参数资料
| 型号: | ISL6556BCR-T |
| 厂商: | Intersil |
| 文件页数: | 18/24页 |
| 文件大小: | 0K |
| 描述: | IC CTRLR MULTIPHASE VRM10 32-QFN |
| 标准包装: | 6,000 |
| 应用: | 控制器,Intel VR10X |
| 输入电压: | 3 V ~ 12 V |
| 输出数: | 4 |
| 输出电压: | 0.84 V ~ 1.6 V |
| 工作温度: | 0°C ~ 70°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 32-VFQFN 裸露焊盘 |
| 供应商设备封装: | 32-QFN 裸露焊盘(5x5) |
| 包装: | 带卷 (TR) |
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�ISL6556B�
�General� Design� Guide�
�This� design� guide� is� intended� to� provide� a� high-level�
�explanation� of� the� steps� necessary� to� create� a� multi-phase�
�power� converter.� It� is� assumed� that� the� reader� is� familiar� with�
�many� of� the� basic� skills� and� techniques� referenced� below.� In�
�addition� to� this� guide,� Intersil� provides� complete� reference�
�designs� that� include� schematics,� bills� of� materials,� and� example�
�board� layouts� for� all� common� microprocessor� applications.�
�Power� Stages�
�The� first� step� in� designing� a� multi-phase� converter� is� to�
�determine� the� number� of� phases.� This� determination�
�depends� heavily� on� the� cost� analysis� which� in� turn� depends�
�on� system� constraints� that� differ� from� one� design� to� the� next.�
�Principally,� the� designer� will� be� concerned� with� whether�
�components� can� be� mounted� on� both� sides� of� the� circuit�
�board;� whether� through-hole� components� are� permitted;� and�
�the� total� board� space� available� for� power-supply� circuitry.�
�Generally� speaking,� the� most� economical� solutions� are�
�those� in� which� each� phase� handles� between� 15� and� 20A.� All�
�surface-mount� designs� will� tend� toward� the� lower� end� of� this�
�current� range.� If� through-hole� MOSFETs� and� inductors� can�
�be� used,� higher� per-phase� currents� are� possible.� In� cases�
�where� board� space� is� the� limiting� constraint,� current� can� be�
�Thus� the� total� maximum� power� dissipated� in� each� lower�
�MOSFET� is� approximated� by� the� summation� of� P� LOW,1� and�
�P� LOW,2� .�
�UPPER� MOSFET� POWER� CALCULATION�
�In� addition� to� r� DS(ON)� losses,� a� large� portion� of� the� upper-�
�MOSFET� losses� are� due� to� currents� conducted� across� the�
�input� voltage� (V� IN� )� during� switching.� Since� a� substantially�
�higher� portion� of� the� upper-MOSFET� losses� are� dependent�
�on� switching� frequency,� the� power� calculation� is� more�
�complex.� Upper� MOSFET� losses� can� be� divided� into�
�separate� components� involving� the� upper-MOSFET�
�switching� times;� the� lower-MOSFET� body-diode� reverse-�
�recovery� charge,� Q� rr� ;� and� the� upper� MOSFET� r� DS(ON)�
�conduction� loss.�
�When� the� upper� MOSFET� turns� off,� the� lower� MOSFET� does�
�not� conduct� any� portion� of� the� inductor� current� until� the�
�voltage� at� the� phase� node� falls� below� ground.� Once� the�
�lower� MOSFET� begins� conducting,� the� current� in� the� upper�
�MOSFET� falls� to� zero� as� the� current� in� the� lower� MOSFET�
�ramps� up� to� assume� the� full� inductor� current.� In� Equation� 14,�
�the� required� time� for� this� commutation� is� t� 1� and� the�
�approximated� associated� power� loss� is� P� UP,1� .�
�P� UP� ,� 1� ≈� V� IN� ?� ------� +� ---------� ?� ?� ----� 1� ?� f� S�
�pushed� as� high� as� 30A� per� phase,� but� these� designs� require�
�heat� sinks� and� forced� air� to� cool� the� MOSFETs,� inductors�
�and� heat-dissipating� surfaces.�
�?� N� 2� ?� ?� 2� ?�
�I� M� I� PP� ?� t� ?�
�(EQ.� 14)�
�MOSFETs�
�The� choice� of� MOSFETs� depends� on� the� current� each�
�MOSFET� will� be� required� to� conduct;� the� switching� frequency;�
