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参数资料
| 型号: | NCP5424DG |
| 厂商: | ON Semiconductor |
| 文件页数: | 15/18页 |
| 文件大小: | 0K |
| 描述: | IC REG CTRLR BUCK PWM 16-SOIC |
| 产品变化通告: | Product Obsolescence 21/Jan/2010 |
| 标准包装: | 48 |
| PWM 型: | 电流/电压模式,V²? |
| 输出数: | 1 |
| 频率 - 最大: | 750kHz |
| 占空比: | 100% |
| 电源电压: | 10.8 V ~ 13.2 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: | 0°C ~ 70°C |
| 封装/外壳: | 16-SOIC(0.154",3.90mm 宽) |
| 包装: | 管件 |
��
�
�NCP5424�
�capacitor� on� the� Comp1� pin� and� a� 0.01� m� F� capacitor� on� the�
�Comp2� pin� in� suggested.�
�Selecting� Current� Sharing� Current� Limit�
�In� a� two?phase� single� output� application,� there� are� two�
�different� current� limit� options.� The� Master� (Controller� One)�
�current� limit� can� be� set� equal� to� the� Slave� (Controller� Two)�
�which� brings� both� controllers� into� Hiccup� Mode� during� an�
�overcurrent� condition.� The� second� option� is� to� set� Slave�
�current� limit� lower� than� that� of� the� Master,� which� limits� the�
�Slave’s� input� power� when� its� limit� is� reached,� while� the�
�output� voltage� remains� in� regulation.� Both� Master� and� Slave�
�will� go� into� hiccup� mode� if� the� Master� ’s� limit� is� reached.�
�During� Cycle?By?Cycle� current� limit,� the� Slave’s� operating�
�frequency� will� decrease� in� half,� due� to� pulse� skipping,�
�resulting� in� phase� overlap.� This� overlap� will� increase� the�
�output� voltage� ripple.�
�Exceeding� 70� mV� between� the� IS+� and� IS?� pins� trips� the�
�current� limits.� A� divided� down� V� out� signal� is� used� to� generate�
�the� IS?� reference,� and� inductor� sensing� of� the� controllers�
�output� chokes� provide� the� output� current� information� to�
�IS+X� pin.� The� inductor� sensing� is� achieved� by� placing� a�
�series� RC� in� parallel� with� the� output� choke.� With� the� RC� time�
�constant� selected� to� equal� the� L/R� L� time� constant,� the�
�voltage� across� the� capacitor� will� be� equal� to� the� voltage� drop�
�across� the� internal� resistance� of� the� inductor.�
�The� resistance� of� the� output� choke� (LSR)� must� be� known�
�to� calculate� the� overcurrent� trip� point.� The� voltage� drop�
�across� the� inductor� at� overcurrent� is� calculated� as� follows:�
�where:�
�V� out� =� Output� regulated� voltage.�
�V� os� =� Offset� voltage,� example� above� was� 20� mV.�
�R4� =� Chosen� value,� 10� K� W� is� a� good� choice.�
�If� V� os� is� larger� than� 70� mV,� then� the� current� signal� from� the�
�output� chokes� must� be� divided� down.� For� example,� if� the�
�inductor� ’s� LSR� is� equal� to� 8.0� m� W� and� the� current� limit� is�
�15� A,� then� the� current� signal� is� 120� mV,� which� is� almost�
�twice� the� comparator� ’s� offset� (70� mV).� This� signal� can� be�
�divided� down� by� adding� a� resistor� (R1)� in� parallel� with� the�
�capacitor� (C6)� in� the� inductor� sensing� network,� see� Figure� 1.�
�The� divider� R1� and� R2� can� be� set� to� equal� value� to� divide� the�
�current� signal� in� half� and� equation� (3)� should� be� used� to�
�select� the� proper� voltage� divider.� Notice� that� the� divider� R1�
�and� R2,� divides� down� the� voltage� applied� to� the� capacitor�
�C� RC� by� a� factor� of� 2.� This� divides� the� voltage� across� the�
