参数资料
| 型号: | NCP1417DMR2 |
| 厂商: | ON Semiconductor |
| 文件页数: | 10/13页 |
| 文件大小: | 0K |
| 描述: | IC REG BST SYNC ADJ 0.2A 8MICRO |
| 产品变化通告: | Product Obsolescence 01/Apr/2004 |
| 标准包装: | 1 |
| 类型: | 升压(升压) |
| 输出类型: | 可调式 |
| 输出数: | 1 |
| 输出电压: | 1.5 V ~ 5.5 V |
| 输入电压: | 1 V ~ 5.5 V |
| 频率 - 开关: | 600kHz |
| 电流 - 输出: | 200mA |
| 同步整流器: | 是 |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 8-TSSOP,8-MSOP(0.118",3.00mm 宽) |
| 包装: | 剪切带 (CT) |
| 供应商设备封装: | Micro8? |
| 其它名称: | NCP1417DMR2OSCT |
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�
�NCP1417�
�1� )� FB1�
�VOUT� +� 1.190� V�
�higher� than� 1.190� V� +� 30� mV,� the� comparator� output� will�
�cause� the� 50� W� low� side� switch� to� be� turned� OFF,� pin� 3� will�
�become� high� impedance,� and� its� voltage� will� be� pulled� high.�
�The� second� low� ?� battery� detector� functions� in� the� same�
�manner,� the� second� comparator,� CP2� with� a� lower� triggering�
�reference� point� derived� from� the� internal� reference� is� used�
�instead,� typical� 0.944� V.� This� configuration� provides� two�
�levels� of� low� battery� warning� to� the� target� system.�
�APPLICATIONS� INFORMATION�
�Output� Voltage� Setting�
�The� output� voltage� of� the� converter� is� determined� by� the�
�external� feedback� network� comprised� of� R� FB1� and� R� FB2� and�
�the� relationship� is� given� by:�
�R�
�RFB2�
�where� R� FB1� and� R� FB2� are� the� upper� and� lower� feedback�
�resistors� respectively.�
�Low� Battery� Detect� Level� Setting�
�out� of� the� capacitors� multiplying� with� the� Equivalent� Series�
�Resistance� (ESR)� of� the� capacitor� producing� ripple� voltage�
�at� the� terminals.� During� the� syn� ?� rect� switch� off� cycle,� the�
�charges� stored� in� the� output� capacitor� is� used� to� sustain� the�
�output� load� current.� Load� current� at� this� period� and� the� ESR�
�combined� and� reflected� as� ripple� at� the� output� terminal.� For�
�all� cases,� the� lower� the� capacitor� ESR,� the� lower� the� ripple�
�voltage� at� output.� As� a� general� guide� line,� low� ESR�
�capacitors� should� be� used.� Ceramic� capacitors� have� the�
�lowest� ESR,� but� low� ESR� tantalum� capacitors� can� also� be�
�used� as� a� cost� effective� substitute.�
�Optional� Startup� Schottky� Diode� for� Low� Battery�
�Voltage�
�In� general� operation,� no� external� schottky� diode� is�
�required,� however,� in� case� you� are� intended� to� operate� the�
�device� close� to� 1.0� V� level,� a� schottky� diode� connected�
�between� the� LX� and� OUT� pins� as� shown� in� Figure� 27� can�
�help� during� startup� of� the� converter.� The� effect� of� the�
�additional� schottky� is� shown� in� Figure� 8.�
�1� )� LB1�
�The� Low� Battery� Detect� Voltages� of� the� converter� are�
�determined� by� the� external� divider� network� comprised� of�
�R� LB1� and� R� LB2� and� the� relationship� is� given� by:�
�R�
�VLB1� +� 1.190� V�
�RLB2�
�OUT�
�L�
�MBR0520�
�V� OUT�
�where� R� LB1� and� R� LB2� are� the� upper� and� lower� divider�
�resistors� respectively.� By� setting� the� V� LB1� ,� the� second� low�
�battery� detection� point,� V� LB2� will� be� fixed� automatically.�
�NCP1417�
�LX�
�C� OUT�
�Inductor� Selection�
�The� NCP1417� is� tested� to� produce� optimum� performance�
�with� a� 22� m� H� inductor� at� V� IN� =� 3.0� V,� V� OUT� =� 3.3� V�
�supplying� output� current� up� to� 200� mA.� For� other�
�input/output� requirements,� inductance� in� the� range� 10� m� H� to�
�47� m� H� can� be� used� according� to� end� application�
�specifications.� Selecting� an� inductor� is� a� compromise�
�between� output� current� capability� and� tolerable� output�
�voltage� ripple.� Of� course,� the� first� thing� we� need� to� obey� is�
�to� keep� the� peak� inductor� current� below� its� saturation� limit�
�at� maximum� current� and� the� I� LIM� of� the� device.� In� NCP1417,�
�I� LIM� is� set� at� 1.0� A.� As� a� rule� of� thumb,� low� inductance�
�values� supply� higher� output� current,� but� also� increase� the�
�ripple� at� output� and� reducing� efficiency,� on� the� other� hand,�
�high� inductance� values� can� improve� output� ripple� and�
�efficiency,� however� it� also� limit� the� output� current� capability�
�at� the� same� time.� One� other� parameter� of� the� inductor� is� its�
�DC� resistance,� this� resistance� can� introduce� unwanted�
�power� loss� and� hence� reduce� overall� efficiency,� the� basic�
�rule� is� selecting� an� inductor� with� lowest� DC� resistance�
�within� the� board� space� limitation� of� the� end� application.�
�Capacitors� Selection�
�In� all� switching� mode� boost� converter� applications,�
�both� the� input� and� output� terminals� sees� impulsive�
�voltage/current� waveforms.� The� currents� flowing� into� and�
�Figure� 27.�
�PCB� Layout� Recommendations�
�Good� PCB� layout� plays� an� important� role� in� switching�
�mode� power� conversion.� Careful� PCB� layout� can� help� to�
�minimize� ground� bounce,� EMI� noise� and� unwanted�
�feedback� that� can� affect� the� performance� of� the� converter.�
�Hints� suggested� in� below� can� be� used� as� a� guide� line� in� most�
�situations.�
�Grounding�
�Star� ?� ground� connection� should� be� used� to� connect� the�
�output� power� return� ground,� the� input� power� return� ground�
�and� the� device� power� ground� together� at� one� point.� All� high�
�current� running� paths� must� be� thick� enough� for� current�
�flowing� through� and� producing� insignificant� voltage� drop�
�along� the� path.� Feedback� signal� path� must� be� separated� with�
�the� main� current� path� and� sensing� directly� at� the� anode� of� the�
�output� capacitor.�
�Components� Placement�
�Power� components,� i.e.� input� capacitor,� inductor� and�
�output� capacitor,� must� be� placed� as� close� together� as�
�possible.� All� connecting� traces� must� be� short,� direct� and�
�thick.� High� current� flowing� and� switching� paths� must� be�
�http://onsemi.com�
�10�
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