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参数资料
| 型号: | ADP3207CJCPZ-RL |
| 厂商: | ON Semiconductor |
| 文件页数: | 23/32页 |
| 文件大小: | 0K |
| 描述: | IC CTLR SYNC BUCK 7BIT 40-LFCSP |
| 标准包装: | 2,500 |
| 应用: | 控制器,Intel IMVP-6 |
| 输入电压: | 3.3 V ~ 22 V |
| 输出数: | 3 |
| 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: | 40-VFQFN 裸露焊盘,CSP |
| 供应商设备封装: | 40-LFCSP-VQ(6x6) |
| 包装: | 带卷 (TR) |
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�ADP3207C�
�R� T� +� *� 5� k� W�
�I� R� +�
�f� SW�
�Application� Information�
�The� design� parameters� for� a� typical� Intel� IMVP6� ?� compliant�
�CPU� core� VR� application� are� as� follows:�
�?� Maximum� input� voltage� (V� INMAX� )� =� 19� V�
�?� Minimum� input� voltage� (V� INMIN� )� =� 7.0� V�
�?� Output� voltage� by� VID� setting� (V� VID� )� =� 1.150� V�
�?� Maximum� output� current� (I� O� )� =� 44� A�
�?� Load� line� slope� (R� O� )� =� 2.1� m� W�
�?� Maximum� output� current� step� (� D� I� O� )� =� 34.5� A�
�?� Maximum� output� thermal� current� (I� OTDC� )� =� 32� A�
�?� Number� of� phases� (n)� =� 2�
�?� Switching� frequency� per� phase� (f� SW� )� =� 280� kHz�
�?� Duty� cycle� at� maximum� input� voltage� (D� MIN� )� =� 0.061�
�?� Duty� cycle� at� minimum� input� voltage� (D� MAX� )� =� 0.164�
�Setting� the� Clock� Frequency� for� PWM� Mode�
�In� PWM� mode� operation,� the� ADP3207C� uses� a�
�fixed� ?� frequency� control� architecture.� The� frequency� is� set�
�by� an� external� timing� resistor� (R� T� ).� The� clock� frequency� and�
�the� number� of� phases� determine� the� switching� frequency� per�
�phase,� which� directly� relates� to� switching� losses� and� the�
�sizes� of� the� inductors� and� input� and� output� capacitors.� In� a�
�2� ?� phase� design,� a� clock� frequency� of� 560� kHz� sets� the�
�switching� frequency� to� 280� kHz� per� phase.� This� selection�
�represents� a� trade� ?� off� between� the� switching� losses� and� the�
�minimum� sizes� of� the� output� filter� components.� To� achieve�
�a� 560� kHz� oscillator� frequency� at� VID� voltage� 1.150� V,� R� T�
�has� to� be� 237� k� W� .� Alternatively,� the� value� for� R� T� can� be�
�calculated� using:�
�V� VID� )� 1.0� V�
�n� f� SW� 16� pF� (eq.� 1)�
�where� 16� pF� and� 5� k� W� are� internal� IC� component� values.� For�
�good� initial� accuracy� and� frequency� stability,� it� is�
�recommended� to� use� a� 1%� resistor.�
�Current� Monitor� Output�
�The� I� MON� pin� output� a� current� proportional� to� the� inductor�
�current.�
�Inductor� Selection�
�The� choice� of� inductance� determines� the� ripple� current� in�
�the� inductor.� Less� inductance� leads� to� more� ripple� current,�
�which� increases� the� output� ripple� voltage� and� conduction�
�losses� in� the� MOSFETs.� However,� this� allows� the� use� of�
�smaller� size� inductors,� and� for� a� specified� peak� ?� to� ?� peak�
�transient� deviation,� it� allows� less� total� output� capacitance.�
�Conversely,� a� higher� inductance� means� lower� ripple� current�
�and� reduced� conduction� losses� but� requires� larger� size�
�inductors� and� more� output� capacitance� for� the� same�
�peak� ?� to� ?� peak� transient� deviation.� In� a� multi� ?� phase� converter,�
�the� practical� peak� ?� to� ?� peak� inductor� ripple� current� is� less� than�
�50%� of� the� maximum� dc� current� in� the� same� inductor.�
�Equation� 2� shows� the� relationship� between� the� inductance,�
�oscillator� frequency,� and� peak� ?� to� ?� peak� ripple� current.�
�Equation� 3� can� be� used� to� determine� the� minimum� inductance�
�based� on� a� given� output� ripple� voltage.�
�V� VID� 1� *� D� MIN�
