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| 型号: | MAX17409GTI+T |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 10/32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�
�Pin� Description�
�PIN�
�1�
�2�
�3�
�4�
�5�
�NAME�
�IMON�
�GNDS/OFSP�
�FB�
�CSN�
�CSP�
�FUNCTION�
�Current� Monitor� Output.� The� MAX17409� IMON� output� sources� a� current� that� is� directly� proportional�
�to� the� current-sense� voltage� as� defined� by:�
�I� IMON� =� G� m(IMON)� x� (V� CSP� -� V� CSN� )�
�where� G� m(IMON)� =� 5mS� (typ).�
�The� IMON� current� is� unidirectional� (sources� current� out� of� IMON� only)� for� positive� current-sense�
�values.� For� negative� current-sense� voltages,� the� IMON� current� is� zero.�
�Connect� an� external� resistor� between� IMON� and� GNDS� to� create� the� desired� IMON� gain� based� on�
�the� following� equation:�
�R� IMON� =� 1.0V/(I� LOAD(MAX)� x� R� SENSE� x� G� m(IMON)� )�
�where� I� LOAD(MAX)� is� the� maximum� load� current,� and� R� SENSE� is� the� current-sense� voltage.�
�The� IMON� voltage� is� internally� clamped� to� 1.1V.� The� transconductance� amplifier� and� voltage�
�clamp� are� internally� compensated,� so� IMON� cannot� drive� large� external� capacitance� values.� To�
�filter� the� IMON� signal,� use� an� RC� filter� as� shown� in� Figure� 1.�
�Remote� Ground-Sense� Input/Positive� Offset� Input.� Connect� directly� to� the� ground-sense� pin� or�
�ground� connection� of� the� load.� GNDS� internally� connects� to� a� transconductance� amplifier� that�
�adjusts� the� feedback� voltage—compensating� for� voltage� drops� between� the� regulator’s� ground� and�
�the� processor� ’s� ground.�
�Remote-Sense� Feedback� Input� and� Voltage-Positioning� Transconductance� Amplifier� Output.�
�Connect� resistor� R� FB� between� FB� and� the� output� remote-sense� pin� (or� Kelvin-sensed� to� the� supply�
�pin� of� the� load)� for� best� accuracy� and� to� set� the� steady-state� droop� based� on� the� voltage-�
�positioning� gain� requirement:�
�R� FB� =� R� DROOP� /(R� SENSE� x� G� MD� )�
�where� R� DROOP_DC� is� the� desired� voltage-positioning� slope,� G� MD� =� 600μS� (typ),� and� R� SENSE� is� the�
�current-sense� resistance� with� respect� to� CSP� to� CSN� current-sense� inputs.� See� the� Current� Sense�
�section� for� details� on� designing� with� sense� resistors� or� inductor� DCR� sensing.�
�Shorting� FB� directly� to� the� output� effectively� disables� voltage� positioning,� but� impacts� the� stability�
�requirements.� Designs� that� disable� voltage� positioning� require� a� higher� minimum� output�
�capacitance� ESR� to� maintain� stability� (see� the� Output� Capacitor� Selection� section).�
�FB� enters� a� high-impedance� state� in� shutdown.�
�Negative� Inductor� Current-Sense� Input.� Connect� CSN� to� the� negative� terminal� of� the� inductor�
�current-sensing� resistor� or� directly� to� the� negative� terminal� of� the� inductor� if� the� lossless� DCR�
�sensing� method� is� used� (see� Figure� 3).�
�Positive� Inductor� Current-Sense� Input.� Connect� CSP� to� the� positive� terminal� of� the� inductor� current-�
�sensing� resistor� or� directly� to� the� positive� terminal� of� the� filtering� capacitor� used� when� the�
�lossless� DCR� sensing� method� is� used� (see� Figure� 3).�
�Pulse-Skipping� Control� Input.� The� SKIP� signal� indicates� the� power� usage� and� sets� the� operating�
�mode� of� the� MAX17409.� When� the� system� forces� SKIP� high,� the� MAX17409� immediately� enters�
�automatic� pulse-skipping� mode.� The� controller� returns� to� continuous� forced-PWM� mode� when� SKIP�
�is� pulled� low� and� the� output� is� in� regulation.� SKIP� determines� the� operating� mode� and� output-�
�voltage� transition� slew� rate� as� shown� in� the� truth� table� below:�
�6�
�SKIP�
�SKIP�
�0�
�1�
�Functionality�
�Normal� slew� rate,� forced-PWM� mode�
�Normal� slew� rate,� skip� mode�
�The� SKIP� state� is� ignored� during� soft-start� and� shutdown.� The� MAX17409� always� uses� pulse-�
�skipping� mode� during� startup� to� ensure� a� monotonic� power-up.� During� shutdown,� the� controller�
�always� uses� forced-PWM� mode� so� the� output� can� be� actively� discharged.�
�10�
�______________________________________________________________________________________�
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