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| 型号: | LT1676IS8#TR |
| 厂商: | Linear Technology |
| 文件页数: | 8/16页 |
| 文件大小: | 0K |
| 描述: | IC REG BUCK ADJ 0.7A 8SOIC |
| 标准包装: | 2,500 |
| 类型: | 降压(降压) |
| 输出类型: | 可调式 |
| 输出数: | 1 |
| 输出电压: | 1.24 V ~ 51 V |
| 输入电压: | 7.4 V ~ 60 V |
| PWM 型: | 电流模式,混合 |
| 频率 - 开关: | 100kHz |
| 电流 - 输出: | 700mA |
| 同步整流器: | 无 |
| 工作温度: | -40°C ~ 125°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 8-SOIC(0.154",3.90mm 宽) |
| 包装: | 带卷 (TR) |
| 供应商设备封装: | 8-SOIC |
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�LT1676�
�APPLICATIO� N� S� I� N� FOR� M� ATIO� N�
�Once� the� inductance� value� is� decided,� inductor� peak�
�current� rating� and� resistance� need� to� be� considered.� Here,�
�the� inductor� peak� current� rating� refers� to� the� onset� of�
�saturation� in� the� core� material,� although� manufacturers�
�sometimes� specify� a� “peak� current� rating”� which� is�
�derived� from� a� worst-case� combination� of� core� saturation�
�and� self-heating� effects.� Inductor� winding� resistance� alone�
�limits� the� inductor’s� current� carrying� capability� as� the� I� 2� R�
�power� threatens� to� overheat� the� inductor.� If� applicable,�
�remember� to� include� the� condition� of� output� short� circuit.�
�Although� the� peak� current� rating� of� the� inductor� can� be�
�exceeded� in� short-circuit� operation,� as� core� saturation� per�
�se� is� not� destructive� to� the� core,� excess� resistive� self-�
�heating� is� still� a� potential� problem.�
�The� final� inductor� selection� is� generally� based� on� cost,�
�which� usually� translates� into� choosing� the� smallest� physi-�
�cal� size� part� that� meets� the� desired� inductance� value,�
�resistance� and� current� carrying� capability.� An� additional�
�factor� to� consider� is� that� of� physical� construction.� Briefly�
�stated,� “open”� inductors� built� on� a� rod-� or� barrel-shaped�
�core� generally� offer� the� smallest� physical� size� and� lowest�
�cost.� However� their� open� construction� does� not� contain�
�the� resulting� magnetic� field,� and� they� may� not� be� accept-�
�able� in� RFI-sensitive� applications.� Toroidal� style� induc-�
�tors,� many� available� in� surface� mount� configuration,� offer�
�improved� RFI� performance,� generally� at� an� increase� in�
�cost� and� physical� size.� And� although� custom� design� is�
�always� a� possibility,� most� potential� LT1676� applications�
�can� be� handled� by� the� array� of� standard,� off-the-shelf�
�inductor� products� offered� by� the� major� suppliers.�
�Selecting� Freewheeling� Diode�
�Highest� efficiency� operation� requires� the� use� of� a� Schottky�
�type� diode.� DC� switching� losses� are� minimized� due� to� its�
�low� forward� voltage� drop,� and� AC� behavior� is� benign� due�
�to� its� lack� of� a� significant� reverse� recovery� time.� Schottky�
�diodes� are� generally� available� with� reverse� voltage� ratings�
�of� 60V� and� even� 100V,� and� are� price� competitive� with� other�
�types.�
�The� use� of� so-called� “ultrafast”� recovery� diodes� is� gener-�
�ally� not� recommended.� When� operating� in� continuous�
�mode,� the� reverse� recovery� time� exhibited� by� “ultrafast”�
�diodes� will� result� in� a� slingshot� type� effect.� The� power�
�8�
�internal� switch� will� ramp� up� V� IN� current� into� the� diode� in� an�
�attempt� to� get� it� to� recover.� Then,� when� the� diode� has�
�finally� turned� off,� some� tens� of� nanoseconds� later,� the� V� SW�
�node� voltage� ramps� up� at� an� extremely� high� dV/dt,� per-�
�haps� 5� to� even� 10V/ns� !� With� real� world� lead� inductances,�
�the� V� SW� node� can� easily� overshoot� the� V� IN� rail.� This� can�
�result� in� poor� RFI� behavior� and� if� the� overshoot� is� severe�
�enough,� damage� the� IC� itself.�
�Selecting� Bypass� Capacitors�
�The� basic� topology� as� shown� in� Figure� 1� uses� two� bypass�
�capacitors,� one� for� the� V� IN� input� supply� and� one� for� the�
�V� OUT� output� supply.�
�User� selection� of� an� appropriate� output� capacitor� is� rela-�
�tively� easy,� as� this� capacitor� sees� only� the� AC� ripple� current�
�in� the� inductor.� As� the� LT1676� is� designed� for� Buck� or�
�step-down� applications,� output� voltage� will� nearly� always�
�be� compatible� with� tantalum� type� capacitors,� which� are�
�generally� available� in� ratings� up� to� 35V� or� so.� These�
�tantalum� types� offer� good� volumetric� efficiency� and� many�
�are� available� with� specified� ESR� performance.� The� product�
�of� inductor� AC� ripple� current� and� output� capacitor� ESR� will�
�manifest� itself� as� peak-to-peak� voltage� ripple� on� the� output�
�node.� (Note:� If� this� ripple� becomes� too� large,� heavier�
�control� loop� compensation,� at� least� at� the� switching� fre-�
�quency,� may� be� required� on� the� V� C� pin.)� The� most�
�demanding� applications,� requiring� very� low� output� ripple,�
�may� be� best� served� not� with� a� single� extremely� large�
�output� capacitor,� but� instead� by� the� common� technique� of�
�a� separate� L/C� lowpass� post� filter� in� series� with� the� output.�
�(In� this� case,� “Two� caps� are� better� than� one.”)�
�The� input� bypass� capacitor� is� normally� a� more� difficult�
�choice.� In� a� typical� application� e.g.,� 48V� IN� to� 5V� OUT� ,�
�relatively� heavy� V� IN� current� is� drawn� by� the� power� switch�
�for� only� a� small� portion� of� the� oscillator� period� (low� ON�
�duty� cycle).� The� resulting� RMS� ripple� current,� for� which�
�the� capacitor� must� be� rated,� is� often� several� times� the� DC�
�average� V� IN� current.� Similarly,� the� “glitch”� seen� on� the� V� IN�
�supply� as� the� power� switch� turns� on� and� off� will� be� related�
�to� the� product� of� capacitor� ESR,� and� the� relatively� high�
�instantaneous� current� drawn� by� the� switch.� To� compound�
�these� problems� is� the� fact� that� most� of� these� applications�
�will� be� designed� for� a� relatively� high� input� voltage,� for�
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