�L� (eq.� 2)�
�V� VID� R� O� (1� *� (n� D� MIN))� (1� *� D� MIN� )�
�L� w�
�f� SW� V� RIPPLE� (eq.� 3)�
�Solving� Equation� 3� for� a� 20� mV� peak� ?� to� ?� peak� output� ripple�
�voltage� yields:�
�1.150 V 2.1 m� W� (1� *� (2 0.061)) (1� *� 0.061)�
�L� w�
�280� kHz� 20� mV�
�+� 356� nH� (eq.� 4)�
�If� the� ripple� voltage� ends� up� being� less� than� the� initially�
�selected� value,� then� the� inductor� can� be� changed� to� a� smaller�
�value� until� the� ripple� value� is� met.� This� iteration� allows�
�optimal� transient� response� and� minimum� output� decoupling.�
�The� smallest� possible� inductor� should� be� used� to� minimize�
�the� number� of� output� capacitors.� For� this� example,� choosing�
�a� 360� nH� inductor� is� a� good� starting� point� and� gives� a�
�calculated� ripple� current� of� 10.7� A.� The� inductor� should� not�
�saturate� at� the� peak� current� of� 27.4� A� and� should� be� able� to�
�handle� the� sum� of� the� power� dissipation� caused� by� the�
�average� current� of� 16� A� in� the� winding� and� core� loss.�
�Another� important� factor� in� the� inductor� design� is� the�
�DCR,� which� is� used� to� measure� phase� currents.� A� large� DCR�
�causes� excessive� power� losses,� though� too� small� a� value�
�leads� to� increased� measurement� error.� This� example� uses� an�
�inductor� with� a� DCR� of� 0.89� m� W� .�
�Selecting� a� Standard� Inductor�
�Once� the� inductance� and� DCR� are� known,� the� next� step� is�
�to� either� design� an� inductor� or� select� a� standard� inductor� that�
�comes� as� close� as� possible� to� meeting� the� overall� design� goals.�
�It� is� also� important� to� have� the� inductance� and� DCR� tolerance�
�specified� to� keep� the� accuracy� of� the� system� controlled;� 20%�
�inductance� and� 15%� DCR� (at� room� temperature)� are�
�reasonable� expectations� that� most� manufacturers� can� meet.�
�Power� Inductor� Manufacturers�
�The� following� companies� provide� surface� mount� power�
�inductors� optimized� for� high� power� applications� upon�
�request:�
�?� Vishay� Dale� Electronics,� Inc.�
�?� Panasonic�
�?� Sumida� Corporation�
�?� NEC� Tokin� Corporation�
�Output� Droop� Resistance�
�The� inductor� design� requires� that� the� regulator� output�
�voltage� measured� at� the� CPU� pins� drops� when� the� output�
�current� increases.� The� specified� voltage� drop� corresponds� to�
�a� dc� output� resistance� (R� O� ).�
�The� output� current� is� measured� by� summing� the� currents� of�
�the� resistors� monitoring� the� voltage� across� each� inductor� and�
�http://onsemi.com�
�23�
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相关代理商/技术参数 |
参数描述 |
|---|---|
| ADP3207D | 制造商:ONSEMI 制造商全称:ON Semiconductor 功能描述:7-Bit Programmable, Multi-Phase Mobile, CPU Synchronous Buck |
| ADP3207DJCPZ-RL | 功能描述:DC/DC 开关控制器 IMVP6 BUCK CONTROLLER RoHS:否 制造商:Texas Instruments 输入电压:6 V to 100 V 开关频率: 输出电压:1.215 V to 80 V 输出电流:3.5 A 输出端数量:1 最大工作温度:+ 125 C 安装风格: 封装 / 箱体:CPAK |
| ADP3207JCPZ-RL | 功能描述:DC/DC 开关控制器 IMVP6 MLTI/PHSE CNTR RoHS:否 制造商:Texas Instruments 输入电压:6 V to 100 V 开关频率: 输出电压:1.215 V to 80 V 输出电流:3.5 A 输出端数量:1 最大工作温度:+ 125 C 安装风格: 封装 / 箱体:CPAK |
| ADP3208AJCPZ-RL | 功能描述:肖特基二极管与整流器 IMVP6 MLT-PH CTRL W/DRVR RoHS:否 制造商:Skyworks Solutions, Inc. 产品:Schottky Diodes 峰值反向电压:2 V 正向连续电流:50 mA 最大浪涌电流: 配置:Crossover Quad 恢复时间: 正向电压下降:370 mV 最大反向漏泄电流: 最大功率耗散:75 mW 工作温度范围:- 65 C to + 150 C 安装风格:SMD/SMT 封装 / 箱体:SOT-143 封装:Reel |
| ADP3208C | 制造商:ONSEMI 制造商全称:ON Semiconductor 功能描述:7-Bit,Programmable,Dual- Phase,Mobile,CPU,Synchronous Buck Controller |
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