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| 型号: | LT1372HVCS8#PBF |
| 厂商: | Linear Technology |
| 文件页数: | 8/12页 |
| 文件大小: | 0K |
| 描述: | IC REG MULTI CONFIG ADJ 8SOIC |
| 标准包装: | 100 |
| 类型: | 降压(降压),升压(升压),反相,Cuk,回扫,正向转换器 |
| 输出类型: | 可调式 |
| 输出数: | 1 |
| 输出电压: | 1.25 V ~ 42 V |
| 输入电压: | 2.7 V ~ 25 V |
| PWM 型: | 电流模式 |
| 频率 - 开关: | 500kHz |
| 电流 - 输出: | 1.5A |
| 同步整流器: | 无 |
| 工作温度: | 0°C ~ 125°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 8-SOIC(0.154",3.90mm 宽) |
| 包装: | 管件 |
| 供应商设备封装: | 8-SOIC |
| 产品目录页面: | 1327 (CN2011-ZH PDF) |
��
�
�LT1372/LT1377�
�APPLICATIO� S� I� FOR� ATIO�
�Choosing� the� Inductor�
�For� most� applications� the� inductor� will� fall� in� the� range� of�
�2.2� μ� H� to� 22� μ� H.� Lower� values� are� chosen� to� reduce� physi-�
�cal� size� of� the� inductor.� Higher� values� allow� more� output�
�current� because� they� reduce� peak� current� seen� by� the�
�power� switch,� which� has� a� 1.5A� limit.� Higher� values� also�
�reduce� input� ripple� voltage� and� reduce� core� loss.�
�When� choosing� an� inductor� you� might� have� to� consider�
�maximum� load� current,� core� and� copper� losses,� allowable�
�component� height,� output� voltage� ripple,� EMI,� fault�
�current� in� the� inductor,� saturation,� and� of� course,� cost.�
�The� following� procedure� is� suggested� as� a� way� of� handling�
�these� somewhat� complicated� and� conflicting� requirements.�
�1.� Assume� that� the� average� inductor� current� for� a� boost�
�converter� is� equal� to� load� current� times� V� OUT� /� V� IN� and�
�decide� whether� or� not� the� inductor� must� withstand�
�continuous� overload� conditions.� If� average� inductor�
�current� at� maximum� load� current� is� 0.5A,� for� instance,�
�a� 0.5A� inductor� may� not� survive� a� continuous� 1.5A�
�overload� condition.� Also� be� aware� that� boost� convert-�
�ers� are� not� short� circuit� protected,� and� that� under�
�output� short� conditions,� inductor� current� is� limited� only�
�by� the� available� current� of� the� input� supply.�
�2.� Calculate� peak� inductor� current� at� full� load� current� to�
�ensure� that� the� inductor� will� not� saturate.� Peak� current�
�can� be� significantly� higher� than� output� current,� espe-�
�cially� with� smaller� inductors� and� lighter� loads,� so� don’t�
�omit� this� step.� Powdered� iron� cores� are� forgiving� be-�
�cause� they� saturate� softly,� whereas� ferrite� cores� satu-�
�rate� abruptly.� Other� core� materials� fall� in� between�
�somewhere.� The� following� formula� assumes� continu-�
�ous� mode� operation� but� it� errors� only� slightly� on� the�
�high� side� for� discontinuous� mode,� so� it� can� be� used� for�
�all� conditions.�
�radiation,� or� whether� it� needs� a� closed� core� like� a� toroid�
�to� prevent� EMI� problems.� One� would� not� want� an� open�
�core� next� to� a� magnetic� storage� media� for� instance!�
�This� is� a� tough� decision� because� the� rods� or� barrels� are�
�temptingly� cheap� and� small,� and� there� are� no� helpful�
�guidelines� to� calculate� when� the� magnetic� field� radia-�
�tion� will� be� a� problem.�
�4.� Start� shopping� for� an� inductor� which� meets� the� re-�
�quirements� of� core� shape,� peak� current� (to� avoid�
�saturation),� average� current� (to� limit� heating)� and� fault�
�current.� If� the� inductor� gets� too� hot,� wire� insulation� will�
�melt� and� cause� turn-to-turn� shorts.� Keep� in� mind� that�
�all� good� things� like� high� efficiency,� low� profile� and� high�
�temperature� operation� will� increase� cost,� sometimes�
�dramatically.�
�5.� After� making� an� initial� choice,� consider� the� secondary�
�things� like� output� voltage� ripple,� second� sourcing,� etc.�
�Use� the� experts� in� the� Linear� Technology� application�
�department� if� you� feel� uncertain� about� the� final� choice.�
�They� have� experience� with� a� wide� range� of� inductor�
�types� and� can� tell� you� about� the� latest� developments� in�
�low� profile,� surface� mounting,� etc.�
�Output� Capacitor�
�The� output� capacitor� is� normally� chosen� by� its� effective�
�series� resistance,� (ESR),� because� this� is� what� determines�
�output� ripple� voltage.� At� 500kHz,� any� polarized� capacitor�
�is� essentially� resistive.� To� get� low� ESR� takes� volume,� so�
�physically� smaller� capacitors� have� high� ESR.� The� ESR�
�range� for� typical� LT1372� and� LT1377� applications� is�
�0.05� ?� to� 0.5� ?� .� A� typical� output� capacitor� is� an� AVX� type�
�TPS,� 22� μ� F� at� 25V,� with� a� guaranteed� ESR� less� than� 0.2� ?� .�
�This� is� a� “D”� size� surface� mount� solid� tantalum� capacitor.�
�TPS� capacitors� are� specially� constructed� and� tested� for�
�low� ESR,� so� they� give� the� lowest� ESR� for� a� given� volume.�
�I� PEAK� =� I� OUT� � OUT� +�
�V�
�V� IN�
�V� IN� (V� OUT� – V� IN� )�
�2(f)(L)(V� OUT� )�
�To� further� reduce� ESR,� multiple� output� capacitors� can� be�
�used� in� parallel.� The� value� in� microfarads� is� not� particu-�
�larly� critical,� and� values� from� 22� μ� F� to� greater� than� 500� μ� F�
�V� IN� =� Minimum� Input� Voltage�
�f� =� 500kHz� Switching� Frequency� (LT1372)� or�
�1MHz� Switching� Frequency� (LT1377)�
�3.� Decide� if� the� design� can� tolerate� an� “open”� core� geom-�
�etry� like� a� rod� or� barrel,� which� have� high� magnetic� field�
�8�
�work� well,� but� you� cannot� cheat� mother� nature� on� ESR.�
�If� you� find� a� tiny� 22� μ� F� solid� tantalum� capacitor,� it� will� have�
�high� ESR,� and� output� ripple� voltage� will� be� terrible.� Table�
�1� shows� some� typical� solid� tantalum� surface� mount�
�capacitors.�
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