voltage, regulation of DC distribution voltage, and multiple distribution voltage levels. In the low-voltage, high-current, high-temperature environment of the automobile, in addition to packaging and thermal management, a major problem is the switching loss caused by leakage, package, and other parasitic inductances. The nonlinear resonant switch can remove this source of loss, achieving zero current switching without sacrificing conduction loss or MOSFET switch utilization. For the nonlinear resonant switch in a 1.5 kW load converter application, the upper limit is approximately 20 nH. Hence, device interconnections have low inductance, and MOSFET package inductances are taken into account. A low-voltage, high-current nonlinear resonant switch converter operating at 700 kHz an producing 600 W is described     

一种基于自适应峰值电流检测的模式切换电路北大核心

在降压转换器中，为了在不同的负载情况下获得高效率，常采用的方法是在重载时使用脉冲宽度调制(PWM),在轻载时使用脉冲频率调制(PFM),因此需要模式切换信号去控制整个降压转换器的工作状态，同时模式切换信号也可以用于自适应改变功率级电路中的功率管栅宽，减小功率管的栅极电容，提高整体电路的效率。文章设计了一个自适应峰值电流模式切换电路，用于产生模式切换信号，其原理是监控峰值电流的变化，产生峰值电压，将峰值电压与参考电压进行比较，得到模式切换信号，以决定降压转换器是采用PFM模式还是PWM模式。仿真结果表明，在负载电流0.5～500 mA范围内，该电路可以在两种调制模式之间平稳切换，其峰值效率可提升到94%以上。