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| 型号: | MAX15034BAUI+ |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 18/26页 |
| 文件大小: | 0K |
| 描述: | IC REG CTRLR BUCK PWM 28TSSOP-EP |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 50 |
| PWM 型: | 电流模式 |
| 输出数: | 1 或 2 |
| 频率 - 最大: | 1MHz |
| 电源电压: | 4.75 V ~ 5.5 V,5 V ~ 28 V |
| 降压: | 是 |
| 升压: | 无 |
| 回扫: | 无 |
| 反相: | 无 |
| 倍增器: | 无 |
| 除法器: | 无 |
| Cuk: | 无 |
| 隔离: | 无 |
| 工作温度: | -40°C ~ 125°C |
| 封装/外壳: | 28-SOIC(0.173",4.40mm 宽)裸露焊盘 |
| 包装: | 管件 |
��
�
�Configurable,� Single-/Dual-Output,� Synchronous�
�Buck� Controller� for� High-Current� Applications�
�V� OUT� (� V� IN� (� MAX� )� ?� V� OUT� )�
�� f�
�� ?� I�
�Design Procedures�
�Inductor� Selection�
�The� switching� frequency� per� phase,� peak-to-peak� ripple�
�current� in� each� phase,� and� allowable� voltage� ripple� at�
�the� output,� determine� the� inductance� value.� Selecting�
�higher� switching� frequencies� reduces� the� inductance�
�requirement,� but� at� the� cost� of� lower� efficiency� due� to�
�the� charge/discharge� cycle� of� the� gate� and� drain�
�capacitances� in� the� switching� MOSFETs.� The� situation�
�worsens� at� higher� input� voltages,� since� capacitive�
�switching� losses� are� proportional� to� the� square� of� the�
�input� voltage.� Lower� switching� frequencies� on� the� other�
�hand� increase� the� peak-to-peak� inductor� ripple� current�
�(� ?� I� L� ),� and� therefore,� increase� the� MOSFET� conduction�
�losses� (see� the� Power� MOSFET� Selection� section� for� a�
�detailed� description� of� MOSFET� power� loss).�
�When� using� higher� inductor� ripple� current,� the� ripple� can-�
�cellation� in� the� multiphase� topology,� reduces� the� input�
�and� output� capacitor� RMS� ripple� current.� Use� the� follow-�
�ing� equation� to� determine� the� minimum� inductance� value:�
�L� =�
�V� IN� SW� L�
�Choose� ?� I� L� to� be� equal� to� approximately� 30%� of� the� out-�
�put� current� per� channel.� Since� ?� I� L� affects� the� output-rip-�
�ple� voltage,� the� inductance� value� may� need� minor�
�adjustment� after� choosing� the� output� capacitors� for� full-�
�rated� efficiency.� Choose� inductors� from� the� standard�
�high-current,� surface-mount� inductor� series� available�
�from� various� manufacturers.� Particular� applications� may�
�require� custom-made� inductors.� Use� high-frequency� core�
�material� for� custom� inductors.� High� ?� I� L� causes� large�
�peak-to-peak� flux� excursion� increasing� the� core� losses� at�
�higher� frequencies.� The� high-frequency� operation� cou-�
�pled� with� high� ?� I� L� ,� reduces� the� required� minimum� induc-�
�tance� and� even� makes� the� use� of� planar� inductors�
�possible.� The� advantages� of� using� planar� magnetics�
�include� low-profile� design,� excellent� current� sharing�
�between� phases� due� to� the� tight� control� of� parasitics,� and�
�low� cost.� For� example,� the� minimum� inductance� at� V� IN� =�
�12V,� V� OUT� =� 0.8V,� ?� I� L� =� 3A,� and� f� SW� =� 500kHz� is� 0.5μH.�
�The� average� current-mode� control� feature� of� the�
�MAX15034� limits� the� maximum� inductor� current,� which�
�prevents� the� inductor� from� saturating.� Choose� an�
�inductor� with� a� saturating� current� greater� than� the�
�worst-case� peak� inductor� current:�
�where� 24.75mV� is� the� maximum� average� current-limit�
�threshold� for� the� current-sense� amplifier� and� R� SENSE� is�
�the� sense� resistor.�
�Power� MOSFET� Selection�
�When� choosing� the� MOSFETs,� consider� the� total� gate�
