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参数资料
| 型号: | FDMF6705 |
| 厂商: | Fairchild Semiconductor |
| 文件页数: | 16/19页 |
| 文件大小: | 0K |
| 描述: | MODULE DRMOS HI PERF HF POWER66 |
| 标准包装: | 3,000 |
| 系列: | XS™ DrMOS |
| 类型: | 高端/低端驱动器 |
| 输入类型: | PWM |
| 输出数: | 1 |
| 电流 - 峰值输出: | 40A |
| 电源电压: | 4.5 V ~ 5.5 V |
| 工作温度: | -40°C ~ 125°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 40-PowerTFQFN |
| 供应商设备封装: | 40-PQFN(6x6) |
| 包装: | 带卷 (TR) |
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�
�PCB� Layout� Guidelines�
�Figure� 30� provides� an� example� of� a� proper� layout� for� the�
�FDMF6705� and� critical� components.� All� of� the� high-�
�current� paths,� such� as� V� IN� ,� V� SWH� ,� V� OUT� ,� and� GND�
�copper,� should� be� short� and� wide� for� low� inductance�
�and� resistance.� This� technique� aids� in� achieving� a� more�
�stable� and� evenly� distributed� current� flow,� along� with�
�enhanced� heat� radiation� and� system� performance.�
�The� following� guidelines� are� recommendations� for� the�
�PCB� designer:�
�1.� Input� ceramic� bypass� capacitors� must� be� placed�
�close� to� the� VIN� and� PGND� pins.� This� helps�
�reduce� the� high-current� power� loop� inductance�
�and� the� input� current� ripple� induced� by� the� power�
�MOSFET� switching� operation.�
�2.� The� V� SWH� copper� trace� serves� two� purposes.� In�
�addition� to� being� the� high-frequency� current� path�
�from� the� DrMOS� package� to� the� output� inductor,� it�
�also� serves� as� a� heat� sink� for� the� low-side�
�MOSFET� in� the� DrMOS� package.� The� trace�
�should� be� short� and� wide� enough� to� present� a� low-�
�impedance� path� for� the� high-frequency,� high-�
�current� flow� between� the� DrMOS� and� inductor� to�
�minimize� losses� and� temperature� rise.� Note� that�
�the� VSWH� node� is� a� high� voltage� and� high-�
�frequency� switching� node� with� high� noise�
�potential.� Care� should� be� taken� to� minimize�
�coupling� to� adjacent� traces.� Since� this� copper�
�trace� also� acts� as� a� heat� sink� for� the� lower� FET,�
�balance� using� the� largest� area� possible� to� improve�
�DrMOS� cooling� while� maintaining� acceptable�
�noise� emission.�
�3.� An� output� inductor� should� be� located� close� to� the�
�FDMF6705� to� minimize� the� power� loss� due� to� the�
�VSWH� copper� trace.� Care� should� also� be� taken� so�
�the� inductor� dissipation� does� not� heat� the� DrMOS.�
�4.� PowerTrench?� MOSFETs� are� used� in� the� output�
�stage.� The� Power� MOSFETs� are� effective� at�
�minimizing� ringing� due� to� fast� switching.� In� most�
�cases,� no� VSWH� snubber� is� required.� If� a� snubber�
�is� used,� it� should� be� placed� close� to� the� VSWH� and�
�PGND� pins.� The� resistor� and� capacitor� need� to� be�
�of� proper� size� for� the� power� dissipation.�
�5.� VCIN,� VDRV,� and� BOOT� capacitors� should� be�
�placed� as� close� as� possible� to� the� VCIN� to� CGND,�
�VDRV� to� CGND,� and� BOOT� to� PHASE� pins� to�
�ensure� clean� and� stable� power.� Routing� width� and�
�length� should� be� considered� as� well.�
�6.� Include� a� trace� from� PHASE� to� VSWH� to� improve�
�noise� margin.� Keep� the� trace� as� short� as� possible.�
�7.� The� layout� should� include� a� placeholder� to� insert� a�
�small-value� series� boot� resistor� (R� BOOT� )� between�
�?� 2011� Fairchild� Semiconductor� Corporation�
�FDMF6705� ?� Rev.� 1.0.4�
�16�
�the� boot� capacitor� (C� BOOT� )� and� DrMOS� BOOT� pin.�
�The� BOOT-to-VSWH� loop� size,� including� R� BOOT�
�and� C� BOOT� ,� should� be� as� small� as� possible.� The�
�boot� resistor� may� be� required� when� operating� near�
�the� maximum� rated� V� IN� .� The� boot� resistor� is�
�effective� at� controlling� the� high-side� MOSFET� turn-�
�on� slew� rate� and� V� SHW� overshoot.� R� BOOT� can�
�improve� noise� operating� margin� in� synchronous�
