参数资料
| 型号: | NCP3126ADR2G |
| 厂商: | ON Semiconductor |
| 文件页数: | 10/23页 |
| 文件大小: | 0K |
| 描述: | IC REG BUCK SYNC ADJ 3A 8SOIC |
| 标准包装: | 1 |
| 类型: | 降压(降压) |
| 输出类型: | 可调式 |
| 输出数: | 1 |
| 输出电压: | 可调至 0.8V |
| 输入电压: | 4.5 V ~ 13.2 V |
| PWM 型: | 电压模式 |
| 频率 - 开关: | 350kHz |
| 电流 - 输出: | 3A |
| 同步整流器: | 是 |
| 工作温度: | -40°C ~ 125°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 8-SOIC(0.154",3.90mm 宽) |
| 包装: | 标准包装 |
| 供应商设备封装: | 8-SOICN |
| 其它名称: | NCP3126ADR2GOSDKR |
��
�
�NCP3126�
�when� using� electrolytic� capacitors,� a� lower� ripple� current�
�will� result� in� lower� output� ripple� due� to� the� higher� ESR� of�
�electrolytic� capacitors.� The� ratio� of� ripple� current� to�
�maximum� output� current� is� given� in� Equation� 5.�
�I� OUT� =� Output� current�
�I� PK� =� Inductor� peak� current�
�ra� =� Ripple� current� ratio�
�A� standard� inductor� should� be� found� so� the� inductor� will�
�ra� +� D� I� 3� 28%� +�
�Iout�
�0.84 A�
�3A�
�(eq.� 5)�
�be� rounded� to� 6.8� m� H.� The� inductor� should� also� support� an�
�RMS� current� of� 3.01� A� and� a� peak� current� of� 3.42� A.�
�The� final� selection� of� an� output� inductor� has� both�
�L� OUT� +�
�V� OUT�
�I� OUT� @� ra� @� F� SW�
�6.73� m� H� +�
�@� (1� *� 27.5%)�
�SlewRate� LOUT� +� 3� 1.41�
�L� OUT�
�D� I� =� Ripple� current�
�I� OUT� =� Output� current�
�ra� =� Ripple� current� ratio�
�Using� the� ripple� current� rule� of� thumb,� the� user� can�
�establish� acceptable� values� of� inductance� for� a� design� using�
�Equation� 6.�
�@� (1� *� D)� 3�
�(eq.� 6)�
�3.3� V�
�3� A� @� 28%� @� 350� kHz�
�D� =� Duty� ratio�
�F� SW� =� Switching� frequency�
�I� OUT� =� Output� current�
�L� OUT� =� Output� inductance�
�ra� =� Ripple� current� ratio�
�20�
�mechanical� and� electrical� considerations.� From� a�
�mechanical� perspective,� smaller� inductor� values� generally�
�correspond� to� smaller� physical� size.� Since� the� inductor� is�
�often� one� of� the� largest� components� in� the� regulation� system,�
�a� minimum� inductor� value� is� particularly� important� in� space�
�constrained� applications.� From� an� electrical� perspective,� the�
�maximum� current� slew� rate� through� the� output� inductor� for�
�a� buck� regulator� is� given� by� Equation� 9.�
�V� IN� *� V� OUT� A�
�m� s�
�(eq.� 9)�
�12 V� *� 3.3 V�
�+�
�6.8� m� H�
�L� OUT� =� Output� inductance�
�V� IN� =� Input� voltage�
�V� OUT� =� Maximum� output� voltage�
�Equation� 9� implies� that� larger� inductor� values� limit� the�
�regulator� ’s� ability� to� slew� current� through� the� output�
�18�
�16�
�14�
�12�
�10�
�V� IN� =� 12� V�
�inductor� in� response� to� output� load� transients.� Consequently,�
�output� capacitors� must� supply� the� load� current� until� the�
�inductor� current� reaches� the� output� load� current� level.�
�Reduced� inductance� to� increase� slew� rates� results� in� larger�
�values� of� output� capacitance� to� maintain� tight� output� voltage�
�regulation.� In� contrast,� smaller� values� of� inductance� increase�
�the� regulator� ’s� maximum� achievable� slew� rate� and� decrease�
�Selected�
�V� IN� =� 8� V�
�V� IN� =� 4.2� V�
�V� OUT� (1� *� D)�
�L� OUT� @� F� SW�
�0.84� A� +�
�8�
�6�
�4�
�2�
�10� 13� 16� 19� 22� 25� 28� 31� 34� 37�
�CURRENT� RIPPLE� RATIO� (%)�
�Figure� 21.� Inductance� vs.� Current� Ripple� Ratio�
�40�
�the� necessary� capacitance,� at� the� expense� of� higher� ripple�
�current.� The� peak� ?� to� ?� peak� ripple� current� for� NCP3126� is�
�given� by� the� following� equation:�
�Ipp� +� 3�
�(eq.� 10)�
�3.3 V (1� *� 27.5%)�
�6.8� m� H� @� 350� kHz�
�1� )� ra� 3�
�I� RMS� +� I� OUT� @�
�12�
�3.01� A� +� 3� A� *� 1� )�
�I� PK� +� I� OUT� @� 1� )�
�3� 3.42� A� +� 3� A� @� 1� )�
�When� selecting� an� inductor,� the� designer� must� not� exceed�
�the� current� rating� of� the� part.� To� keep� within� the� bounds� of�
�the� part’s� maximum� rating,� a� calculation� of� the� RMS� and�
�peak� inductor� current� is� required.�
�2�
�(eq.� 7)�
�28%� 2�
�12�
�I� OUT� =� Output� current�
�I� RMS� =� Inductor� RMS� current�
�ra� =� Ripple� current� ratio�
�ra 28%�
�2� 2�
�(eq.� 8)�
�D� =� Duty� ratio�
�F� SW� =� Switching� frequency�
�Ipp� =� Peak� ?� to� ?� peak� current� of� the� inductor�
�L� OUT� =� Output� inductance�
�V� OUT� =� Output� voltage�
�From� Equation� 10� it� is� clear� that� the� ripple� current� increases�
�as� L� OUT� decreases,� emphasizing� the� trade� ?� off� between�
�dynamic� response� and� ripple� current.�
�The� power� dissipation� of� an� inductor� falls� into� two�
�categories:� copper� and� core� losses.� The� copper� losses� can� be�
�further� categorized� into� DC� losses� and� AC� losses.� A� good�
�first� order� approximation� of� the� inductor� losses� can� be� made�
�using� the� DC� resistance� as� shown� below:�
�http://onsemi.com�
�10�
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