�charge,� R� DS(ON)� ,� power� dissipation,� the� maximum�
�drain-to-source� voltage,� and� package� thermal� imped-�
�ance.� The� product� of� the� MOSFET� gate� charge� and� on-�
�resistance� is� a� figure� of� merit,� with� a� lower� number�
�signifying� better� performance.� Choose� MOSFETs� opti-�
�mized� for� high-frequency� switching� applications.� The�
�average� gate-drive� current� from� the� MAX15034’s� output�
�is� proportional� to� the� total� capacitance� it� drives� at� DH1,�
�DH2,� DL1,� and� DL2.� The� power� dissipated� in� the�
�MAX15034� is� proportional� to� the� input� voltage� and� the�
�average� drive� current.� See� the� Supply� Voltage�
�Connections� (V� IN� /V� REG� )� and� the� Low-Side� MOSFET�
�Drives� Supply� (V� DD� )� sections� to� determine� the� maxi-�
�mum� total� gate� charge� allowed� from� all� driver� outputs�
�together.�
�The� losses� may� be� broken� into� four� categories:� conduc-�
�tion� loss,� gate� drive� loss,� switching� loss,� and� output� loss.�
�The� following� simplified� power� loss� equation� is� true� for�
�both� MOSFETs� in� the� synchronous� buck-converter:�
�P� LOSS� =� P� CONDUCTION� +� P� GATEDRIVE�
�+� P� SWITCH� +� P� OUTP� U� T�
�For� the� low-side� MOSFET,� the� P� SWITCH� term� becomes�
�virtually� zero� because� the� body� diode� of� the� MOSFET� is�
�conducting� before� the� MOSFET� is� turned� on.�
�Tables� 1� and� 2� describe� the� different� losses� and� shows�
�an� approximation� of� the� losses� during� that� period.�
�Input� Capacitance�
�The� discontinuous� input-current� waveform� of� the� buck�
�converter� causes� large� ripple� currents� in� the� input�
�capacitor.� The� switching� frequency,� peak� inductor� cur-�
�rent,� and� the� allowable� peak-to-peak� voltage� ripple�
�reflected� back� to� the� source,� dictate� the� capacitance�
�requirement.� Increasing� the� number� of� phases� increas-�
�es� the� effective� switching� frequency� and� lowers� the�
�peak-to-average� current� ratio,� yielding� lower� input�
�capacitance� requirement.� It� can� be� shown� that� the�
�worst-case� RMS� current� occurs� when� only� one� con-�
�troller� section� is� operating.� The� controller� section� with�
�the� highest� output� power� needs� to� be� used� in� determin-�
�I� L� _� PEAK� =�
�24� .� 75� � 10� ?� 3�
�R� SENSE�
�+�
�?� I� L�
�2�
�ing� the� maximum� input� RMS� ripple� current� requirement.�
�Increasing� the� output� current� drawn� from� the� other� out-�
�of-phase� controller� section� results� in� reducing� the� input�
�18�
�______________________________________________________________________________________�
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相关代理商/技术参数 |
参数描述 |
|---|---|
| MAX15034BAUI+ | 功能描述:DC/DC 开关控制器 Configurable Synchronous Buck 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 |
| MAX15034BAUI+T | 功能描述:DC/DC 开关控制器 Configurable Synchronous Buck 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 |
| MAX15034BEVKIT+ | 功能描述:电源管理IC开发工具 MAX15034B Eval Kit RoHS:否 制造商:Maxim Integrated 产品:Evaluation Kits 类型:Battery Management 工具用于评估:MAX17710GB 输入电压: 输出电压:1.8 V |
| MAX15035ETL+ | 功能描述:电压模式 PWM 控制器 15A Step-Down Reg w/Internal Switch RoHS:否 制造商:Texas Instruments 输出端数量:1 拓扑结构:Buck 输出电压:34 V 输出电流: 开关频率: 工作电源电压:4.5 V to 5.5 V 电源电流:600 uA 最大工作温度:+ 125 C 最小工作温度:- 40 C 封装 / 箱体:WSON-8 封装:Reel |
| MAX15035ETL+T | 功能描述:电压模式 PWM 控制器 15A Step-Down Reg w/Internal Switch RoHS:否 制造商:Texas Instruments 输出端数量:1 拓扑结构:Buck 输出电压:34 V 输出电流: 开关频率: 工作电源电压:4.5 V to 5.5 V 电源电流:600 uA 最大工作温度:+ 125 C 最小工作温度:- 40 C 封装 / 箱体:WSON-8 封装:Reel |
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