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| 型号: | MAX1904EAI+T |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 24/33页 |
| 文件大小: | 0K |
| 描述: | IC CNTRLR PWR SPLY LN 28-SSOP |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 2,000 |
| 应用: | 控制器,笔记本电脑电源系统 |
| 输入电压: | 4.2 V ~ 30 V |
| 输出数: | 4 |
| 输出电压: | 2.5 V ~ 5 V |
| 工作温度: | 0°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 28-SSOP(0.209",5.30mm 宽) |
| 供应商设备封装: | 28-SSOP |
| 包装: | 带卷 (TR) |
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�500kHz� Multi-Output,� Low-Noise� Power-Supply�
�Controllers� for� Notebook� Computers�
�Use� a� Schottky� diode� with� a� DC� current� rating� equal� to�
�one� third� of� the� load� current.� The� Schottky� diode� ’� s� rated�
�Electrical� Characteristics� parameter,� 97%� guaranteed�
�over� temperature� at� f� =� 333kHz),� as� follows:�
�reverse� breakdown� voltage� must� be� at� least� equal� to�
�the� maximum� input� voltage,� preferably� with� a� 20%� der-�
�ating� factor.�
�V� SAG� =�
�2� � C� OUT�
�I� STEP� 2� � L�
�� (� V� IN� (� MIN� )� � D� MAX� -� V� OUT� )�
�Boost-Supply� Diode�
�A� signal� diode� such� as� a� 1N4148� works� well� in� most�
�applications.� If� the� input� voltage� can� go� below� +6V,� use�
�a� small� (20mA)� Schottky� diode� for� slightly� improved�
�efficiency� and� dropout� characteristics.� Don� ’� t� use� large�
�power� diodes,� such� as� 1N5817� or� 1N4001,� since� high�
�junction� capacitance� can� pump� up� V� L� to� excessive�
�voltages.�
�Rectifier� Diode� (Transformer� Secondary� Diode)�
�The� secondary� diode� in� coupled-inductor� applications�
�must� withstand� flyback� voltages� greater� than� 60V,�
�which� usually� rules� out� most� Schottky� rectifiers.�
�Common� silicon� rectifiers,� such� as� the� 1N4001,� are� also�
�prohibited� because� they� are� too� slow.� This� often� makes�
�fast� silicon� rectifiers� such� as� the� MURS120� the� only�
�choice.� The� flyback� voltage� across� the� rectifier� is� relat-�
�ed� to� the� V� IN� -� V� OUT� difference,� according� to� the� trans-�
�former� turns� ratio:�
�V� FLYBACK� =� V� SEC� +� (V� IN� -� V� OUT� )� ?� N�
�where:� N� =� the� transformer� turns� ratio� SEC/PRI�
�V� SEC� =� the� maximum� secondary� DC� output�
�voltage�
�V� OUT� =� the� primary� (main)� output� voltage�
�Subtract� the� main� output� voltage� (V� OUT� )� from� V� FLY-�
�BACK� in� this� equation� if� the� secondary� winding� is�
�returned� to� V� OUT� and� not� to� ground.� The� diode� reverse-�
�breakdown� rating� must� also� accommodate� any� ringing�
�due� to� leakage� inductance.� The� rectifier� diode� ’� s� current�
�rating� should� be� at� least� twice� the� DC� load� current� on�
�the� secondary� output.�
�Low-Voltage� Operation�
�Low� input� voltages� and� low� input-output� differential� volt-�
�ages� each� require� extra� care� in� their� design.� Low�
�absolute� input� voltages� can� cause� the� V� L� linear� regulator�
�to� enter� dropout� and� eventually� shut� itself� off.� Low� input�
�voltages� relative� to� the� output� (low� V� IN� -� V� OUT� differential)�
�can� cause� bad� load� regulation� in� multi-output� flyback�
�applications� (see� the� design� equations� in� the� Transformer�
�Design� section).� Also,� low� V� IN� -� V� OUT� differentials� can�
�also� cause� the� output� voltage� to� sag� when� the� load� cur-�
�rent� changes� abruptly.� The� amplitude� of� the� sag� is� a�
�function� of� inductor� value� and� maximum� duty� factor� (an�
�The� cure� for� low-voltage� sag� is� to� increase� the� output�
�capacitor� ’� s� value.� Take� a� 333kHz/6A� application� circuit�
�as� an� example,� at� V� IN� =� +5.5V,� V� OUT� =� +5V,� L� =� 6.7μH,�
�f� =� 333kHz,� I� STEP� =� 3A� (half-load� step),� a� total� capaci-�
�tance� of� 470μF� keeps� the� sag� less� than� 200mV.� The�
�capacitance� is� higher� than� that� shown� in� the� Typical�
�Application� Circuit� because� of� the� lower� input� voltage.�
�Note� that� only� the� capacitance� requirement� increases,�
�and� the� ESR� requirements� don� ’� t� change.� Therefore,� the�
�added� capacitance� can� be� supplied� by� a� low-cost� bulk�
�capacitor� in� parallel� with� the� normal� low-ESR� capacitor.�
�Applications� Information�
�Heavy-Load� Efficiency� Considerations�
�The� major� efficiency-loss� mechanisms� under� loads� are,�
�in� the� usual� order� of� importance:�
�?� P(I� 2� R)� =� I� 2� R� losses�
�?� P(tran)� =� transition� losses�
�?� P(gate)� =� gate-charge� losses�
�?� P(diode)� =� diode-conduction� losses�
�?� P(cap)� =� input� capacitor� ESR� losses�
�?� P(IC)� =� losses� due� to� the� IC� ’� s� operating� supply� current�
�Inductor� core� losses� are� fairly� low� at� heavy� loads�
�because� the� inductor� ’� s� AC� current� component� is� small.�
�Therefore,� they� aren� ’� t� accounted� for� in� this� analysis.�
�Ferrite� cores� are� preferred,� especially� at� 300kHz,� but�
�powdered� cores,� such� as� Kool-Mu,� can� work� well:�
�Efficiency� =� P� OUT� /P� IN� ?� 100%�
�=� P� OUT� /(P� OUT� +� P� TOTAL� )� ?� 100%�
�P� TOTAL� =� P(I� 2� R)� +� P(tran)� +� P(gate)� +� P(diode)� +�
�P(cap)� +� P(IC)�
�P� (I� 2� R)� =� I� LOAD� 2� x� (R� DC� +� R� DS(ON)� +� R� SENSE� )�
�where� RDC� is� the� DC� resistance� of� the� coil,� R� DS(ON)� is�
�the� MOSFET� on-resistance,� and� R� SENSE� is� the� current-�
�sense� resistor� value.� The� R� DS(ON)� term� assumes� identi-�
�cal� MOSFETs� for� the� high-side� and� low-side� switches:�
�because� they� time-share� the� inductor� current.� If� the�
�MOSFETs� aren� ’� t� identical,� their� losses� can� be� estimat-�
�ed� by� averaging� the� losses� according� to� duty� factor.�
�24�
�______________________________________________________________________________________�
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