�output� inductor� ’s� LSR� by� a� factor� of� two� and� results� in� twice�
�the� current� limit.� This� scaling� technique� is� another� way� the�
�current� limit� may� be� set� so� that� virtually� any� current� limit�
�may� be� obtained.�
�To� ensure� accuracy,� the� equivalent� parallel� resistance� of�
�R1� and� R2� should� be� greater� or� equal� to� the� value� R� RC� ,� the�
�resistance� value� calculated� from� equation� (2).� If� Hiccup�
�Mode� is� used,� then� both� sensing� network� values� must� be�
�equal.�
�If� Cycle?by?Cycle� is� desired,� then� equation� (1),� (2)� and�
�(3)� should� be� used� to� select� the� Slave’s� inductor� sensing�
�network� for� the� desired� current� limit� and� equation� (4)� should�
�be� used� to� raise� the� Master� ’s� current� limit,� Hiccup� Mode,�
�VL� +� RL� ·� Iout�
�(eq.� 1)�
�above� the� Slave’s� limit.�
�where:�
�V� L� =� Voltage� drop� across� the� inductor,�
�R2� +�
�R1(1� *� Ratio)�
�Ratio�
�(eq.� 4)�
�Ratio� +� slave.limit� ,� Master� ’s� and� Slave’s� current�
�R� L� =� LSR� of� the� inductor,�
�I� out� =� Output� current� trip� point� for� one� phase.�
�For� Hiccup� Mode� only,� both� sensing� networks� should� have�
�the� identical� values.�
�If� the� inductor� selected� has� a� 5.0� m� W� LSR� and� the� current�
�limit� is� 10� A� through� one� of� the� phases,� then� the� analog�
�signal� will� be� 50� mV.� Since� this� value� is� less� than� 70� mV,�
�then� the� IS?� divider,� R3� and� R4� in� Figure� 1,� must� scale� down�
�where:�
�R1� =� Chosen� value,� 10� K� W� is� recommended,�
�I�
�Imaster.limit�
�limit� ratio.�
�To� ensure� greater� accuracy,� the� equivalent� parallel�
�resistance� of� R1� and� R2� should� be� greater� or� equal� to� the�
�value� R� RC� ,� value� calculated� from� equation� (2).�
�RRC� v� R1� ·� R2�
�the� V� out� by� 20� mV,� thus� placing� a� 20� mV� offset� across� the� IS?�
�and� IS+x� pin� at� no� load� and� allowing� the� Controllers� to� trip�
�into� current� limit� with� only� 50� mV� across� the� inductor.� In�
�R1� )� R2�
�(eq.� 5)�
�RRC� +�
�L�
�this� case,� the� RC� values� are� calculated� using� the� following�
�equation:�
�(eq.� 2)�
�CRC� ·� RL�
�L=� Inductor� value,� both� Controllers� should� have� the�
�same� value.�
�R� L� =� Internal� resistance� of� L,� see� data� sheet.�
�C� RC� =� Chosen� value,� 0.1� m� F� will� make� R� a� reasonable�
�value.�
�And� the� IS?� divider� value� can� be� selected� with� this� equation.�
�Current� Sensing�
�The� current� supplied� to� the� load� can� be� sensed� easily� using�
�the� IS+� and� IS?� pins� for� the� output.� These� pins� sense� a�
�voltage,� proportional� to� the� output� current,� and� compare� it� to�
�a� fixed� internal� voltage� threshold.� When� the� differential�
�voltage� exceeds� 70� mV,� the� internal� overcurrent� protection�
�system� goes� into� hiccup� mode.� Two� methods� for� sensing� the�
�current� are� available.�
�Sense� Resistor.� A� sense� resistor� can� be� added� in� series�
�with� the� inductor.� When� the� voltage� drop� across� the� sense�
�resistor� exceeds� the� internal� voltage� threshold� of� 70� mV,� a�
�R3� +�
�Vout�
�Vout� *� Vos�
�*� 1� ·� R4�
�(eq.� 3)�
�fault� condition� is� set.�
�The� sense� resistor� is� selected� according� to:�
�http://onsemi.com�
�15�
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