参数资料
| 型号: | ISL6328ACRZ |
| 厂商: | Intersil |
| 文件页数: | 13/33页 |
| 文件大小: | 0K |
| 描述: | IC VOLTAGE REGULATOR |
| 标准包装: | 50 |
| 系列: | * |
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�ISL6328A�
�Another� benefit� of� interleaving� is� to� reduce� input� ripple� current.�
�Input� capacitance� is� determined� in� part� by� the� maximum� input�
�ripple� current.� Multi-phase� topologies� can� improve� overall� system�
�cost� and� size� by� lowering� input� ripple� current� and� allowing� the�
�designer� to� reduce� the� cost� of� input� capacitance.� The� example� in�
�Figure� 2� illustrates� input� currents� from� a� 3-phase� converter�
�combining� to� reduce� the� total� input� ripple� current.�
�The� converter� depicted� in� Figure� 2� delivers� 1.5V� to� a� 36A� load� from�
�a� 12V� input.� The� RMS� input� capacitor� current� is� 5.9A.� Compare�
�this� to� a� single-phase� converter� also� stepping� down� 12V� to� 1.5V� at�
�36A.� The� single-phase� converter� has� 11.9A� RMS� input� capacitor�
�current.� The� single-phase� converter� must� use� an� input� capacitor�
�bank� with� twice� the� RMS� current� capacity� as� the� equivalent�
�three-phase� converter.�
�INPUT-CAPACITOR CURRENT, 10A/DIV�
�CHANNEL� 3�
�INPUT� CURRENT�
�10A/DIV�
�CHANNEL� 2�
�INPUT� CURRENT�
�10A/DIV�
�CHANNEL� 1�
�INPUT� CURRENT�
�10A/DIV�
�1� μ� s/DIV�
�FIGURE� 2.� CHANNEL� INPUT� CURRENTS� AND� INPUT-CAPACITOR�
�RMS� CURRENT� FOR� 3-PHASE� CONVERTER�
�illustrated� in� Figure� 3.� At� the� beginning� of� each� PWM� time�
�interval,� this� modified� V� COMP� signal� is� compared� to� the� internal�
�modulator� waveform.� As� long� as� the� modified� V� COMP� voltage� is�
�lower� then� the� modulator� waveform� voltage,� the� PWM� signal� is�
�commanded� low.� The� internal� MOSFET� driver� detects� the� low�
�state� of� the� PWM� signal� and� turns� off� the� upper� MOSFET� and�
�turns� on� the� lower� synchronous� MOSFET.� When� the� modified�
�V� COMP� voltage� crosses� the� modulator� ramp,� the� PWM� output�
�transitions� high,� turning� off� the� synchronous� MOSFET� and� turning�
�on� the� upper� MOSFET.� The� PWM� signal� will� remain� high� until� the�
�modified� V� COMP� voltage� crosses� the� modulator� ramp� again.�
�When� this� occurs� the� PWM� signal� will� transition� low� again.�
�During� each� PWM� time� interval,� the� PWM� signal� can� only�
�transition� high� once.� Once� PWM� transitions� high,� it� can� not�
�transition� high� again� until� the� beginning� of� the� next� PWM� time�
�interval.� This� prevents� the� occurrence� of� double� PWM� pulses�
�occurring� during� a� single� period.�
�To� further� improve� the� transient� response,� ISL6328A� also�
�implements� Intersil’s� proprietary� Adaptive� Phase� Alignment�
�(APA)� technique,� which� turns� on� all� phases� together� under�
�transient� events� with� large� step� current.� With� both� APP� and� APA�
�control,� ISL6328A� can� achieve� excellent� transient� performance�
�and� reduce� the� demand� on� the� output� capacitors.�
�Adaptive� Phase� Alignment� (APA)�
�When� a� load� is� applied,� the� output� will� fall� in� direct� relation� to� the�
�amount� of� load� being� applied� and� the� speed� at� which� the� load� is�
�being� applied.� The� ISL6329� monitors� the� output� differentially�
�through� the� VSEN� pin.� If� the� sensed� voltage� drops� quickly� by� a�
�user� programmable� magnitude� (V� APATRIP� ),� all� of� the� upper�
�MOSFETs� will� immediately� be� turned� on� simultaneously.� The� trip�
�level� is� relative,� not� absolute,� and� can� be� programmed� through� a�
�resistor� and� capacitor� tied� in� parallel� from� the� APA� pin� to� ground.�
���1.75� μ� A�
�V� APATRIP�
�R� APA� =� -------------------------�
�(EQ.� 4)�
�capacitor� RMS� current� based� on� load� current,� duty� cycle,� and� the�
�number� of� channels.� They� are� provided� as� aids� in� determining�
�the� optimal� input� capacitor� solution.�
�Active� Pulse� Positioning� Modulated� PWM�
�Operation�
�The� ISL6328A� uses� a� proprietary� Active� Pulse� Positioning� (APP)�
�modulation� scheme� to� control� the� internal� PWM� signals� that�
�command� each� channel’s� driver� to� turn� their� upper� and� lower�
�MOSFETs� on� and� off.� The� time� interval� in� which� a� PWM� signal� can�
�occur� is� generated� by� an� internal� clock,� whose� cycle� time� is� the�
�inverse� of� the� switching� frequency� set� by� the� resistor� between� the�
�FS� pin� and� ground.� The� advantage� of� Intersil’s� proprietary� Active�
�Pulse� Positioning� (APP)� modulator� is� that� the� PWM� signal� has�
�the� ability� to� turn� on� at� any� point� during� this� PWM� time� interval,�
�and� turn� off� immediately� after� the� PWM� signal� has� transitioned�
�high.� This� is� important� because� it� allows� the� controller� to� quickly�
�respond� to� output� voltage� drops� associated� with� current� load�
�spikes,� while� avoiding� the� ring� back� affects� associated� with� other�
�modulation� schemes.�
�The� PWM� output� state� is� driven� by� the� position� of� the� error�
�amplifier� output� signal,� V� COMP� ,� minus� the� current� correction�
�signal� relative� to� the� proprietary� modulator� ramp� waveform� as�
�13�
�A� 3900pF,� X7R� capacitor� is� required� to� be� placed� in� parallel� to�
�the� APA� resistor.�
�PWM� Operation�
�The� timing� of� each� core� channel� is� set� by� the� number� of� active�
�channels.� Channel� detection� on� the� ISEN2-,� ISEN3-� and� ISEN4-,�
�pins� selects� 1-channel� to� 4-channel� operation� for� the� ISL6328A.�
�The� switching� cycle� is� defined� as� the� time� between� PWM� pulse�
�termination� signals� of� each� channel.� The� cycle� time� of� the� pulse�
�signal� is� the� inverse� of� the� switching� frequency� set� by� the� resistor�
�between� the� FS� pin� and� ground� (or� VCC).� The� PWM� signals�
�command� the� MOSFET� driver� to� turn� on/off� the� channel�
�MOSFETs.�
�The� channel� firing� order� for� 4-channel� operation,� the� channel�
�firing� order� is� 1-2-3-4.� For� 3-channel� operation,� the� channel� firing�
�order� is� 1-2-3.�
�Connecting� ISEN4-� to� VCC� selects� three� channel� operation.� To� set�
�2-channel� operation,� both� ISEN4-� and� ISEN3-� must� be� tied� to�
�VCC.� Similarly,� to� set� single� channel� operation,� ISEN4-,� ISEN3-�
�and� ISEN2-� must� be� tied� to� VCC.�
�FN7986.0�
�April� 6,� 2012�
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| ISL6328ACRZ-T | 功能描述:IC VOLTAGE REGULATOR RoHS:是 类别:集成电路 (IC) >> PMIC - 稳压器 - 专用型 系列:* 标准包装:43 系列:- 应用:控制器,Intel VR11 输入电压:5 V ~ 12 V 输出数:1 输出电压:0.5 V ~ 1.6 V 工作温度:-40°C ~ 85°C 安装类型:表面贴装 封装/外壳:48-VFQFN 裸露焊盘 供应商设备封装:48-QFN(7x7) 包装:管件 |
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