�buck� designs� that� may� have� noise� issues� due� to�
�ground� bounce� or� high� positive� and� negative�
�VSWH� ringing.� However,� inserting� a� boot�
�resistance� lowers� the� DrMOS� efficiency.� Efficiency�
�versus� noise� trade-offs� must� be� considered.� R� BOOT�
�values� from� 0.5� ?� to� 3.0� ?� are� typically� effective� in�
�reducing� VSWH� overshoot� for� the� FDMF6705.�
�The� VIN� and� PGND� pins� handle� large� current�
�transients� with� frequency� components� greater� than�
�100MHz.� If� possible,� these� pins� should� be�
�connected� directly� to� the� VIN� and� board� GND�
�planes.� The� use� of� thermal� relief� traces� in� series�
�with� these� pins� is� discouraged� since� this� adds�
�inductance� to� the� power� path.� This� added�
�inductance� in� series� with� either� the� VIN� or� PGND�
�pin� degrades� system� noise� immunity� by� increasing�
�positive� and� negative� VSWH� ringing.�
�8.� CGND� pad� and� PGND� pins� should� be� connected� to�
�the� GND� plane� copper� with� multiple� vias� for� stable�
�grounding.� Poor� grounding� can� create� a� noise�
�transient� offset� voltage� level� between� CGND� and�
�PGND.� This� could� lead� to� faulty� operation� of� the�
�gate� driver� and� MOSFETs.�
�9.� Ringing� at� the� BOOT� pin� is� most� effectively�
�controlled� by� close� placement� of� the� boot�
�capacitor.� Do� not� add� an� additional� BOOT� to� the�
�PGND� capacitor.� This� may� lead� to� excess� current�
�flow� through� the� BOOT� diode.�
�10.� The� SMOD#� and� DISB#� pins� have� weak� internal�
�pull-up� and� pull-down� current� sources,�
�respectively.� These� pins� should� not� have� any�
�noise� filter� capacitors.� Do� not� to� float� these� pins�
�unless� absolutely� necessary.�
�11.� Use� multiple� vias� on� each� copper� area� to�
�interconnect� top,� inner,� and� bottom� layers� to� help�
�distribute� current� flow� and� heat� conduction.� Vias�
�should� be� relatively� large� and� of� reasonably� low�
�inductance.� Critical� high-frequency� components,�
�such� as� R� BOOT� ,� C� BOOT� ,� the� RC� snubber,� and�
�bypass� capacitors� should� be� located� as� close� to�
�the� respective� DrMOS� module� pins� as� possible�
�on� the� top� layer� of� the� PCB.� If� this� is� not� feasible,�
�they� should� be� connected� from� the� backside�
�through� a� network� of� low-inductance� vias.�
�www.fairchildsemi.com�
�相关PDF资料 |
PDF描述 |
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相关代理商/技术参数 |
参数描述 |
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| FDMF6705B | 功能描述:功率驱动器IC Xtra-Small Hi-Perf Hi-Freq DrMOS Module RoHS:否 制造商:Micrel 产品:MOSFET Gate Drivers 类型:Low Cost High or Low Side MOSFET Driver 上升时间: 下降时间: 电源电压-最大:30 V 电源电压-最小:2.75 V 电源电流: 最大功率耗散: 最大工作温度:+ 85 C 安装风格:SMD/SMT 封装 / 箱体:SOIC-8 封装:Tube |
| FDMF6705V | 功能描述:功率驱动器IC XS DrMOS; Hi-Freq Hi-Perf Module RoHS:否 制造商:Micrel 产品:MOSFET Gate Drivers 类型:Low Cost High or Low Side MOSFET Driver 上升时间: 下降时间: 电源电压-最大:30 V 电源电压-最小:2.75 V 电源电流: 最大功率耗散: 最大工作温度:+ 85 C 安装风格:SMD/SMT 封装 / 箱体:SOIC-8 封装:Tube |
| FDMF6706B | 功能描述:功率驱动器IC Xtra-Small Hi-Perf Hi-Freq DrMOS Module RoHS:否 制造商:Micrel 产品:MOSFET Gate Drivers 类型:Low Cost High or Low Side MOSFET Driver 上升时间: 下降时间: 电源电压-最大:30 V 电源电压-最小:2.75 V 电源电流: 最大功率耗散: 最大工作温度:+ 85 C 安装风格:SMD/SMT 封装 / 箱体:SOIC-8 封装:Tube |
| FDMF6706C | 功能描述:功率驱动器IC XS DrMOS; Hi-Freq Hi-Perf Module RoHS:否 制造商:Micrel 产品:MOSFET Gate Drivers 类型:Low Cost High or Low Side MOSFET Driver 上升时间: 下降时间: 电源电压-最大:30 V 电源电压-最小:2.75 V 电源电流: 最大功率耗散: 最大工作温度:+ 85 C 安装风格:SMD/SMT 封装 / 箱体:SOIC-8 封装:Tube |
| FDMF6707B | 功能描述:功率驱动器IC XS DrMOS; Hi-Freq Hi-Perf Module RoHS:否 制造商:Micrel 产品:MOSFET Gate Drivers 类型:Low Cost High or Low Side MOSFET Driver 上升时间: 下降时间: 电源电压-最大:30 V 电源电压-最小:2.75 V 电源电流: 最大功率耗散: 最大工作温度:+ 85 C 安装风格:SMD/SMT 封装 / 箱体:SOIC-8 封装:Tube |
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