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参数资料
| 型号: | SP6134HVLEDEB |
| 厂商: | Exar Corporation |
| 文件页数: | 10/15页 |
| 文件大小: | 0K |
| 描述: | EVAL BOARD FOR SP6134HVLED |
| 标准包装: | 1 |
| 系列: | * |
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��S� P� 6� 1� 3� 4� H�
�H� i� g� h� V� o� l� t� a� g� e� ,� 6� 0� 0� k� H� z� S� y� n� c� h� r� o� n� o� u� s� P� W� M� S� t� e� p� D� o� w� n�
�C� o� n� t� r� o� l� l� e� r�
�P� CH� (� max� )� =� R� DS� (� ON� )� I� OUT� (� max� )� D�
�P� CL� (� max� )� =� R� DS� (� ON� )� I� OUT� (� max� )� (� 1� ?� D� )�
�T� J� (� max� )� =� T� A� (� max� )� +�
�MOSFET� S� ELECTION�
�The� losses� associated� with� MOSFETs� can� be�
�divided� into� conduction� and� switching� losses.�
�Conduction� losses� are� related� to� the� on�
�resistance� of� MOSFETs,� and� increase� with� the�
�load� current.� Switching� losses� occur� on� each�
�on/off� transition� when� the� MOSFETs�
�experience� both� high� current� and� voltage.�
�Since� the� bottom� MOSFET� switches� current�
�from/to� a� paralleled� diode� (either� its� own� body�
�diode� or� a� Schottky� diode),� the� voltage� across�
�the� MOSFET� is� no� more� than� 1V� during�
�switching� transition.� As� a� result,� its� switching�
�losses� are� negligible.� The� switching� losses� are�
�difficult� to� quantify� due� to� all� the� variables�
�affecting� turn� on/� off� time.� However,� the�
�following� equation� provides� an� approximation�
�on� the� switching� losses� associated� with� the� top�
�MOSFET� driven� by� SP6134H.�
�P� SH� (� max� )� =� 12� C� rss� V� IN� (� max� )� I� OUT� (� max� )� F� S�
�where�
�Crss� =� reverse� transfer� capacitance� of� the� top�
�MOSFET�
�Switching� losses� need� to� be� taken� into� account�
�for� high� switching� frequency,� since� they� are�
�directly� proportional� to� switching� frequency.�
�The� conduction� losses� associated� with� top� and�
�bottom� MOSFETs� are� determined� by:�
�2�
�2�
�where�
�PCH(max)� =� conduction� losses� of� the� high� side�
�MOSFET�
�PCL(max)� =� conduction� losses� of� the� low� side�
�lowering� the� RDS(ON)� of� the� MOSFETs� always�
�improves� efficiency� even� though� it� gives� rise�
�to� higher� switching� losses� due� to� increased�
�Crss.�
�Top� and� bottom� MOSFETs� experience� unequal�
�conduction� losses� if� their� on� time� is� unequal.�
�For� applications� running� at� large� or� small� duty�
�cycle,� it� makes� sense� to� use� different� top� and�
�bottom� MOSFETs.� Alternatively,� parallel�
�multiple� MOSFETs� to� conduct� large� duty�
�factor.�
�RDS(ON)� varies� greatly� with� the� gate� driver�
�voltage.� The� MOSFET� vendors� often� specify�
�RDS(ON)� on� multiple� gate� to� source� voltages�
�(VGS),� as� well� as� provide� typical� curve� of�
�RDS(ON)� versus� VGS.� For� 5V� input,� use� the�
�RDS(ON)� specified� at� 4.5V� VGS.� At� the� time� of�
�this� publication,� vendors,� such� as� Fairchild,�
�Siliconix� and� International� Rectifier,� have�
�started� to� specify� RDS(ON)� at� VGS� less� than�
�3V.� This� has� provided� necessary� data� for�
�designs� in� which� these� MOSFETs� are� driven�
�with� 3.3V� and� made� it� possible� to� use�
�SP6134H� in� 3.3V� only� applications.�
�Thermal� calculation� must� be� conducted� to�
�ensure� the� MOSFET� can� handle� the� maximum�
�load� current.� The� junction� temperature� of� the�
�MOSFET,� determined� as� follows,� must� stay�
�below� the� maximum� rating.�
�P� MOSFET� (� max� )�
�R� θ� JA�
�where�
�TA(max)� =� maximum� ambient� temperature�
�PMOSFET(max)� =� maximum� power� dissipation�
�of� the� MOSFET�
�MOSFET�
�R� Θ� JA� =� junction�
�to�
�ambient�
�thermal�
�RDS(ON)� =� drain� to� source� on� resistance.�
�The� total� power� losses� of� the� top� MOSFET� are�
�the� sum� of� switching� and� conduction� losses.�
�For� synchronous� buck� converters� of� efficiency�
�over� 90%,� allow� no� more� than� 4%� power�
�losses� for� high� or� low� side� MOSFETs.� For� input�
�voltages� of� 3.3V� and� 5V,� conduction� losses�
�often� dominate� switching� losses.� Therefore,�
�resistance.�
�R� Θ� JA� of� the� device� depends� greatly� on� the�
�board� layout,� as� well� as� device� package.�
�Significant� thermal� improvement� can� be�
�achieved� in� the� maximum� power� dissipation�
�through� the� proper� design� of� copper� mounting�
�pads� on� the� circuit� board.� For� example,� in� a�
�SO-8� package,� placing� two� 0.04� square� inches�
�?� 2008� Exar� Corporation�
�10/15�
�Rev.� 2.0.0�
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