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参数资料
| 型号: | MAX5003EVKIT |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 15/16页 |
| 文件大小: | 0K |
| 描述: | EVAL KIT FOR MAX5003 |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 1 |
| 主要目的: | DC/DC,步降 |
| 输出及类型: | 1,非隔离 |
| 输出电压: | 5V |
| 电流 - 输出: | 1A |
| 输入电压: | 36 ~ 72V |
| 稳压器拓扑结构: | 降压 |
| 频率 - 开关: | 300kHz |
| 板类型: | 完全填充 |
| 已供物品: | 板 |
| 已用 IC / 零件: | MAX5003 |
��
�
�High-Voltage� PWM�
�Power-Supply� Controller�
�zero� at� 2kHz,� the� crossover� frequency� is� 4kHz� and� the�
�phase� margin� is� 50°.�
�Given� the� above� considerations,� R� A� ,� R� B� ,� R� F� ,� and� C� F�
�can� be� chosen� (Figure� 2).� The� sum� of� R� A� and� R� B� is�
�chosen� for� low� current� drain.� In� the� example,� R� A� plus�
�R� B� is� 58k� ?� and� draws� 80μA.� The� following� ratio� sets�
�the� output� voltage:�
�R� B� /� (R� A� +� R� B� )� =� V� SET� /� V� OUT�
�Since� V� SET� =� 1.5V� and� V� OUT� =� 5V,� R� A� is� set� to� 41.2k� ?�
�and� R� B� to� 17.4k� ?� .�
�The� midband� gain� is� the� ratio� of� R� F� /R� A� .� R� B� does� not�
�desired� value,� the� center-point� voltage� will� be� 1.5V.� The�
�Thevenin� equivalent� of� the� resistors� must� be� low�
�enough� so� the� error� amplifier� bias� current� will� not� intro-�
�duce� a� division� error.� The� two� resistors� must� have� simi-�
�lar� temperature� coefficients� (tempcos),� so� the� dividing�
�ratio� will� be� constant� with� temperature.�
�Component� Selection�
�CS� Resistor�
�The� CS� resistor� is� connected� in� series� with� the� source�
�of� the� N-channel� MOSFET� and� ground,� sensing� the�
�switch� current.� Its� value� can� be� calculated� from� the� fol-�
�lowing� equation:�
�affect� the� gain� because� it� is� connected� to� a� virtual�
�ground.� For� a� midband� gain� of� 5,� the� feedback� resistor�
�equals� 200k� ?� .� To� set� the� zero� at� 2kHz,� the� capacitor�
�value� is:�
�C� F� =� 1� /� (2� π� x� R� F� x� f� z� )� =� 400pF�
�R� CS� =�
�100� mV�
�I� LIM� (� PRI� )�
�=�
�100� mV�
�2� PWR� OUT� (� MAX� )�
�L� PRI� ×� ?� SW� ×� η�
�� K� TOL�
�Layout� Recommendations�
�All� connections� carrying� pulsed� currents� must� be� very�
�short,� be� as� wide� as� possible,� and� have� a� ground� plane�
�behind� them� whenever� possible.� The� inductance� of�
�these� connections� must� be� kept� to� an� absolute� mini-�
�mum� due� to� the� high� di/dt� of� the� currents� in� high-�
�frequency� switching� power� converters.� In� the� develop-�
�ment� or� prototyping� process,� multipurpose� boards,� wire�
�wrap,� and� similar� constructive� practices� are� not� suit-�
�able� for� these� type� of� circuits;� attempts� to� use� them� will�
�fail.� Instead,� use� milled� PC� boards� with� a� ground� plane,�
�or� equivalent� techniques�
�Current� loops� must� be� analyzed� in� any� layout� pro-�
�posed,� and� the� internal� area� kept� to� a� minimum� to�
�reduce� radiated� EMI.� The� use� of� automatic� routers� is�
�discouraged� for� PC� board� layout� generation� in� the�
�board� area� where� the� high-frequency� switching� con-�
�verters� are� located.� Designers� should� carefully� review�
�the� layout.� In� particular,� pay� attention� to� the� ground�
�connections.� Ground� planes� must� be� kept� as� intact� as�
�possible.� The� ground� for� the� power-line� filter� capacitor�
�and� the� ground� return� of� the� power� switch� or� current-�
�sensing� resistor� must� be� close.� All� ground� connections�
�must� resemble� a� star� system� as� much� as� practical.�
�“Short� ”� and� “close� ”� are� dimensions� on� the� order� of�
�0.25in� to� 0.5in� (0.5cm� to� about� 1cm).�
�Setting� the� Output� Voltage�
�The� output� voltage� of� the� converter,� if� using� the� internal�
�error� amplifier,� can� easily� be� set� by� the� value� of� the� FB�
�pin� set� voltage.� This� value� is� 1.5V.� A� resistive� divider�
�must� be� calculated� from� the� output� line� to� ground,� with�
�a� dividing� ratio� such� that� when� the� output� is� at� the�
�where� η� =� efficiency� and� 0.5� <� KT� OL� <� 0.75.�
�K� TOL� includes� the� tolerance� of� the� sensing� resistor,� the�
�dispersion� of� the� MAX5003� CS� trip� point,� and� the�
�uncertainties� in� the� calculation� of� the� primary� maximum�
�current.�
�The� sensing� resistor� must� be� of� the� adequate� power�
�dissipation� and� low� tempco.� It� must� also� be� noninduc-�
�tive� and� physically� short.� Use� standard� surface-mount�
�CS� resistors.� A� 100� ?� resistor� is� recommended� between�
�the� CS� resistor� and� the� CS� pin.� If� the� current� surge� at�
�the� beginning� of� the� conduction� period� is� large� and� dis-�
�rupts� the� MAX5003� ’s� operation,� add� a� capacitor�
�between� the� CS� pin� and� PGND,� to� form� an� RC� filter.�
�Power� Switch�
�The� MAX5003� will� typically� drive� an� N-channel� MOSFET�
�power� switch.� The� maximum� drain� voltage,� maximum�
�R� DS(ON)� ,� and� total� gate� switching� charge� are� the� para-�
�meters� involved� in� choosing� the� FET.� The� maximum�
�gate� switching� charge� is� the� most� important� factor�
�defining� the� MAX5003� internal� power� consumption,�
�since� the� product� of� the� switching� frequency� and� the�
�total� gate� charge� is� the� IC� current� consumption.�
�R� DS(ON)� is� the� parameter� that� determines� the� total� con-�
�duction� power� losses� in� the� switch,� and� the� choice�
�depends� on� the� expected� efficiency� and� the� cooling�
�and� mounting� method.� The� maximum� drain� voltage�
�requirements� can� be� different� depending� on� the� topolo-�
�gy� used.� In� the� flyback� configuration,� the� maximum�
�voltage� is� the� maximum� supply� voltage� plus� the� reflect-�
�ed� secondary� voltage,� any� ringing� at� the� end� of� the�
�conduction� period,� and� the� spike� caused� by� the� leak-�
�age� inductance.� In� the� case� of� the� forward� converter,�
�the� reset� time� of� the� core� will� set� the� maximum� voltage�
�______________________________________________________________________________________�
�15�
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| MAX5003EVKIT50W | 功能描述:电压模式 PWM 控制器 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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| MAX5005ACUB | 功能描述:低压差稳压器 - LDO 150mA USB LDO RoHS:否 制造商:Texas Instruments 最大输入电压:36 V 输出电压:1.4 V to 20.5 V 回动电压(最大值):307 mV 输出电流:1 A 负载调节:0.3 % 输出端数量: 输出类型:Fixed 最大工作温度:+ 125 C 安装风格:SMD/SMT 封装 / 箱体:VQFN-20 |
| MAX5005ACUB+ | 功能描述:低压差稳压器 - LDO 150mA USB LDO RoHS:否 制造商:Texas Instruments 最大输入电压:36 V 输出电压:1.4 V to 20.5 V 回动电压(最大值):307 mV 输出电流:1 A 负载调节:0.3 % 输出端数量: 输出类型:Fixed 最大工作温度:+ 125 C 安装风格:SMD/SMT 封装 / 箱体:VQFN-20 |
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