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参数资料
| 型号: | MAX1637EEE+T |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 15/20页 |
| 文件大小: | 0K |
| 描述: | IC REG CTRLR BUCK PWM CM 16-QSOP |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 2,500 |
| PWM 型: | 电流模式,混合 |
| 输出数: | 1 |
| 频率 - 最大: | 338kHz |
| 占空比: | 96% |
| 电源电压: | 3.15 V ~ 5.5 V |
| 降压: | 是 |
| 升压: | 无 |
| 回扫: | 无 |
| 反相: | 无 |
| 倍增器: | 无 |
| 除法器: | 无 |
| Cuk: | 无 |
| 隔离: | 无 |
| 工作温度: | -40°C ~ 85°C |
| 封装/外壳: | 16-SSOP(0.154",3.90mm 宽) |
| 包装: | 带卷 (TR) |
��
�
�Miniature,� Low-Voltage,�
�Precision� Step-Down� Controller�
�Inductor� Value�
�The� exact� inductor� value� is� not� critical� and� can� be�
�freely� adjusted� to� allow� trade-offs� among� size,� cost,�
�and� efficiency.� Lower� inductor� values� minimize� size�
�and� cost,� but� reduce� efficiency� due� to� higher� peak-�
�current� levels.� The� smallest� inductor� value� is� obtained�
�by� lowering� the� inductance� until� the� circuit� operates� at�
�the� border� between� continuous� and� discontinuous�
�mode.� Further� reducing� the� inductor� value� below� this�
�crossover� point� results� in� discontinuous-conduction�
�operation,� even� at� full� load.� This� helps� lower� output� filter�
�capacitance� requirements,� but� efficiency� suffers� under�
�these� conditions,� due� to� high� I� 2� R� losses.� On� the� other�
�hand,� higher� inductor� values� produce� greater� efficien-�
�cy,� but� also� result� in� resistive� losses� due� to� extra� wire�
�turns—a� consequence� that� eventually� overshadows� the�
�benefits� gained� from� lower� peak� current� levels.� High�
�inductor� values� can� also� affect� load-transient� response�
�(see� the� V� SAG� equation� in� the� Low-Voltage� Operation�
�section).� The� equations� in� this� section� are� for� continu-�
�ous-conduction� operation.�
�Three� key� inductor� parameters� must� be� specified:�
�inductance� value� (L),� peak� current� (I� PEAK� ),� and� DC�
�resistance� (R� DC� ).� The� following� equation� includes� a�
�constant,� LIR,� which� is� the� ratio� of� inductor� peak-to-�
�peak� AC� current� to� DC� load� current.� A� higher� LIR� value�
�allows� lower� inductance,� but� results� in� higher� losses�
�and� ripple.� A� good� compromise� is� a� 30%� ripple-current�
�to� load-current� ratio� (LIR� =� 0.3),� which� corresponds� to� a�
�peak� inductor� current� 1.15� times� higher� than� the� DC�
�load� current.�
�L� =� V� OUT� (V� IN(MAX)� -� V� OUT� )� /� (V� IN(MIN)� x� ?� x� I� OUT� x�
�LIR)�
�where� ?� =� switching� frequency� (normally� 200kHz� or�
�300kHz),� and� I� OUT� =� maximum� DC� load� current.�
�The� peak� current� can� be� calculated� as� follows:�
�I� PEAK� =� I� LOAD� +� [V� OUT� (V� IN(MAX)� -� V� OUT� )� /� (2� x� ?� x� L�
�x� V� IN(MAX)� )]�
�The� inductor’s� DC� resistance� should� be� low� enough�
�that� R� DC� x� I� PEAK� <� 100mV,� as� it� is� a� key� parameter� for�
�efficiency� performance.� If� a� standard,� off-the-shelf�
�inductor� is� not� available,� choose� a� core� with� an� LI� 2� rat-�
�ing� greater� than� L� x� IPEAK� 2� and� wind� it� with� the� largest�
�diameter� wire� that� fits� the� winding� area.� For� 300kHz�
�applications,� ferrite-core� material� is� strongly� preferred;�
�for� 200kHz� applications,� Kool-Mu� ?� (aluminum� alloy)� or�
�even� powdered� iron� is� acceptable.� If� light-load� efficien-�
�cy� is� unimportant� (in� desktop� PC� applications,� for�
�example),� then� low-permeability� iron-powder� cores� can�
�Kool-Mu� is� a� trademark� of� Magnetics,� Inc.�
�be� acceptable,� even� at� 300kHz.� For� high-current� appli-�
�cations,� shielded-core� geometries� (such� as� toroidal� or�
�pot� core)� help� keep� noise,� EMI,� and� switching-�
�waveform� jitter� low.�
�Current-Sense� Resistor� Value�
�The� current-sense� resistor� value� is� calculated� accord-�
�ing� to� the� worst-case,� low-current� limit� threshold� volt-�
�age� (from� the� Electrical� Characteristics� )� and� the� peak�
�inductor� current:�
�R� SENSE� =� 80mV� /� I� PEAK�
�Use� I� PEAK� from� the� second� equation� in� the� Inductor�
�Value� section.� Use� the� calculated� value� of� R� SENSE� to�
�size� the� MOSFET� switches� and� specify� inductor� satura-�
�tion-current� ratings� according� to� the� worst-case� high-�
�current-limit� threshold� voltage:�
�I� PEAK� =� 120mV� /� R� SENSE�
�Low-inductance� resistors,� such� as� surface-mount� metal�
�film,� are� recommended.�
�Input� Capacitor� Value�
�Connect� low-ESR� bulk� capacitors� directly� to� the� drain�
�on� the� high-side� MOSFET.� The� bulk� input� filter� capaci-�
�tor� is� usually� selected� according� to� input� ripple� current�
�requirements� and� voltage� rating,� rather� than� capacitor�
�value.� Electrolytic� capacitors� with� low� enough� equiva-�
�lent� series� resistance� (ESR)� to� meet� the� ripple-current�
�requirement� invariably� have� sufficient� capacitance� val-�
�ues.� Aluminum� electrolytic� capacitors,� such� as� Sanyo�
�OS-CON� or� Nichicon� PL,� are� superior� to� tantalum�
�types,� which� risk� power-up� surge-current� failure,� espe-�
�cially� when� connecting� to� robust� AC� adapters� or� low-�
�impedance� batteries.� RMS� input� ripple� current� (I� RMS� )� is�
�determined� by� the� input� voltage� and� load� current,� with�
�the� worst� case� occurring� at� V� IN� =� 2� x� V� OUT� .� Therefore,�
�when� V� IN� is� 2� x� V� OUT� :�
�I� RMS� =� I� LOAD� /� 2�
�V� CC� and� V� GG� should� be� isolated� from� each� other� with� a�
�20� Ω� resistor� and� bypassed� to� ground� independently.�
�Place� a� 0.1μF� capacitor� between� V� CC� and� GND,� as�
�close� to� the� supply� pin� as� possible.� A� 4.7μF� capacitor�
�is� recommended� between� V� GG� and� PGND.�
�Output� Filter� Capacitor� Value�
�The� output� filter� capacitor� values� are� generally� deter-�
�mined� by� the� ESR� and� voltage-rating� requirements,�
�rather� than� by� actual� capacitance� requirements� for� loop�
�stability.� In� other� words,� the� low-ESR� electrolytic� capac-�
�itor� that� meets� the� ESR� requirement� usually� has� more�
�output� capacitance� than� is� required� for� AC� stability.�
�______________________________________________________________________________________�
�15�
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