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| 型号: | LTC3876EFE#PBF |
| 厂商: | Linear Technology |
| 文件页数: | 34/48页 |
| 文件大小: | 0K |
| 描述: | IC CTLR DC/DC DDR DUAL 38-TSSOP |
| 产品培训模块: | LTC3876 Dual DC/DC Controller |
| 标准包装: | 50 |
| 应用: | 控制器,DDR,DDR2,DDR3 |
| 输入电压: | 4.5 V ~ 38 V |
| 输出数: | 2 |
| 输出电压: | 可调 |
| 工作温度: | -40°C ~ 125°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 38-TFSOP (0.173",4.40mm 宽)裸露焊盘 |
| 供应商设备封装: | 38-TSSOP 裸露焊盘 |
| 包装: | 管件 |
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�LTC3876�
�APPLICATIONS� INFORMATION�
�can� be� added� to� improve� the� high� frequency� response,� as�
�shown� in� Figure� 1.� Capacitor� C� FF� provides� phase� lead� by�
�creating� a� high� frequency� zero� with� R� FB2� which� improves�
�the� phase� margin.�
�A� more� severe� transient� can� be� caused� by� switching� in�
�loads� with� large� supply� bypass� capacitors.� The� discharged�
�bypass� capacitors� of� the� load� are� effectively� put� in� parallel�
�with� the� converter’s� C� OUT� ,� causing� a� rapid� drop� in� V� OUT� .�
�No� regulator� can� deliver� current� quick� enough� to� prevent�
�this� sudden� step� change� in� output� voltage,� if� the� switch�
�connecting� the� C� OUT� to� the� load� has� low� resistance� and� is�
�driven� quickly.� The� solution� is� to� limit� the� turn-on� speed� of�
�the� load� switch� driver.� Hot� Swap?� controllers� are� designed�
�specifically� for� this� purpose� and� usually� incorporate� current�
�limiting,� short-circuit� protection� and� soft� starting.�
�Load-Release� Transient� Detection�
�As� the� output� voltage� requirement� of� step-down� switching�
�regulators� becomes� lower,� V� IN� to� V� OUT� step-down� ratio�
�increases,� and� load� transients� become� faster,� a� major�
�challenge� is� to� limit� the� overshoot� in� V� OUT� during� a� fast�
�load� current� drop,� or� “load-release”� transient.�
�Inductor� current� slew� rate� di� L� /dt� =� V� L� /L� is� proportional�
�to� voltage� across� the� inductor� V� L� =� V� SW� –� V� OUT� .� When�
�the� top� MOSFET� is� turned� on,� V� L� =� V� IN� –� V� OUT� ,� inductor�
�current� ramps� up.� When� bottom� MOSFET� turns� on,� V� L� =�
�V� SW� –� V� OUT� =� –V� OUT� ,� inductor� current� ramps� down.� At�
�very� low� V� OUT� ,� the� low� differential� voltage,� V� L� ,� across� the�
�inductor� during� the� ramp� down� makes� the� slew� rate� of� the�
�inductor� current� much� slower� than� needed� to� follow� the�
�load� current� change.� The� excess� inductor� current� charges�
�up� the� output� capacitor,� which� causes� overshoot� at� V� OUT� .�
�If� the� bottom� MOSFET� could� be� turned� off� during� the� load-�
�release� transient,� the� inductor� current� would� flow� through�
�the� body� diode� of� the� bottom� MOSFET,� and� the� equation�
�can� be� modified� to� include� the� bottom� MOSFET� body�
�diode� drop� to� become� V� L� =� –(V� OUT� +� V� BD� ).� Obviously� the�
�benefit� increases� as� the� output� voltage� gets� lower,� since�
�V� BD� would� increase� the� sum� significantly,� compared� to� a�
�single� V� OUT� only.�
�The� load-release� overshoot� at� V� OUT� causes� the� error� ampli-�
�fier� output,� ITH,� to� drop� quickly.� ITH� voltage� is� proportional�
�to� the� inductor� current� setpoint.� A� load� transient� will�
�result� in� a� quick� change� of� this� load� current� setpoint,� i.e.,�
�a� negative� spike� of� the� first� derivative� of� the� ITH� voltage.�
�The� LTC3876� uses� a� detect� transient� (DTR)� pin� to� monitor�
�the� first� derivative� of� the� ITH� voltage,� and� detect� the� load-�
�release� transient.� Referring� to� the� Functional� Diagram,� the�
�DTR� pin� is� the� input� of� a� DTR� comparator,� and� the� internal�
�reference� voltage� for� the� DTR� comparator� is� half� of� INTV� CC� .�
�To� use� this� pin� for� transient� detection,� ITH� compensation�
�needs� an� additional� R� ITH� resistor� tied� to� INTV� CC� ,� and� con-�
�nects� the� junction� point� of� ITH� compensation� components�
�C� ITH1� ,� R� ITH1� and� R� ITH2� to� the� DTR� pin� as� shown� in� the�
�Functional� Diagram.� The� DTR� pin� is� now� proportional� to�
�the� first� derivative� of� the� inductor� current� setpoint,� through�
�the� highpass� filter� of� C� ITH1� and� (R� ITH1� //R� ITH2� ).�
�The� two� R� ITH� resistors� establish� a� voltage� divider� from�
�INTV� CC� to� SGND,� and� bias� the� DC� voltage� on� DTR� pin� (at�
�steady-state� load� or� ITH� voltage)� slightly� above� half� of�
�INTV� CC� .� Compensation� performance� will� be� identical� by�
�using� the� same� C� ITH1� and� make� R� ITH1� //R� ITH2� equal� the�
�R� ITH� as� used� in� conventional� single� resistor� OPTI-LOOP�
�compensation.� This� will� also� provide� the� R-C� time� constant�
�needed� for� the� DTR� duration.� The� DTR� sensitivity� can� be�
�adjusted� by� the� DC� bias� voltage� difference� between� DTR�
�and� half� INTV� CC� .� This� difference� could� be� set� as� low� as�
�100mV,� as� long� as� the� ITH� ripple� voltage� with� DC� load�
�current� does� not� trigger� the� DTR.�
�When� load� current� suddenly� drops,� V� OUT� overshoots,� and�
�ITH� drops� quickly.� The� voltage� on� the� DTR� pin� will� also�
�drop� quickly,� since� it� is� coupled� to� the� ITH� pin� through� a�
�capacitor.� If� the� load� transient� is� fast� enough� that� the� DTR�
�voltage� drops� below� half� of� INTV� CC� ,� a� load� release� event�
�is� detected.� The� bottom� gate� (BG)� will� be� turned� off,� so�
�that� the� inductor� current� flows� through� the� body� diode�
�in� the� bottom� MOSFET.� This� allows� the� SW� node� to� drop�
�below� PGND� by� a� voltage� of� a� forward-conducted� silicon�
�diode.� This� creates� a� more� negative� differential� voltage�
�(V� SW� –� V� OUT� )� across� the� inductor,� allowing� the� inductor�
�current� to� drop� at� a� faster� rate� to� zero,� therefore� creating�
�less� overshoot� on� V� OUT� .�
�3876f�
�34�
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