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参数资料
| 型号: | KIT34712EPEVBE |
| 厂商: | Freescale Semiconductor |
| 文件页数: | 19/24页 |
| 文件大小: | 0K |
| 描述: | KIT EVAL BOARD 3A 1MHZ |
| 标准包装: | 1 |
| 系列: | * |
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�
�TYPICAL� APPLICATIONS�
�PROTECTION� AND� DIAGNOSTIC� FEATURES�
�stay� enhanced.� A� 0.1� ?� F� capacitor� is� a� good� value� for� this�
�bootstrap� element.�
�LAYOUT� GUIDELINES�
�The� layout� of� any� switching� regulator� requires� careful�
�consideration.� First,� there� are� high� di/dt� signals� present,� and�
�the� traces� carrying� these� signals� need� to� be� kept� as� short� and�
�as� wide� as� possible� to� minimize� the� trace� inductance,� and�
�therefore� reduce� the� voltage� spikes� they� can� create.� To� do�
�this,� an� understanding� of� the� major� current� carrying� loops� is�
�?�
�Equating� the� Pole� 2� to� 5� times� the� Crossover� Frequency� to�
�achieve� a� faster� response� and� a� proper� phase� margin,�
�important.� See� Figure 10� .� These� loops,� and� their� associated�
�components,� should� be� placed� in� such� a� way� as� to� minimize�
�the� loop� size� to� prevent� coupling� to� other� parts� of� the� circuit.�
�Also,� the� current� carrying� power� traces� and� their� associated�
�return� traces� should� run� adjacent� to� one� another,� to� minimize�
�the� amount� of� noise� coupling.� If� sensitive� traces� must� cross�
�the� current� carrying� traces,� they� should� be� made�
�perpendicular� to� one� another� to� reduce� field� interaction� .�
�1�
�2� ?� ?� R� F� ---------------------�
�5� ?� F� CROSS� =� F�
�P2� =�
�------------------------------------------�
�C� F� C� X�
�C� F� +� C� X�
�Second,� small� signal� components� which� connect� to�
�sensitive� nodes� need� consideration.� The� critical� small� signal�
�components� are� the� ones� associated� with� the� feedback�
�circuit.� The� high� impedance� input� of� the� error� amp� is�
�especially� sensitive� to� noise,� and� the� feedback� and�
�?�
�BOOTSTRAP� CAPACITOR�
�The� bootstrap� capacitor� is� needed� to� supply� the� gate�
�voltage� for� the� high� side� MOSFET.� This� N-Channel� MOSFET�
�needs� a� voltage� difference� between� its� gate� and� source� to� be�
�able� to� turn� on.� The� high� side� MOSFET� source� is� the� SW�
�node,� so� it� is� not� ground� and� it� is� floating� and� moving� in�
�voltage,� so� we� cannot� just� apply� a� voltage� directly� to� the� gate�
�of� the� high� side� that� is� referenced� to� ground,� we� need� a�
�voltage� referenced� to� the� SW� node.� That� is� why� the� bootstrap�
�capacitor� is� needed� for.� This� capacitor� charges� during� the�
�high� side� off� time,� since� the� low� side� will� be� on� during� that�
�time,� so� the� SW� node� and� the� bottom� of� the� bootstrap�
�capacitor� will� be� connected� to� ground� and� the� top� of� the�
�capacitor� will� be� connected� to� a� voltage� source,� so� the�
�capacitor� will� charge� up� to� that� voltage� source� (say� 5.0� V).�
�Now� when� the� low� side� MOSFET� switches� off� and� the� high�
�side� MOSFET� switches� on,� the� SW� nodes� rises� up� to� Vin,�
�and� the� voltage� on� the� boot� pin� will� be� Vcap� +� Vin.� So� the� gate�
�of� the� high� side� will� have� Vcap� across� it� and� it� will� be� able� to�
�compensation� components� should� be� placed� as� far� from� the�
�switch� node,� and� as� close� to� the� input� of� the� error� amplifier� as�
�possible.� Other� critical� small� signal� components� include� the�
�bypass� capacitors� for� VIN,� VREFIN,� and� VDDI.� Locate� the�
�bypass� capacitors� as� close� to� the� pin� as� possible.�
�The� use� of� a� multi-layer� printed� circuit� board� is�
�recommended.� Dedicate� one� layer,� usually� the� layer� under�
�the� top� layer,� as� a� ground� plane.� Make� all� critical� component�
�ground� connections� with� vias� to� this� layer.� Make� sure� that� the�
�power� ground,� PGND,� is� connected� directly� to� the� ground�
�plane� and� not� routed� through� the� thermal� pad� or� analog�
�ground.� Dedicate� another� layer� as� a� power� plane� and� split�
�this� plane� into� local� areas� for� common� voltage� nets.�
�The� IC� input� supply� (VIN)� should� be� connected� with� a�
�dedicated� trace� to� the� input� supply.� This� will� help� prevent�
�noise� from� the� Buck� Regulator's� power� input� (PVIN)� from�
�injecting� switching� noise� into� the� IC’s� analog� circuitry.�
�In� order� to� effectively� transfer� heat� from� the� top� layer� to� the�
�ground� plane� and� other� layers� of� the� printed� circuit� board,�
�thermal� vias� need� to� be� used� in� the� thermal� pad� design.� It� is�
�recommended� that� 5� to� 9� vias� be� spaced� evenly� and� have� a�
�finished� diameter� of� 0.3� mm.�
�34712�
�Analog� Integrated� Circuit� Device� Data� ?�
�Freescale� Semiconductor�
�19�
�相关PDF资料 |
PDF描述 |
|---|---|
| KIT34713EPEVBE | KIT EVAL BOARD 5A 1MHZ |
| KIT34716EPEVBE | KIT EVAL BOARD 1MHZ DUAL SW-MODE |
| KIT34717EPEVBE | KIT EVAL BOARD 5A 1.0MHZ |
| KS-1787-MG | SHELF SLIDING KEYBOARD ASSEMBLY |
| KS-1788 | SHELF SLIDING KEYBOARD ASSEMBLY |
相关代理商/技术参数 |
参数描述 |
|---|---|
| KIT34713EPEVBE | 功能描述:电源管理IC开发工具 5.0 A 1.0 MHZ FULLY INTEG RoHS:否 制造商:Maxim Integrated 产品:Evaluation Kits 类型:Battery Management 工具用于评估:MAX17710GB 输入电压: 输出电压:1.8 V |
| KIT34716EPEVBE | 功能描述:电源管理IC开发工具 1.0 MHZ DUAL SWITCH-MODE RoHS:否 制造商:Maxim Integrated 产品:Evaluation Kits 类型:Battery Management 工具用于评估:MAX17710GB 输入电压: 输出电压:1.8 V |
| KIT34717EPEVBE | 功能描述:电源管理IC开发工具 5.0 A 1.0MHZ FULLY INTEG RoHS:否 制造商:Maxim Integrated 产品:Evaluation Kits 类型:Battery Management 工具用于评估:MAX17710GB 输入电压: 输出电压:1.8 V |
| KIT34727FCEVBE | 功能描述:电源管理IC开发工具 600MA HIGH EFFICIENCY LO RoHS:否 制造商:Maxim Integrated 产品:Evaluation Kits 类型:Battery Management 工具用于评估:MAX17710GB 输入电压: 输出电压:1.8 V |
| KIT34825EPEVME | 功能描述:界面开发工具 MICRO USB INTERFACE IC RoHS:否 制造商:Bourns 产品:Evaluation Boards 类型:RS-485 工具用于评估:ADM3485E 接口类型:RS-485 工作电源电压:3.3 V |
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