参数资料
| 型号: | ISL6217CV-T |
| 厂商: | Intersil |
| 文件页数: | 15/19页 |
| 文件大小: | 0K |
| 描述: | IC CTRLR PWM INTEL PENT 38-TSSOP |
| 标准包装: | 2,500 |
| 应用: | 控制器,Intel Pentium? IMVP-IV,IMVP+ |
| 输入电压: | 5.5 V ~ 25 V |
| 输出数: | 1 |
| 工作温度: | -10°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 38-TFSOP(0.173",4.40mm 宽) |
| 供应商设备封装: | 38-TSSOP |
| 包装: | 带卷 (TR) |
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�ISL6217�
�Control� Loops�
�The� “Block� Diagram”� and� Figure� 9� shows� a� simplified�
�diagram� of� the� voltage� regulation� and� current� control� loops�
�for� a� two-phase� converter.� Both� voltage� and� current�
�feedback� are� used� to� precisely� regulate� voltage� and� tightly�
�control� output� currents,� IL1� and� IL2,� of� the� two� power�
�channels.� The� voltage� loop� is� comprised� of� the� Error�
�Amplifier,� Comparators,� Internal� Gate� Drivers,� and�
�MOSFETs.� The� Error� Amplifier� drives� the� modulator� to� force�
�the� FB� pin� to� the� IMVP-IV?� and� IMVP-IV+?� reference�
�minus� “Droop”.�
�Voltage� Loop�
�The� output� CORE� voltage� feedback� is� applied� to� the� Error�
�Amplifier� through� the� compensation� network.� The� signal�
�seen� on� the� FB� pin� will� drive� the� Error� Amplifier� output� either�
�high� or� low,� depending� on� the� CORE� voltage.� A� CORE�
�voltage� level� that� is� lower� than� the� IMVP-IV?� and�
�IMVP-IV+?� reference,� as� output� from� the� 6� bit� DAC,� makes�
�the� amplifier� output� move� towards� a� higher� output� voltage�
�level.� The� amplifier� output� voltage� is� applied� to� the� positive�
�inputs� of� the� comparators� by� the� BALANCE� summing�
�networks.� Out-of-phase� sawtooth� signals� are� applied� to� the�
�two� comparators’� inverting� inputs.� Increasing� Error� Amplifier�
�voltage� results� in� increased� Comparator� output� duty� cycle.�
�This� increased� duty� cycle� signal� is� passed� through� the� PWM�
�circuit� to� the� internal� gate-drive� circuitry.� The� output� of� the�
�internal� gate-drive� is� directly� connected� to� the� gate� of� the�
�MOSFETs.� Increased� duty� cycle� or� ON-time� for� the� high� side�
�MOSFET� transistors� results� in� increased� output� voltage,�
�VCORE,� to� compensate� for� the� low� output� voltage� sensed.�
�Current� Loop�
�The� current� control� loop� keeps� the� channel� currents� in�
�balance.� During� the� PWM� off-time� of� each� channel,� the�
�voltage� VrDS(ON),� developed� across� the� lower� MOSFET� is�
�sampled.� Internally,� the� ISEN� pin� is� held� at� virtual� ground�
�during� this� interval,� and� VrDS(ON)� is� impressed� across� the�
�RISEN� resistor.� This� provides� current� feedback� proportional�
�to� the� output� current� of� each� channel.� The� scaled� output�
�currents� from� all� active� channels� are� combined� to� create� an�
�average� current� reference� IAVERAGE,� proportional� to� the�
�converter� total� output� current.� This� signal� is� then� subtracted�
�from� the� individual� channel� scaled� output� currents� to�
�produce� a� current� correction� signal� for� each� channel.� The�
�current� correction� signal� keeps� each� channel� output� current�
�contribution� balanced� relative� to� the� other� active� channels.�
�Each� current� correction� signal� is� subtracted� from� the� error�
�amplifier� output� and� fed� to� the� individual� channel� PWM�
�circuits.� For� example,� assume� the� voltage� sampled� across�
�Droop� Compensation�
�Microprocessors� and� other� peripherals� tend� to� change� their�
�load� current� demands� from� near� no-load� to� full� load� often�
�during� operation.� These� same� devices� require� minimal�
�output� voltage� deviation� during� a� load� step.�
�A� high� di/dt� load� step� will� cause� an� output� voltage� spike.�
�The� amplitude� of� the� spike� is� dictated� by� the� output�
�capacitor� ESR,� multiplied� by� the� load� step� magnitude,� plus�
�the� output� capacitor� ESL,� times� the� load� step� di/dt.� A�
�positive� load� step� produces� a� negative� output� voltage� spike�
�and� vice� versa.� A� large� number� of� low-series-impedance�
�capacitors� are� often� used� to� prevent� the� output� voltage�
�deviation� from� exceeding� the� tolerance� of� some� devices.�
�One� widely� accepted� solution� to� this� problem� is� output�
�voltage� “Droop”,� or� active� voltage� positioning.�
�As� shown� in� Figure� 3� and� Figure� 9,� the� average� channel�
�current� is� used� to� control� the� “Droop”� current� source,�
�IDROOP.� The� “Droop”� current� source� is� a� controlled� current�
�source� and� is� proportional� to� output� current.� This� current�
�source� is� approximately� 87%� of� the� averaged� ISEN�
�currents.� The� Droop� current� is� sourced� out� of� the� SOFT� pin�
�through� the� Droop� resistor� and� returns� through� the� EA+� pin.�
�This� creates� a� “Droop”� voltage� VDROOP,� which� subtracts�
�from� the� IMVP-IV?� and� IMVP-IV+?� reference� voltage� on�
�SOFT� to� generate� the� voltage� setpoint� for� the� CORE�
�regulator.�
�Full� load� current� for� the� Intel� IMVP-IV?� and� IMVP-IV+?�
�specification� is� 25� amps.� ISEN� currents� are� designed� to� be�
�32μA� for� this� load.� Knowing� that� the� Droop� Current,�
�sourced� out� of� the� SOFT� pin,� will� be� 87%� of� the� ISEN�
�averaged� currents,� a� “Droop”� resistor� RDROOP,� can� be�
�selected� to� provide� the� amount� of� voltage� “Droop”� required�
�at� full� load.� The� selection� of� this� resistor� is� explained� in� the�
�following� section.�
�A� choice� of� RISEN� and� rDS(ON)� giving� a� sense� current�
�value� other� than� 32μA� at� full� load,� will� require� proportional�
�adjustments� in� RDROOP� and� ROCSET.� This� may� happen,�
�as� the� PTC� is� not� found� in� every� possible� resistance� value.�
�Selection� of� RDROOP�
�Figure� 11� shows� a� static� “Droop”� load� line� for� the� 1.484V�
�Active� Mode.� The� ISL6217,� as� previously� mentioned,�
�allows� the� programming� of� the� load� line� slope� by� the�
�selection� of� the� RDROOP� resistor.�
�(0A,1.506V)�
�(0A,1.484V)�
�Q4� in� Figure� 9� is� higher� than� that� sampled� across� Q2.� The�
�ISEN2� current� would� be� higher� than� ISEN1.� When� the� two�
�reference� currents� are� averaged,� they� accurately� represent�
�the� total� output� current� of� the� converter.� The� reference�
�current� IAVERAGE� is� then� subtracted� from� the� ISEN�
�currents.� This� results� in� a� positive� offset� for� Channel� 2� and� a�
�V� OUT,HI�
�V� OUT,NOM�
�V� OUT,LO�
�(0A,1.462V)�
�(25A,1.431V)�
�(25A,1.409V)�
�(25A,1.387V)�
�negative� offset� for� Channel� 1.� These� offsets� are� subtracted�
�from� the� error� amplifier� signal� and� perform� phase� balance�
�correction.� The� VERROR2� signal� is� reduced,� while�
�VERROR1� would� be� increased.� The� PWM� circuit� would� then�
�-3� m� _�
�load� line�
�I� OUT,NL�
�I� OUT,MID�
�I� OUT,MAX�
�reduce� the� pulse� width� to� lower� the� output� current�
�contribution� by� Channel� 2,� while� doing� the� opposite� to�
�STATIC� TOLERANCE� BANDS�
�NOMINAL� "DROOP"� LOAD� LINE�
�Channel� 1,� thereby� balancing� channel� currents.�
�FIGURE� 11.� IMVP-IV?� AND� IMVP-IV+?� ACTIVE� MODE�
�STATIC� LOAD� LINE�
�15�
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相关代理商/技术参数 |
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| ISL6217CVZ | 功能描述:IC CTRLR PWM INTEL PENT 38-TSSOP 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 |
| ISL6217CVZA | 制造商:INTERSIL 制造商全称:Intersil Corporation 功能描述:Precision Multi-Phase Buck PWM Precision Multi-Phase Buck PWM Positioning IMVP-IV? and IMVP-IV+ |
| ISL6217CVZA-T | 制造商:INTERSIL 制造商全称:Intersil Corporation 功能描述:Precision Multi-Phase Buck PWM Precision Multi-Phase Buck PWM Positioning IMVP-IV? and IMVP-IV+ |
| ISL6217CVZ-T | 功能描述:IC CTRLR PWM INTEL PENT 38-TSSOP 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 |
| ISL6217EVAL2 | 制造商:Intersil Corporation 功能描述:PURCHASE ISL6216EVAL1, ISL6217EVAL2 OR ISL6218EVAL2 WITH IS - Bulk |
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