�At� turn� on,� the� upper� MOSFET� begins� to� conduct� and� this�
�transition� occurs� over� a� time� t� 2� .� In� Equation� 15,� the�
�approximate� power� loss� is� P� UP,2� .�
�?� I� M� I� PP� ?� ?� ?�
�P� UP� ,� 2� ≈� V� IN� ?� ------� –� ---------� ?� ?� ----� 2� ?� f� S�
�the� capability� of� the� MOSFETs� to� dissipate� heat;� and� the�
�availability� and� nature� of� heat� sinking� and� air� flow.�
�t�
�?� N� 2� ?� ?� 2� ?�
�(EQ.� 15)�
�P� UP� ,� 3� =� V� IN� Q� rr� f� S�
�LOWER� MOSFET� POWER� CALCULATION�
�The� calculation� for� heat� dissipated� in� the� lower� MOSFET� is�
�simple,� since� virtually� all� of� the� heat� loss� in� the� lower�
�MOSFET� is� due� to� current� conducted� through� the� channel�
�resistance� (r� DS(ON)� ).� In� Equation� 12,� I� M� is� the� maximum�
�continuous� output� current;� I� PP� is� the� peak-to-peak� inductor�
�current� (see� Equation� 1);� d� is� the� duty� cycle� (V� OUT� /V� IN� );� and�
�L� is� the� per-channel� inductance.�
�A� third� component� involves� the� lower� MOSFET’s� reverse-�
�recovery� charge,� Q� rr� .� Since� the� inductor� current� has� fully�
�commutated� to� the� upper� MOSFET� before� the� lower-�
�MOSFET’s� body� diode� can� draw� all� of� Q� rr� ,� it� is� conducted�
�through� the� upper� MOSFET� across� VIN.� The� power�
�dissipated� as� a� result� is� P� UP,3� and� is� approximately�
�(EQ.� 16)�
�?� I� M� ?� 2� I� L� ,� PP� (� 1� –� d� )�
�P� LOW� ,� 1� =� r� DS� (� ON� )� ?� ------� ?� (� 1� –� d� )� +� --------------------------------�
�?� N� ?� 12�
�(EQ.� 12)�
�Finally,� the� resistive� part� of� the� upper� MOSFET’s� is� given� in�
�Equation� 17� as� P� UP,4� .�
�An� additional� term� can� be� added� to� the� lower-MOSFET� loss�
�equation� to� account� for� additional� loss� accrued� during� the�
�dead� time� when� inductor� current� is� flowing� through� the�
�lower-MOSFET� body� diode.� This� term� is� dependent� on� the�
�diode� forward� voltage� at� I� M� ,� V� D(ON)� ;� the� switching� frequency,�
�f� S� ;� and� the� length� of� dead� times,� t� d1� and� t� d2� ,� at� the�
�beginning� and� the� end� of� the� lower-MOSFET� conduction�
�interval� respectively.�
�The� total� power� dissipated� by� the� upper� MOSFET� at� full� load�
�can� now� be� approximated� as� the� summation� of� the� results�
�from� Equations� 14,� 15,� 16� and� 17.� Since� the� power�
�equations� depend� on� MOSFET� parameters,� choosing� the�
�correct� MOSFETs� can� be� an� iterative� process� involving�
�repetitive� solutions� to� the� loss� equations� for� different�
�MOSFETs� and� different� switching� frequencies.�
�I� PP� ?�
�I� M�
�P� LOW� ,� 2� =� V� D� (� ON� )� f� S� ?� ------� +� I� ---------� ?� t�
�?� I�
�?� d1� +� ?� ?� ------� –� ---------� ?� ?� d2�
�t�
�?� N�
�?� I� M� ?�
�I� PP�
�P� UP� ,� 4� ≈� r� DS� (� ON� )� ?� ------� ?� d� +� ----------�
�PP� M�
�2� N� 2�
�18�
�(EQ.� 13)�
�2� 2�
�?� N� ?� 12�
�(EQ.� 17)�
�FN9097.4�
�December� 28,� 2004�
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相关代理商/技术参数 |
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| ISL6556BCRZ | 功能描述:IC CTRLR MULTIPHASE VRM10 32-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 |
| ISL6556BCRZA | 功能描述:IC CTRLR MULTIPHASE VRM10 32-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 |
| ISL6556BCRZA-T | 功能描述:IC CTRLR MULTIPHASE VRM10 32-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 |
| ISL6556BCRZ-T | 功能描述:IC CTRLR MULTIPHASE VRM10 32-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 |
| ISL6557 WAF | 制造商:Intersil Corporation 功能描述: |
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