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| 型号: | NCP3125CRAGEVB |
| 厂商: | ON Semiconductor |
| 文件页数: | 12/22页 |
| 文件大小: | 0K |
| 描述: | BOARD EVALUATION NCP3125 CERAMIC |
| 设计资源: | NCP3125 Schematic NCP3125CRAGEVB BOM |
| 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: | 最低可调至 0.8V |
| 电流 - 输出: | 4A |
| 输入电压: | 4.5 ~ 13.2 V |
| 稳压器拓扑结构: | 降压 |
| 频率 - 开关: | 350kHz |
| 板类型: | 完全填充 |
| 已供物品: | 板 |
| 已用 IC / 零件: | NCP3125 |
| 其它名称: | NCP3125CRAGEVBOS |
��
�
�NCP3125�
�In� a� typical� converter� design,� the� ESR� of� the� output�
�capacitor� bank� dominates� the� transient� response.� Please� note�
�that� D� V� OUT� ?� DIS� and� D� V� OUT� ?� ESR� are� out� of� phase� with� each�
�other,� and� the� larger� of� these� two� voltages� will� determine� the�
�maximum� deviation� of� the� output� voltage� (neglecting� the�
�effect� of� the� ESL).�
�Input� Capacitor� Selection�
�The� input� capacitor� has� to� sustain� the� ripple� current�
�produced� during� the� on� time� of� the� upper� MOSFET,� so� it�
�Starting� with� the� high� ?� side� MOSFET,� the� power�
�dissipation� can� be� approximated� from:�
�P� D_HS� +� P� COND� )� P� SW_TOT� (eq.� 21)�
�P� COND� =� Conduction� power� losses�
�P� SW_TOT� =� Total� switching� losses�
�P� D_HS� =� Power� losses� in� the� high� side� MOSFET�
�The� first� term� in� Equation� 21� is� the� conduction� loss� of� the�
�high� ?� side� MOSFET� while� it� is� on.�
�must� have� a� low� ESR� to� minimize� the� losses.� The� RMS� value�
�of� the� input� ripple� current� is:�
�P� COND� +� I� RMS_HS�
�2�
�@� R� DS(on)_HS�
�(eq.� 22)�
�Iin� RMS� +� I� OUT� D� (1� *� D)� 3�
�1.79� A� +� 4� A� *� 27.5� *� (1� *� 27.5)�
�(eq.� 19)�
�I� RMS_HS�
�R� DS(on)_HS�
�P� cond�
�=� RMS� current� in� the� high� ?� side� MOSFET�
�=� On� resistance� of� the� high� ?� side� MOSFET�
�=� Conduction� power� losses�
�I� RMS_HS� +� I� OUT� @�
�D� @� 1� )�
�D� =� Duty� ratio�
�IIN� RMS� =� Input� capacitance� RMS� current�
�I� OUT� =� Load� current�
�The� equation� reaches� its� maximum� value� with� D� =� 0.5.�
�Using� the� ra� term� from� Equation� 5,� I� RMS� becomes:�
�ra� 2�
�12�
�(eq.� 23)�
�P� CIN� +� CIN� ESR� *� IiN� RMS� 3�
�32� mW� +� 10� m� W� *� 1.79� A�
�Loss� in� the� input� capacitors� can� be� calculated� with� the�
�following� equation:�
�2�
�(eq.� 20)�
�2�
�CIN� ESR� =� Input� capacitance� Equivalent� Series�
�Resistance�
�IIN� RMS� =� Input� capacitance� RMS� current�
�P� CIN� =� Power� loss� in� the� input� capacitor�
�Due� to� large� di/dt� through� the� input� capacitors,� electrolytic�
�or� ceramics� should� be� used.� If� a� tantalum� must� be� used,� it�
�must� be� surge� protected,� otherwise,� capacitor� failure� could�
�occur.�
�Power� MOSFET� Dissipation�
�MOSFET� power� dissipation,� package� size,� and� the�
�I� RMS_HS� =� High� side� MOSFET� RMS� current�
�I� OUT� =� Output� current�
�D� =� Duty� ratio�
�ra� =� Ripple� current� ratio�
�The� second� term� from� Equation� 21� is� the� total� switching�
�loss� and� can� be� approximated� from� the� following� equations.�
�P� SW_TOT� +� P� SW� )� P� DS� )� P� RR� (eq.� 24)�
�P� DS� =� High� side� MOSFET� drain� source� losses�
�P� RR� =� High� side� MOSFET� reverse� recovery� losses�
�P� SW� =� High� side� MOSFET� switching� losses�
�P� SW_TOT� =� High� side� MOSFET� total� switching� losses�
�The� first� term� for� total� switching� losses� from� Equation� 24�
�are� the� losses� associated� with� turning� the� high� ?� side�
�MOSFET� on� and� off� and� the� corresponding� overlap� in� drain�
�voltage� and� current.�
�thermal� environment� drive� power� supply� design.� Once� the�
�dissipation� is� known,� the� thermal� impedance� can� be�
�calculated� to� prevent� the� specified� maximum� junction�
�P� SW� +� P� TON� )� P� TOFF�
�2�
�+� 1� @� I� OUT� @� V� IN� @� F� SW� @� t� RISE� )� t� FALL�
�(eq.� 25)�
�temperatures� from� being� exceeded� at� the� highest� ambient�
�temperature.�
�Power� dissipation� has� two� primary� contributors:�
�conduction� losses� and� switching� losses.� The� high� ?� side�
�MOSFET� will� display� both� switching� and� conduction�
�losses.� The� switching� losses� of� the� low� side� MOSFET� will�
�not� be� calculated� as� it� switches� into� nearly� zero� voltage� and�
�the� losses� are� insignificant.� However,� the� body� diode� in� the�
�low� ?� side� MOSFET� will� suffer� diode� losses� during� the�
�F� SW�
�I� OUT�
�t� FALL�
�t� RISE�
�V� IN�
�P� SW�
�P� TON�
�P� TOFF�
�=� Switching� frequency�
�=� Load� current�
�=� MOSFET� fall� time�
�=� MOSFET� rise� time�
�=� Input� voltage�
�=� High� side� MOSFET� switching� losses�
�=� Turn� on� power� losses�
�=� Turn� off� power� losses�
�non� ?� overlap� time� of� the� gate� drivers.�
�http://onsemi.com�
�12�
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| NCP3126ADR2G | 功能描述:直流/直流开关转换器 3A PWM Switching Buck Regulator RoHS:否 制造商:STMicroelectronics 最大输入电压:4.5 V 开关频率:1.5 MHz 输出电压:4.6 V 输出电流:250 mA 输出端数量:2 最大工作温度:+ 85 C 安装风格:SMD/SMT |
| NCP3126AGEVB | 功能描述:电源管理IC开发工具 NCP3126 EVB 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 |
| NCP3126CRAGEVB | 功能描述:电源管理IC开发工具 NCP3126 CERAMIC EVB 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 |
| NCP3127ADR2G | 功能描述:直流/直流开关转换器 2A PWM Switching Buck Regulator RoHS:否 制造商:STMicroelectronics 最大输入电压:4.5 V 开关频率:1.5 MHz 输出电压:4.6 V 输出电流:250 mA 输出端数量:2 最大工作温度:+ 85 C 安装风格:SMD/SMT |
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