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| 型号: | KIT33701DWBEVB |
| 厂商: | Freescale Semiconductor |
| 文件页数: | 32/39页 |
| 文件大小: | 0K |
| 描述: | KIT FOR 33701 POWER SUPPLY |
| 标准包装: | 1 |
| 主要目的: | DC/DC,LDO 步降 |
| 输出及类型: | 2,非隔离 |
| 输入电压: | 2.8 ~ 6V |
| 稳压器拓扑结构: | 降压 |
| 频率 - 开关: | 300kHz |
| 板类型: | 完全填充 |
| 已供物品: | 板,软件 |
| 已用 IC / 零件: | MC34701 |
| 相关产品: | MC34701EKR2CT-ND - IC POWER SUPPLY MCU 1A 32-SOIC MC34701EKR2TR-ND - IC POWER SUPPLY MCU 1A 32-SOIC MC34701EK-ND - IC POWER SUPPLY MCU 1A 32-SOIC |
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�TYPICAL� APPLICATIONS�
�P� D� ?� Q� ?� max� ?� -----------------------------------------------------------�
�Linear� Regulator� Current� Limit�
�As� described� in� the� Linear� Regulator� Functional�
�Description� section,� the� current� limit� of� the� linear� regulator�
�can� be� adjusted� by� means� of� an� external� current� sense�
�resistor� R� S� .� The� voltage� drop� caused� by� the� regulator� output�
�current� flowing� through� the� current� sense� resistor� R� S� is�
�sensed� between� the� LDO� and� the� CS� pins.� When� the� sensed�
�voltage� exceeds� 50mV� (typical),� the� current� limit� timer� starts�
�to� time� out� while� the� control� circuit� limits� the� output� current.� If�
�the� over-current� condition� lasts� for� more� than� 10ms,� the� linear�
�regulator� is� shut� off� and� turned� on� again� after� 100ms.� This�
�type� of� operation� provides� equivalent� protection� to� the� analog�
�“current� foldback”� operation.�
�It� is� important� to� keep� in� mind� that� the� amount� of� capacitive�
�load� which� can� be� supplied� by� the� by� the� linear� regulator� is�
�limited� by� the� setting� of� the� LDO� current� limit.� During� the�
�power-up� period,� the� linear� regulator� operates� in� the� current�
�limit,� supplying� the� current� into� the� load� of� the� LDO,� which�
�includes� all� the� capacitors� connected� to� the� regulator� output.�
�If� the� total� amount� load� is� so� large� that� the� regulator� could� not�
�reach� its� regulation� voltage� in� 10ms� during� the� power-up,� it�
�turns� off� and� tries� to� power� up� again� after� 100ms.� This�
�situation� may� lead� to� the� power-up� oscillations.�
�Linear� Regulator� External� MOSFET�
�The� linear� regulator� uses� an� external� N-channel� power�
�MOSFET� to� provide� a� pass� element� for� the� power� path.� The�
�selection� of� the� proper� type� of� the� external� power� MOSFET� is�
�critical� for� optimum� performance� and� safe� operation� of� the�
�linear� regulator.�
�The� power� MOSFET’s� threshold� voltage,� R� DS(on)� ,� gate�
�charge,� capacitances� and� transconductance� are� important�
�parameters� for� the� stable� operation� of� the� linear� regulator�
�while� the� package� of� the� power� MOSFET� determines� the�
�maximum� power� dissipation,� and� hence� the� maximum� output�
�current� for� the� required� input-to-output� voltage� drop.� The�
�power� dissipation� of� the� external� MOSFET� can� be� calculated�
�from� the� simple� formula:�
�P� D� ?� Q� ?� =� I� LDO� ?� ?� V� IN� –� V� LDO� ?�
�Where� P� D(Q)� is� the� power� MOSFET� power� dissipation� ?�
�VIN� is� the� LDO� input� voltage,� ?�
�VLDO� is� the� LDO� output� voltage,� ?�
�ILDO� is� the� LDO� output� load� current.�
�Table 10� shows� the� recommended� power� MOSFET� types�
�for� the� 34701� linear� regulator,� their� typical� power� dissipation,�
�and� thermal� resistance� junction-to-case.�
�Table� 10.� Recommended� Power� MOSFETs�
�NOTE� :� Freescale� does� not� assume� liability,� endorse,� or� warrant�
�components� from� external� manufacturers� referenced� in� figures�
�or� tables.� Although� Freescale� offers� component�
�recommendations,� it� is� the� customer’s� responsibility� to� validate�
�their� application.�
�*When� mounted� to� an� FR4� using� 0.5� sq.in.� drain� pad� size�
�The� maximum� power� dissipation� is� limited� by� the�
�maximum� operating� junction� temperature� T� Jmax� .� The�
�allowed� power� dissipation� in� the� given� application� can� be�
�calculated� from� the� following� expression:�
�T� Jmax� –� T� A�
�R� thJC� +� R� thCB� +� R� thBA�
�Where� P� D(Q)max� is� the� power� MOSFET� maximum�
�allowed� dissipation,� ?�
�T� Jmax� is� the� power� MOSFET� maximum� operating�
�junction� temperature,� ?�
�T� A� is� the� ambient� temperature,� ?�
�R� thJC� is� the� power� MOSFET� thermal� resistance�
�junction-to-case,� ?�
�R� thCB� is� the� thermal� resistance� case-to-board,� ?�
�R� thBA� is� the� thermal� resistance� board-to-ambient� of�
�the� PC� board.�
�PCB� Layout� Considerations�
�As� with� any� power� application,� the� proper� PCB� layout�
�plays� a� critical� role� in� the� overall� power� regulator�
�performance.� While� good� careful� printed� circuit� board� layout�
�significantly� improves� regulation� parameters� and�
�electromagnetic� compatibility� (EMC)� performance� of� the�
�switching� regulator,� poor� layout� practices� can� lead� not� only� to�
�significant� degradation� of� regulation� and� EMC� parameters,�
�but� even� to� total� dysfunction� of� the� whole� regulator� IC.�
�Extreme� care� should� be� taken� when� laying� out� the� ground�
�of� the� regulator� circuit.� In� order� to� avoid� any� inductive� or�
�capacitive� coupling� of� the� switching� regulator� noise� into� the�
�sensitive� analog� control� circuits,� the� noisy� power� ground� and�
�the� clean� quiet� signal� ground� should� be� well� separated� on� the�
�printed� circuit� board,� and� connected� only� at� one� connection�
�point.� The� power� routing� should� be� made� by� heavy� traces� or�
�areas� of� copper.� The� power� path� and� its� return� should� be�
�placed,� if� possible,� atop� each� other� on� the� different� layers� or�
�opposite� sides� of� the� PC� board.� The� switching� regulator� input�
�and� output� capacitors� should� be� physically� placed� very� close�
�to� the� power� pins� (VIN2,� SW,� PGND)� of� the� 34701� switching�
�regulator;� and� their� ground� pins,� together� with� the� 34701�
�power� ground� pins� (PGND),� should� be� connected� by� a� single�
�island� of� the� power� ground� copper� to� create� the� “single-point”�
�grounding.� Figure 32� illustrates� the� 34701� switching� regulator�
�grounding� concept.� The� bootstrap� capacitor� C� b� should� be�
�tightly� connected� to� the� integrated� circuit� as� well.�
�Part� No.�
�IRL2703S�
�MTD20N03HDL�
�Package�
�D2PAK�
�DPAK�
�Typ.� P� D�
�2.0W�
�1.75W*�
�R� thJ-C�
�3.3°C/W�
�1.67°C/W�
�34701�
�Analog� Integrated� Circuit� Device� Data� ?�
�32�
�Freescale� Semiconductor�
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