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| 型号: | MAX8792ETD+T |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 24/28页 |
| 文件大小: | 0K |
| 描述: | IC PWM CTRLR STEP-DWN 14TDFN |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 1 |
| 应用: | PWM 控制器 |
| 输入电压: | 2 V ~ 26 V |
| 电源电压: | 4.5 V ~ 5.5 V |
| 电流 - 电源: | 700µA |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 14-WFDFN 裸露焊盘 |
| 供应商设备封装: | 14-TDFN-EP(3x3) |
| 包装: | 标准包装 |
| 其它名称: | MAX8792ETD+TDKR |
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�Single� Quick-PWM� Step-Down�
�Controller� with� Dynamic� REFIN�
�PD� (� N� H� Re� sistive� )� =� ?� OUT� ?� (� I� LOAD� )� 2� R� DS� (� ON� )�
�I� RMS� =� ?� LOAD� ?� V� OUT� (� V� IN� ?� V� OUT� )�
�When only using ceramic output capacitors, output�
�overshoot� (V� SOAR� )� typically� determines� the� minimum�
�output� capacitance� requirement.� Their� relatively� low�
�capacitance� value� may� allow� significant� output� over-�
�shoot� when� stepping� from� full-load� to� no-load� condi-�
�tions,� unless� designed� with� a� small� inductance� value�
�and� high� switching� frequency� to� minimize� the� energy�
�transferred� from� the� inductor� to� the� capacitor� during�
�load-step� recovery.�
�Unstable� operation� manifests� itself� in� two� related� but�
�distinctly� different� ways:� double� pulsing� and� feedback-�
�loop� instability.� Double� pulsing� occurs� due� to� noise� on�
�the� output� or� because� the� ESR� is� so� low� that� there� is�
�not� enough� voltage� ramp� in� the� output� voltage� signal.�
�This� “fools”� the� error� comparator� into� triggering� a� new�
�cycle� immediately� after� the� minimum� off-time� period�
�has� expired.� Double� pulsing� is� more� annoying� than�
�harmful,� resulting� in� nothing� worse� than� increased� out-�
�put� ripple.� However,� it� can� indicate� the� possible� pres-�
�ence� of� loop� instability� due� to� insufficient� ESR.� Loop�
�instability� can� result� in� oscillations� at� the� output� after�
�line� or� load� steps.� Such� perturbations� are� usually�
�damped,� but� can� cause� the� output� voltage� to� rise�
�above� or� fall� below� the� tolerance� limits.�
�The� easiest� method� for� checking� stability� is� to� apply� a�
�very� fast� zero-to-max� load� transient� and� carefully�
�observe� the� output� voltage-ripple� envelope� for� over-�
�shoot� and� ringing.� It� can� help� to� simultaneously� monitor�
�the� inductor� current� with� an� AC� current� probe.� Do� not�
�allow� more� than� one� cycle� of� ringing� after� the� initial�
�step-response� under/overshoot.�
�Input� Capacitor� Selection�
�The� input� capacitor� must� meet� the� ripple� current�
�requirement� (I� RMS� )� imposed� by� the� switching� currents.�
�The� I� RMS� requirements� may� be� determined� by� the� fol-�
�lowing� equation:�
�?� I� ?�
�?� V� IN� ?�
�The� worst-case� RMS� current� requirement� occurs� when�
�operating� with� V� IN� =� 2V� OUT� .� At� this� point,� the� above�
�equation� simplifies� to� I� RMS� =� 0.5� x� I� LOAD� .�
�For� most� applications,� nontantalum� chemistries� (ceramic,�
�aluminum,� or� OS-CON)� are� preferred� due� to� their� resis-�
�tance� to� inrush� surge� currents� typical� of� systems� with� a�
�mechanical� switch� or� connector� in� series� with� the� input.�
�If� the� Quick-PWM� controller� is� operated� as� the� second�
�stage� of� a� two-stage� power-conversion� system,� tanta-�
�lum� input� capacitors� are� acceptable.� In� either� configu-�
�ration,� choose� an� input� capacitor� that� exhibits� less� than�
�+10°C� temperature� rise� at� the� RMS� input� current� for�
�optimal� circuit� longevity.�
�Power-MOSFET� Selection�
�Most� of� the� following� MOSFET� guidelines� focus� on� the�
�challenge� of� obtaining� high� load-current� capability�
�when� using� high-voltage� (>� 20V)� AC� adapters.� Low-�
�current� applications� usually� require� less� attention.�
�The� high-side� MOSFET� (N� H� )� must� be� able� to� dissipate�
�the� resistive� losses� plus� the� switching� losses� at� both�
�V� IN(MIN)� and� V� IN(MAX)� .� Calculate� both� of� these� sums.�
�Ideally,� the� losses� at� V� IN(MIN)� should� be� roughly� equal� to�
�losses� at� V� IN(MAX)� ,� with� lower� losses� in� between.� If� the�
�losses� at� V� IN(MIN)� are� significantly� higher� than� the� losses�
�at� V� IN(MAX)� ,� consider� increasing� the� size� of� N� H� (reducing�
�R� DS(ON)� but� with� higher� C� GATE� ).� Conversely,� if� the� losses�
�at� V� IN(MAX)� are� significantly� higher� than� the� losses� at�
�V� IN(MIN)� ,� consider� reducing� the� size� of� N� H� (increasing�
�R� DS(ON)� to� lower� C� GATE� ).� If� V� IN� does� not� vary� over� a�
�wide� range,� the� minimum� power� dissipation� occurs�
�where� the� resistive� losses� equal� the� switching� losses.�
�Choose� a� low-side� MOSFET� that� has� the� lowest� possible�
�on-resistance� (R� DS(ON)� ),� comes� in� a� moderate-sized�
�package� (i.e.,� one� or� two� 8-pin� SOs,� DPAK,� or� D� 2� PAK),�
�and� is� reasonably� priced.� Make� sure� that� the� DL� gate�
�driver� can� supply� sufficient� current� to� support� the� gate�
�charge� and� the� current� injected� into� the� parasitic� gate-�
�to-drain� capacitor� caused� by� the� high-side� MOSFET�
�turning� on;� otherwise,� cross-conduction� problems� may�
�occur� (see� the� MOSFET� Gate� Drivers� section).�
�MOSFET� Power� Dissipation�
�Worst-case� conduction� losses� occur� at� the� duty� factor�
�extremes.� For� the� high-side� MOSFET� (N� H� ),� the� worst-�
�case� power� dissipation� due� to� resistance� occurs� at� the�
�minimum� input� voltage:�
�?� V� ?�
�?� V� IN� ?�
�Generally,� a� small� high-side� MOSFET� is� desired� to�
�reduce� switching� losses� at� high-input� voltages.�
�However,� the� R� DS(ON)� required� to� stay� within� package-�
�power� dissipation� often� limits� how� small� the� MOSFET�
�can� be.� Again,� the� optimum� occurs� when� the� switching�
�losses� equal� the� conduction� (R� DS(ON)� )� losses.� High-�
�side� switching� losses� do� not� usually� become� an� issue�
�until� the� input� is� greater� than� approximately� 15V.�
�Calculating� the� power� dissipation� in� the� high-side� MOS-�
�FET� (N� H� )� due� to� switching� losses� is� difficult� since� it� must�
�allow� for� difficult� quantifying� factors� that� influence� the�
�turn-on� and� turn-off� times.� These� factors� include� the�
�internal� gate� resistance,� gate� charge,� threshold� voltage,�
�source� inductance,� and� PCB� layout� characteristics.� The�
�following� switching-loss� calculation� provides� only� a� very�
�24�
�______________________________________________________________________________________�
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