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| 型号: | MAX17409GTI+T |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 28/32页 |
| 文件大小: | 0K |
| 描述: | IC CTRLR NVIDIA CPU 28-TQFN |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 2,500 |
| 系列: | Quick-PWM™ |
| 应用: | 处理器 |
| 电流 - 电源: | 1.5mA |
| 电源电压: | 4.5 V ~ 5.5 V |
| 工作温度: | -40°C ~ 105°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 28-WFQFN 裸露焊盘 |
| 供应商设备封装: | 28-TQFN-EP(4x4) |
| 包装: | 带卷 (TR) |
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�1-Phase� Quick-PWM� GPU� Controller�
�I� RMS� =� ?� LOAD� ?� V� OUT� (� V� IN� OUT� )�
�In applications that require DC droop, R� DROOP(AC)� is�
�the� same� as� the� DC� droop� setting� (R� DROOP(AC)� =�
�R� DROOP(DC)� ).� In� applications� that� do� not� require� DC�
�droop,� this� AC� signal� is� generated� by� capacitively� cou-�
�pling� the� inductor� ripple� current� signal� to� the� FB� pin.� In�
�this� case,� R� DROOP(AC)� =� R� SENSE� ,� where� R� SENSE� is� the�
�effective� sense� resistance� seen� at� the� CSP-CSN� pins.�
�In� Figure� 1,� C3� couples� the� inductor� ripple� current� signal�
�to� the� FB� pin.� C3� can� be� connected� to� the� CSN� pin� or� the�
�CSP� pin.� Connecting� to� the� CSN� pin� only� couples� the� out-�
�put� capacitor� ESR� to� the� FB� pin.� Connecting� to� the� CSP�
�pin� adds� the� R� SENSE� component� to� the� effective� resis-�
�tance� in� addition� to� the� output� capacitor� ESR.� This� is� use-�
�ful� for� applications� using� all� ceramic� output� capacitors.�
�Keep� the� C3� x� R� FB� time� constant� between� 3x� and� 5x� of�
�the� switching� period.� Practical� values� for� C3� range� from�
�0.1μF� to� 1μF.� Calculate� R� FB� after� selecting� C3.� Keeping�
�R� FB� below� 100� ?� minimizes� any� residual� DC� droop.�
�In� the� standard� application� circuit� (Figure� 1),� the� effec-�
�tive� resistance� for� stability� is� the� sum� of� the� ~� 2m� ?� DCR�
�and� the� 6m� ?� ESR� of� the� 470μF� output� capacitor.� The�
�ESR� zero� frequency� is� 42kHz,� well� within� the� require-�
�ment� of� f� SW� /� π� .�
�Ceramic� capacitors� have� a� high-ESR� zero� frequency,�
�but� applications� with� significant� voltage� positioning� can�
�take� advantage� of� their� size� and� low� ESR.� Do� not� put�
�high-value� ceramic� capacitors� directly� across� the� out-�
�put� without� verifying� that� the� circuit� contains� enough�
�voltage� positioning� and� series� PCB� resistance� to�
�ensure� stability.� When� only� using� ceramic� output�
�capacitors,� output� overshoot� (V� SOAR� )� typically� deter-�
�mines� the� minimum� output� capacitance� requirement.�
�Their� relatively� low� capacitance� value� can� cause� output�
�overshoot� when� stepping� from� full-load� to� no-load� con-�
�ditions,� unless� a� small� inductor� value� is� used� (high�
�switching� frequency)� to� minimize� the� energy� transferred�
�from� inductor� to� 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� output� ripple.�
�However,� it� can� indicate� the� possible� presence� 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� can� be� determined� by� the� fol-�
�lowing� equation:�
�?� I� ?�
�-� V�
�?� 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� (ceram-�
�ic,� aluminum,� or� OS-CON)� are� preferred� due� to� their�
�resistance� 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,�
�tantalum� input� capacitors� are� acceptable.� In� either� con-�
�figuration,� 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�
�28�
�______________________________________________________________________________________�
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