参数资料
| 型号: | NCP1605LCDTVGEVB |
| 厂商: | ON Semiconductor |
| 文件页数: | 12/30页 |
| 文件大小: | 0K |
| 描述: | BOARD EVAL NCP1605/1396 |
| 设计资源: | NCP1605LCDTVGEVB Schematic NCP1605LCDTVGEVB Gerber Files NCP1605LCDTVGEVB Bill of Materials |
| 标准包装: | 1 |
| 系列: | * |
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�NCP1027�
�Figure� 25.� A� typical� startup� sequence� showing� the� V� CC� capacitor�
�voltage� evolution� versus� time.�
�Suppose� our� power� supply� takes� 10� ms� (t� startup� )� to� bring�
�the� output� voltage� to� its� target� value.� We� know� that� the�
�switcher� consumption� is� around� 2.0� mA� (I� CC1� ).� Therefore,�
�we� can� calculate� the� amount� of� capacitance� we� need,� to�
�hold� V� CC� above� 7.5� V� at� least� for� 10� ms� while� delivering�
�2.0� mA:�
�C� w�
�ICC1tstartup�
�D� VCC�
�or,� by� replacing� with� the� above� values,�
�C� w� 2m� ·� 10� m� w� 20� m� F� then� select� a� 33� m� F� for� the� V� CC�
�1�
�capacitor.�
�Fault� Condition� –� Short-Circuit� on� V� CC�
�In� some� fault� situations,� a� short-circuit� can� purposely�
�occur� between� V� CC� and� GND.� In� high� line� conditions�
�(V� HV� =� 370� V� DC� )� the� current� delivered� by� the� startup�
�device� will� seriously� increase� the� junction� temperature.� For�
�instance,� since� IC1� equals� 3.0� mA� (the� min� corresponds� to�
�Figure� 26.� The� startup� source� now� features� a�
�dual-level� startup� current.�
�the� highest� T� J� ),� the� device� would� dissipate� 370� 3m=�
�1.1� W.� To� avoid� this� situation,� the� controller� includes� a�
�novel� circuitry� made� of� two� startup� levels,� IC1� and� IC2.� At�
�C�
�The� first� startup� period� is� calculated� by� the� formula�
�V=I� t,� which� implies� a� 33� m� 1.3/650� m� =� 66� ms�
�powerup,� as� long� as� V� CC� is� below� a� 1.3� V� level,� the� source�
�delivers� IC1� (around� 650� m� A� typical),� then,� when� V� CC�
�reaches� 1.3� V,� the� source� smoothly� transitions� to� IC2� and�
�delivers� its� nominal� value.� As� a� result,� in� case� of�
�short-circuit� between� V� CC� and� GND,� the� power� dissipation�
�will� drop� to� 370� 650� m� =� 240� mW.� Figure� 26� portrays�
�this� particular� behavior.�
�startup� time� for� the� first� sequence� (t� 1� ).� The� second�
�sequence� (t� 2� )� is� obtained� by� toggling� the� source� to� 4.0� mA�
�with� a� delta� V� of� VCC� ON� –� VCCth� =� 8.5� –� 1.5� =� 7.0� V,�
�which� finally� leads� to� a� second� startup� time� of�
�7� 33� m� /6.0� m� =� 39� ms.� The� total� startup� time� becomes�
�66� m� +� 39� m� =� 105� ms� as� a� typical� value.� Please� note� that�
�this� calculation� is� approximated� by� the� presence� of� the� knee�
�in� the� vicinity� of� the� transition.�
�http://onsemi.com�
�12�
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