参数资料
| 型号: | ISL6266HRZ |
| 厂商: | Intersil |
| 文件页数: | 27/30页 |
| 文件大小: | 0K |
| 描述: | IC CORE CTRLR 2PHASE 48-QFN |
| 标准包装: | 43 |
| 应用: | 转换器,Intel IMVP-6 |
| 输入电压: | 5 V ~ 25 V |
| 输出数: | 1 |
| 输出电压: | 0.3 V ~ 1.5 V |
| 工作温度: | -10°C ~ 100°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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�ISL6266,� ISL6266A�
�L� R� n� ?� RS� EQV�
�-------------� =� ----------------------------------� ?� C� n�
�R� n� +� RS� EQV�
�To� see� whether� the� NTC� has� compensated� the� temperature�
�change� of� the� DCR,� the� user� can� apply� full� load� current� and�
�wait� for� the� thermal� steady� state� and� see� how� much� the�
�output� voltage� will� deviate� from� the� initial� voltage� reading.� A�
�good� compensation� can� limit� the� drift� to� 2mV.� If� the� output�
�voltage� is� decreasing� with� temperature� increase,� the� ratio�
�between� the� NTC� thermistor� value� and� the� rest� of� the�
�resistor� divider� network� has� to� be� increased.� The� user� is�
�strongly� encouraged� to� use� the� evaluation� board� values� and�
�layout� to� minimize� engineering� time.�
�The� 2.1mV/A� load� line� should� be� adjusted� by� R� drp2� based�
�on� maximum� current.� The� droop� gain� might� vary� slightly�
�between� small� steps� (e.g.� 10A).� For� example,� if� the� max�
�create� a� system� failure.� The� output� voltage� could� also� take� a�
�long� period� of� time� to� settle� to� its� final� value,� which� could� be�
�problematic� if� a� load� dump� were� to� occur� during� this� time.�
�This� situation� would� cause� the� output� voltage� to� rise� above�
�the� no� load� setpoint� of� the� converter� and� could� potentially�
�damage� the� CPU.�
�The� L/DCR� time� constant� of� the� inductor� must� be� matched� to�
�the� R� n� *C� n� time� constant� as� shown� in� Equation� 31.�
�(EQ.� 31)�
�DCR�
�Solving� for� C� n� we� now� have� Equation� 32.�
�L�
�C� n� =� -----------------------------------�
�R� n� ?� RS� EQV�
�current� is� 40A� and� the� load� line� 2.1m� Ω,� the� user� load� the�
�converter� to� 40A� and� look� for� 84mV� of� droop.� If� the� droop�
�voltage� is� less� than� 84mV� (e.g.� 80mV)� the� new� value� will� be�
�calculated� by� Equation� 30:�
�-------------�
�DCR�
�----------------------------------�
�R� n� +� RS� EQV�
�(EQ.� 32)�
�R� drp2� new� =� ----------------� (� R� drp1� +� R� drp2� )� –� R� drp1�
�84mV�
�-� 80mV�
�(EQ.� 30)�
�Note,� R� O� was� neglected.� As� long� as� the� inductor� time�
�constant� matches� the� C� n� ,� R� n� and� R� s� time� constants� as� given�
�0.36� μ� H�
�C� n� =� ----------------------------------------------------------------------� ≈� 330nF�
�parallel� (� 5.823K,� 1.825K� )�
�For� the� best� accuracy,� the� effective� resistance� on� the� DFB�
�and� VSUM� pins� should� be� identical� so� that� the� bias� current�
�of� the� droop� amplifier� does� not� cause� an� offset� voltage.� In�
�the� previous� example,� the� resistance� on� the� DFB� pin� is�
�R� drp1� in� parallel� with� R� drp2� ,� that� is,� 1k� Ω� in� parallel� with�
�5.82k� Ω� or� 853� Ω� .� The� resistance� on� the� VSUM� pin� is� R� n� in�
�parallel� with� RS� EQV� or� 5.87k� Ω� in� parallel� with� 1.825k� Ω� ,�
�which� equals� 1392� Ω� .� The� mismatch� in� the� effective�
�resistances� is� 1404� -� 53� =� 551� Ω� .� The� mismatch� cannot� be�
�larger� than� 600� Ω� .� To� reduce� the� mismatch,� multiply� both�
�R� drp1� and� R� drp2� by� the� appropriate� factor.� The� appropriate�
�factor� in� this� example� is� 1404/853� =� 1.65.� In� summary,� the�
