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| 型号: | NCP5214EVB |
| 厂商: | ON Semiconductor |
| 文件页数: | 27/32页 |
| 文件大小: | 0K |
| 描述: | EVAL BOARD FOR NCP5214 |
| 产品变化通告: | Product Obsolescence 24/Jan/2011 |
| 设计资源: | NCP5214EVB BOM NCP5214EVB Gerber Files NCP5214EVB Schematic |
| 标准包装: | 1 |
| 主要目的: | DC/DC,步降 |
| 输出及类型: | 1,非隔离 |
| 输出电压: | 1.8V |
| 电流 - 输出: | 10A |
| 输入电压: | 5V,4.5 ~ 24 V |
| 稳压器拓扑结构: | 降压 |
| 频率 - 开关: | 100Hz ~ 75kHz |
| 板类型: | 完全填充 |
| 已供物品: | 板 |
| 已用 IC / 零件: | NCP5214 |
| 其它名称: | NCP5214EVBOS |
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�NCP5214�
�PCB� Layout� Guidelines�
�Cautious� PCB� layout� design� is� very� critical� to� ensure�
�high� performance� and� stable� operation� of� the� DDR� power�
�controller.� The� following� items� must� be� considered� when�
�preparing� PCB� layout:�
�1.� All� high?current� traces� must� be� kept� as� short� and�
�vias� with� 0.6� mm� hole?diameter� to� help� heat�
�dissipation� and� ensure� good� thermal� capability.� It�
�is� recommended� to� use� PCB� with� 1� oz� or� 2� oz�
�copper� foil.� The� thermal� pad� can� be� connected� to�
�either� PGND� ground� plane� or� AGND� ground�
�plane� but� not� both.�
�wide� as� possible� to� reduce� power� loss.�
�High?current� traces� are� the� trace� from� the� input�
�voltage� terminal� to� the� drain� of� the� high?side�
�MOSFET,� the� trace� from� the� source� of� the�
�high?side� MOSFET� to� the� inductor,� the� trace�
�from� inductor� to� the� VDDQ� output� terminal,� the�
�trace� from� the� input� ground� terminal� to� the�
�VDDQ� output� ground� terminal,� the� trace� from�
�VDDQ� output� to� VTTI� pin,� the� trace� from� VTT�
�pin� to� VTT� output� terminal,� and� the� trace� from�
�VTT� output� ground� terminal� to� the� VTTGND� pin.�
�Power� handling� and� heaksinking� of� high?current�
�traces� can� be� improved� by� also� routing� the� same�
�high?current� traces� in� the� other� layers� and� joined�
�together� with� multiple� vias.�
�2.� Power� components� which� include� the� input�
�capacitor,� high?side� MOSFET,� low?side�
�MOSFET� and� VDDQ� output� capacitor� of� the�
�buck� converter� section� must� be� positioned� close�
�together� to� minimize� the� current� loop.� The� input�
�capacitor� must� be� placed� close� to� the� drain� of� the�
�high?side� MOSFET� and� the� source� of� the�
�low?side� MOSFET.�
�3.� To� ensure� the� proper� function� of� the� device,�
�separated� ground� connections� should� be� used� for�
�different� parts� of� the� application� circuit� according�
�to� their� functions.� The� input� capacitor� ground,� the�
�low?side� MOSFET� source,� the� VDDQ� output�
�capacitor� ground,� the� VCCP� decoupling� capacitor�
�ground� should� be� connected� to� the� PGND.� The�
�trace� path� connecting� the� source� of� the� low?side�
�MOSFET� and� PGND� pin� should� be� minimized.�
�The� VTT� output� capacitor� ground� should� be�
�connected� to� the� VTTGND� first� with� a� short�
�trace,� it� is� then� connected� to� the� ground� plane� of�
�PGND.� The� VCCA� decoupling� capacitor� ground,�
�the� ground� of� the� VDDQ� feedback� resistor,� the�
�soft?start� capacitor� ground,� the� VTTREF� output�
�capacitor� ground� should� be� connected� to� the�
�AGND.� The� AGND� pin� is� then� connected� directly�
�through� a� sense� trace� to� the� remote� ground� sense�
�point� of� the� PGND,� which� is� usually� the� ground�
�of� the� local� bypass� capacitor� for� the� load.� Never�
�connect� the� AGND,� PGND� and� VTTGND�
�together� just� under� the� thermal� pad.�
�4.� The� thermal� pad� of� the� DFN?22� package� should�
�be� connected� to� the� ground� planes� in� the� internal�
�layer� and� bottom� layer� from� the� copper� pad� at� top�
�layer� underneath� the� package� through� six� to� eight�
�5.�
�6.�
�7.�
�8.�
�9.�
�10.�
�11.�
�12.�
�13.�
�14.�
�The� input� capacitor� ground� terminal,� the� VDDQ�
�output� capacitor� ground� terminal� and� the� source�
�of� the� low?side� MOSFET� must� be� connected� to�
�the� PGND� ground� plane� through� multiple� vias.�
�Sensitive� traces� like� trace� from� FBDDQ,� trace�
�from� COMP,� trace� from� OCDDQ,� trace� from�
�FBVTT� and� trace� from� VTTREF� should� be�
�avoided� from� the� high?voltage� switching� nodes�
�like� SWDDQ,� BOOST,� TGDDQ� and� BGDDQ.�
�Separate� sense� trace� should� be� used� to� connect�
�the� VDDQ� point� of� regulation,� which� is� usually�
�the� local� bypass� capacitor� for� load,� to� the�
�feedback� resistor� divider� to� ensure� accurate�
�voltage� sensing.� The� feedback� resistor� divider�
�should� be� place� close� to� the� FBDDQ� pin.�
�Separate� sense� trace� should� be� used� to� connect� the�
�VTT� point� of� regulation,� which� is� usually� the� local�
�bypass� capacitor� for� load,� to� the� FBVTT� pin.�
�Separate� sense� trace� should� be� used� to� connect�
�the� VDDQ� point� of� regulation� to� the� DDQREF�
�pin� to� ensure� that� the� reference� voltage� to� VTT� is�
�accurately� half� of� the� VDDQ� voltage.�
�The� traces� length� between� the� gate� driver� outputs�
�and� gates� of� the� MOSFETs� must� be� minimized� to�
�avoid� parasitic� impedance.�
�To� ensure� normal� function� of� the� device,� an� RC�
�filter� should� be� placed� close� to� the� VCCA� pin� and�
�a� decoupling� capacitor� should� be� placed� close� to�
�the� VCCP� pin.�
�The� copper� trace� area� of� the� switching� node� which�
�includes� the� source� of� the� high?side� MOSFET,�
�drain� of� the� low?side� MOSFET� and� high� voltage�
�side� of� the� inductor� should� be� minimized� by� using�
�short� wide� trace� to� reduce� EMI.�
�A� snubber� circuit� consists� of� a� 3.3� W� resistor� and�
�1.0� nF� capacitor� may� need� to� be� connected� across�
�the� switching� node� and� PGND� to� reduce� the�
�high?frequency� ringing� occurring� at� the� rising�
�edge� of� the� switching� waveform� to� obtain� more�
�accurate� inductor� current� limit� sensing� of� the�
�VDDQ� buck� converter.� However,� adding� this�
�snubber� circuit� will� slightly� reduce� the� conversion�
�efficiency.�
�VTTI� should� be� connected� to� VDDQ� output� with�
�wide� and� short� trace� if� VDDQ� is� used� as� the�
�sourcing� supply� for� VTT.� An� input� capacitor� of� at�
�least� 10� m� F� should� be� added� close� to� the� VTTI�
�pin� and� bypassed� to� VTTGND� if� external� voltage�
�supply� is� used� as� the� VTT� sourcing� supply.�
�http://onsemi.com�
�27�
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