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参数资料
| 型号: | LTC4008EGN-1#PBF |
| 厂商: | Linear Technology |
| 文件页数: | 16/24页 |
| 文件大小: | 0K |
| 描述: | IC BATT CHARGER CTRLR 4A 20SSOP |
| 标准包装: | 55 |
| 功能: | 充电管理 |
| 电池化学: | 多化学 |
| 电源电压: | 6 V ~ 28 V |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 20-SSOP(0.209",5.30mm 宽) |
| 供应商设备封装: | 20-SSOP |
| 包装: | 管件 |
| 产品目录页面: | 1341 (CN2011-ZH PDF) |
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�LTC4008�
�APPLICATIONS� INFORMATION�
�Selection� criteria� for� the� power� MOSFETs� include� the� “ON”�
�resistance� R� DS(ON)� ,� total� gate� capacitance� Q� G� ,� reverse�
�transfer� capacitance� C� RSS� ,� input� voltage� and� maximum�
�output� current.� The� charger� is� operating� in� continuous�
�mode� so� the� duty� cycles� for� the� top� and� bottom� MOSFETs�
�are� given� by:�
�Main� Switch� Duty� Cycle� =� V� OUT� /V� IN�
�Synchronous� Switch� Duty� Cycle� =� (V� IN� –� V� OUT� )/V� IN� .�
�The� MOSFET� power� dissipations� at� maximum� output�
�current� are� given� by:�
�PMAIN� =� V� OUT� /V� IN(IMAX)2� (1� +� δΔ� T)R� DS(ON)�
�+� k(V� IN� )� 2� (I� MAX� )(C� RSS� )(f� OSC� )�
�PSYNC� =� (V� IN� –� V� OUT� )/V� IN� (I� MAX� )� 2� (1� +� δΔ� T)R� DS(ON)�
�Where� δΔ� T� is� the� temperature� dependency� of� R� DS(ON)� and�
�k� is� a� constant� inversely� related� to� the� gate� drive� current.�
�Both� MOSFETs� have� I� 2� R� losses� while� the� PMAIN� equation�
�includes� an� additional� term� for� transition� losses,� which�
�are� highest� at� high� input� voltages.� For� V� IN� <� 20V� the� high�
�current� ef?ciency� generally� improves� with� larger� MOSFETs,�
�while� for� V� IN� >� 20V� the� transition� losses� rapidly� increase� to�
�the� point� that� the� use� of� a� higher� R� DS(ON)� device� with� lower�
�C� RSS� actually� provides� higher� ef?ciency.� The� synchronous�
�MOSFET� losses� are� greatest� at� high� input� voltage� or� during�
�a� short� circuit� when� the� duty� cycle� in� this� switch� in� nearly�
�100%.� The� term� (1� +� δΔ� T)� is� generally� given� for� a� MOSFET�
�in� the� form� of� a� normalized� R� DS(ON)� vs� temperature� curve,�
�but� δ� =� 0.005/°C� can� be� used� as� an� approximation� for� low�
�voltage� MOSFETs.� C� RSS� =� Q� GD� /� Δ� V� DS� is� usually� speci?ed�
�in� the� MOSFET� characteristics.� The� constant� k� =� 2� can� be�
�used� to� estimate� the� contributions� of� the� two� terms� in� the�
�main� switch� dissipation� equation.�
�If� the� charger� is� to� operate� in� low� dropout� mode� or� with�
�a� high� duty� cycle� greater� than� 85%,� then� the� topside� P-�
�channel� ef?ciency� generally� improves� with� a� larger� MOSFET.�
�Using� asymmetrical� MOSFETs� may� achieve� cost� savings�
�or� ef?ciency� gains.�
�The� Schottky� diode� D1,� shown� in� the� Typical� Application�
�on� the� back� page,� conducts� during� the� dead-time� between�
�the� conduction� of� the� two� power� MOSFETs.� This� prevents�
�the� body� diode� of� the� bottom� MOSFET� from� turning� on� and�
�storing� charge� during� the� dead-time,� which� could� cost� as�
�much� as� 1%� in� ef?ciency.� A� 1A� Schottky� is� generally� a� good�
�size� for� 4A� regulators� due� to� the� relatively� small� average�
�current.� Larger� diodes� can� result� in� additional� transition�
�losses� due� to� their� larger� junction� capacitance.�
�The� diode� may� be� omitted� if� the� ef?ciency� loss� can� be�
�tolerated.�
�Calculating� IC� Power� Dissipation�
�The� power� dissipation� of� the� LTC4008� is� dependent� upon�
�the� gate� charge� of� the� top� and� bottom� MOSFETs� (Q� G1� &�
�Q� G2� respectively)� The� gate� charge� is� determined� from� the�
�manufacturer’s� data� sheet� and� is� dependent� upon� both�
�the� gate� voltage� swing� and� the� drain� voltage� swing� of� the�
�MOSFET.� Use� 6V� for� the� gate� voltage� swing� and� V� DCIN� for�
�the� drain� voltage� swing.�
�PD� =� V� DCIN� ?� (f� OSC� (Q� G1� +� Q� G2� )� +� I� Q� )�
�Example:�
�V� DCIN� =� 19V,� f� OSC� =� 345kHz,� Q� G1� =� Q� G2� =� 15nC,�
�I� Q� =� 5mA�
�PD� =� 292mW�
�Adapter� Limiting�
�An� important� feature� of� the� LTC4008� is� the� ability� to� auto-�
�matically� adjust� charging� current� to� a� level� which� avoids�
�overloading� the� wall� adapter.� This� allows� the� product� to�
�operate� at� the� same� time� that� batteries� are� being� charged�
�without� complex� load� management� algorithms.� Addition-�
�ally,� batteries� will� automatically� be� charged� at� the� maximum�
�possible� rate� of� which� the� adapter� is� capable.�
�This� feature� is� created� by� sensing� total� adapter� output� cur-�
�rent� and� adjusting� charging� current� downward� if� a� preset�
�adapter� current� limit� is� exceeded.� True� analog� control� is�
�4008fb�
�16�
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