�predicted� load� line� with� the� designed� droop� network�
�parameters� based� on� the� Intersil� design� tool� is� shown� in�
�Figure� 41.�
�2.25�
�2.20�
�2.15�
�2.10�
�2.05�
�previously,� the� transient� performance� will� be� optimum.� As� in�
�the� static� droop� case,� this� process� may� require� a� slight�
�adjustment� to� correct� for� layout� inconsistencies.� For� the�
�example� of� L� =� 0.36μH� with� 0.8m� Ω� DCR,� C� n� is� calculated� in�
�Equation� 33.�
�--------------------�
�0.0008�
�(EQ.� 33)�
�The� value� of� this� capacitor� is� selected� to� be� 330nF.� As� the�
�inductors� tend� to� have� 20%� to� 30%� tolerances,� this� capacitor�
�generally� will� be� tuned� on� the� board� by� examining� the�
�transient� voltage.� If� the� output� voltage� transient� has� an� initial�
�dip� lower� than� the� voltage� required� by� the� load� line� and�
�slowly� increases� back� to� steady� state,� the� capacitor� is� too�
�small� and� vice� versa.� It� is� better� to� have� the� capacitor� value�
�a� little� bigger� to� cover� the� tolerance� of� the� inductor� to� prevent�
�the� output� voltage� from� going� lower� than� the� spec.� This�
�capacitor� needs� to� be� a� high� grade� capacitor� like� X7R� with�
�low� tolerance.� There� is� another� consideration� in� order� to�
�achieve� better� time� constant� match� mentioned� previously.�
�The� NPO/COG� (class-I)� capacitors� have� only� 5%� tolerance�
�and� very� good� thermal� characteristics.� However,� these�
�capacitors� are� only� available� in� small� capacitance� values.� In�
�order� to� use� such� capacitors,� the� resistors� and� thermistors�
�surrounding� the� droop� voltage� sensing� and� droop� amplifier�
�0�
�20�
�40�
�60�
�80�
�100�
�has� to� be� resized� up� to� 10x� larger� to� reduce� the� capacitance�
�INDUCTOR� TEMPERATURE� (°C)�
�FIGURE� 41.� LOAD� LINE� PERFORMANCE� WITH� NTC�
�THERMAL� COMPENSATION�
�Dynamic� Mode� of� Operation� -� Dynamic� Droop�
�Using� DCR� Sensing�
�Droop� is� very� important� for� load� transient� performance.� If� the�
�system� is� not� compensated� correctly,� the� output� voltage�
�could� sag� excessively� upon� load� application� and� potentially�
�27�
�by� 10x.� Careful� attention� must� be� paid� in� balancing� the�
�impedance� of� droop� amplifier� in� this� case.�
�Dynamic� Mode� of� Operation� -� Compensation�
�Parameters�
�Considering� the� voltage� regulator� as� a� black� box� with� a�
�voltage� source� controlled� by� VID� and� a� series� impedance,� in�
�order� to� achieve� the� 2.1mV/A� load� line,� the� impedance�
�needs� to� be� 2.1m� Ω� .� The� compensation� design� has� to� target�
�the� output� impedance� of� the� converter� to� be� 2.1m� Ω� .� There� is�
�FN6398.3�
�June� 14,� 2010�
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| ISL6266HRZ-T | 功能描述:IC CORE CTRLR 2PHASE 48-QFN 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 |
| ISL6267 | 制造商:INTERSIL 制造商全称:Intersil Corporation 功能描述:Multiphase PWM Regulator for AMD Fusion Mobile CPUs |
| ISL6267EVAL1Z | 制造商:INTERSIL 制造商全称:Intersil Corporation 功能描述:Multiphase PWM Regulator for AMD Fusion Mobile CPUs |
| ISL6267HRZ | 功能描述:电流型 PWM 控制器 MULTI-OUTPUT CNTRLR FOR AMD FUSION UP RoHS:否 制造商:Texas Instruments 开关频率:27 KHz 上升时间: 下降时间: 工作电源电压:6 V to 15 V 工作电源电流:1.5 mA 输出端数量:1 最大工作温度:+ 105 C 安装风格:SMD/SMT 封装 / 箱体:TSSOP-14 |
| ISL6267HRZ-T | 功能描述:电流型 PWM 控制器 MULTI-OUTPUT CNTRLR FOR AMD FUSION UP RoHS:否 制造商:Texas Instruments 开关频率:27 KHz 上升时间: 下降时间: 工作电源电压:6 V to 15 V 工作电源电流:1.5 mA 输出端数量:1 最大工作温度:+ 105 C 安装风格:SMD/SMT 封装 / 箱体:TSSOP-14 |
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