参数资料
| 型号: | ISL8101CRZ-T |
| 厂商: | Intersil |
| 文件页数: | 16/20页 |
| 文件大小: | 0K |
| 描述: | IC CTRLR PWM BUCK 2PHASE 24-QFN |
| 标准包装: | 6,000 |
| 应用: | 控制器,Intel VRM9,VRM10,AMD Hammer 应用 |
| 输入电压: | 4.6 V ~ 12 V |
| 输出数: | 1 |
| 输出电压: | 0.6 V ~ 2.3 V |
| 工作温度: | 0°C ~ 70°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 24-VFQFN 裸露焊盘 |
| 供应商设备封装: | 24-QFN(4x4) |
| 包装: | 带卷 (TR) |
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�
�ISL8101�
�At� the� beginning� of� the� load� transient,� the� output� capacitors�
�supply� all� of� the� transient� current.� The� output� voltage� will�
�initially� deviate� by� an� amount� approximated� by� the� voltage�
�drop� across� the� ESL.� As� the� load� current� increases,� the�
�voltage� drop� across� the� ESR� increases� linearly� until� the� load�
�current� reaches� its� final� value.� The� capacitors� selected� must�
�have� sufficiently� low� ESL� and� ESR� so� that� the� total� output-�
�voltage� deviation� is� less� than� the� allowable� maximum.�
�Neglecting� the� contribution� of� inductor� current� and� regulator�
�response,� the� output� voltage� initially� deviates� according� to�
�Equation� 21.�
�Normally,� the� trailing� edge� dictates� the� selection� of� L,� since�
�duty� cycles� are� usually� less� than� 50%.� Nevertheless,� both�
�inequalities� should� be� evaluated,� and� L� should� be� selected�
�based� on� the� lower� of� the� two� results.� In� all� equations� in� this�
�paragraph,� L� is� the� per-channel� inductance� and� C� is� the� total�
�output� bulk� capacitance.�
�LAYOUT� CONSIDERATIONS�
�MOSFETs� switch� very� fast� and� efficiently.� The� speed� with�
�which� the� current� transitions� from� one� device� to� another�
�causes� voltage� spikes� across� the� interconnecting�
�Δ� V� ≈� (� ESL� )� -----� +� (� ESR� )� Δ� I�
�di�
�dt�
�(EQ.� 21)�
�impedances� and� parasitic� circuit� elements.� These� voltage�
�spikes� can� degrade� efficiency,� radiate� noise� into� the� circuit�
�and� lead� to� device� overvoltage� stress.� Careful� component�
�(� V� IN� –� 2� ?� V� OUT� )� ?� V� OUT�
�L� ≥� ESR� ?� -----------------------------------------------------------------�
�The� filter� capacitor� must� have� sufficiently� low� ESL� and� ESR�
�so� that� Δ� V� <� Δ� V� MAX� .�
�Most� capacitor� solutions� rely� on� a� mixture� of� high-frequency�
�capacitors� with� relatively� low� capacitance� in� combination�
�with� bulk� capacitors� having� high� capacitance� but� limited�
�high-frequency� performance.� Minimizing� the� ESL� of� the�
�high-frequency� capacitors� allows� them� to� support� the� output�
�voltage� as� the� current� increases.� Minimizing� the� ESR� of� the�
�bulk� capacitors� allows� them� to� supply� the� increased� current�
�with� less� output� voltage� deviation.�
�The� ESR� of� the� bulk� capacitors� is� also� responsible� for� the�
�majority� of� the� output-voltage� ripple.� As� the� bulk� capacitors�
�sink� and� source� the� inductor� ac� ripple� current,� a� voltage�
�develops� across� the� bulk-capacitor� ESR� equal� to� I� P-P� .� Thus,�
�once� the� output� capacitors� are� selected� and� a� maximum�
�allowable� ripple� voltage,� V� P-P(MAX)� ,� is� determined� from� an�
�analysis� of� the� available� output� voltage� budget.� Equation� 22�
�can� be� used� to� determine� a� lower� limit� on� the� output�
�inductance.�
�(EQ.� 22)�
�f� S� ?� V� IN� ?� V� P-P� (� MAX� )�
�Since� the� capacitors� are� supplying� a� decreasing� portion� of�
�the� load� current� while� the� regulator� recovers� from� the�
�transient,� the� capacitor� voltage� becomes� slightly� depleted.�
�The� output� inductors� must� be� capable� of� assuming� the� entire�
�load� current� before� the� output� voltage� decreases� more� than�
�layout� and� printed� circuit� design� minimizes� the� voltage�
�spikes� in� the� converter.� Consider,� as� an� example,� the� turn-off�
�transition� of� the� upper� PWM� MOSFET.� Prior� to� turn-off,� the�
�upper� MOSFET� was� carrying� channel� current.� During� the�
�turnoff,� current� stops� flowing� in� the� upper� MOSFET� and� is�
�picked� up� by� the� lower� MOSFET.� Any� inductance� in� the�
�switched� current� path� generates� a� large� voltage� spike� during�
�the� switching� interval.� Careful� component� selection,� tight�
�layout� of� the� critical� components,� and� short,� wide� circuit�
�traces� minimize� the� magnitude� of� voltage� spikes.�
�There� are� two� sets� of� critical� components� in� a� DC/DC�
�converter� using� a� ISL8101� controller.� The� power�
�components� are� the� most� critical� because� they� switch� large�
�amounts� of� energy.� Next� are� small� signal� components� that�
�connect� to� sensitive� nodes� or� supply� critical� bypassing�
�current� and� signal� coupling.�
�Note� that� as� the� ISL8101� does� not� allow� external� adjustment�
�of� the� channel-to-channel� current� balancing� (current�
�information� is� multiplexed� across� a� single� R� ISEN� resistor),� it�
�is� important� to� have� a� symmetrical� layout,� preferably� with� the�
�controller� equidistantly� located� from� the� two� power� trains� it�
�controls.� Equally� important� are� the� gate� drive� lines� (UGATE,�
�LGATE,� PHASE):� since� they� drive� the� power� train� MOSFETs�
�using� short,� high� current� pulses,� it� is� important� to� size� them�
�accordingly� and� reduce� their� overall� impedance.� Equidistant�
�placement� of� the� controller� to� the� two� power� trains� also� helps�
�keeping� these� traces� equally� long� (equal� impedances,�
�resulting� in� similar� driving� of� both� sets� of� MOSFETs).�
�4� ?� C� ?� V� OUT�
�2�
�Δ� V� MAX� .� This� places� an� upper� limit� on� inductance.�
�L� ≤� --------------------------------� ?� (� Δ� V� MAX� –� Δ� I� ?� ESR� )�
�(� Δ� I� )�
�(EQ.� 23)�
�The� power� components� should� be� placed� first.� Locate� the�
�input� capacitors� close� to� the� power� switches.� Minimize� the�
�length� of� the� connections� between� the� input� capacitors,� C� IN� ,�
�and� the� power� switches.� Locate� the� output� inductors� and�
�While� Equation� 23� addresses� the� leading� edge,� Equation� 24�
�gives� the� upper� limit� on� L� for� cases� where� the� trailing� edge� of�
�the� current� transient� causes� a� greater� output� voltage�
�deviation� than� the� leading� edge.�
�output� capacitors� between� the� MOSFETs� and� the� load.�
�Locate� the� high-frequency� decoupling� capacitors� (ceramic)�
�as� close� as� practicable� to� the� decoupling� target,� making� use�
�of� the� shortest� connection� paths� to� any� internal� planes,� such�
�L� ≤� -----------------� ?� (� Δ� V� MAX� –� Δ� I� ?� ESR� )� ?� (� V� IN� –� V� O� )�
�(� Δ� I� )�
�2.5� ?� C�
�2�
�16�
�(EQ.� 24)�
�as� vias� to� GND� immediately� next,� or� even� onto� the� capacitor�
�solder� pad.�
�The� critical� small� components� include� the� bypass� capacitors�
�for� VCC� and� PVCC.� Locate� the� bypass� capacitors,� C� BP� ,�
�FN9223.1�
�July� 28,� 2008�
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