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参数资料
| 型号: | NCV8842PWGEVB |
| 厂商: | ON Semiconductor |
| 文件页数: | 10/16页 |
| 文件大小: | 0K |
| 描述: | EVAL BOARD FOR NCV8842PWG |
| 设计资源: | NCV8842 EVB BOM NCV8842PWGEVB Gerber Files NCV8842 SOIC 16 EVB Schematic |
| 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: | 2.5V,3.3V,5V |
| 电流 - 输出: | 1.5A |
| 输入电压: | 7 ~ 16 V |
| 稳压器拓扑结构: | 降压 |
| 频率 - 开关: | 170kHz |
| 板类型: | 完全填充 |
| 已供物品: | 板 |
| 已用 IC / 零件: | NCV8842 |
| 其它名称: | NCV8842PWGEVBOS |
��
�
�NCV8842�
�(VIN� *� VO� )� O� )�
�VIN�
�WBASE� +� O�
�VO�
�VIN�
�V 2�
�WDRV� +� 12� mA�
�The� base� current� of� a� bipolar� transistor� is� equal� to� collector�
�current� divided� by� beta� of� the� device.� Beta� of� 60� is� used� here�
�to� estimate� the� base� current.� The� Boost� pin� provides� the� base�
�current� when� the� transistor� needs� to� be� on.� The� power�
�dissipated� by� the� IC� due� to� this� current� is�
�V 2 IS�
�VIN� 60�
�where:�
�I� S� =� DC� switching� current.�
�When� the� power� switch� turns� on,� the� saturation� voltage�
�and� conduction� current� contribute� to� the� power� loss� of� a�
�non� ?� ideal� switch.� The� power� loss� can� be� quantified� as�
�WSAT� +� IS� VSAT�
�where:�
�V� SAT� =� saturation� voltage� of� the� power� switch� which� is�
�shown� in� Figure� 7.�
�The� switching� loss� occurs� when� the� switch� experiences�
�both� high� current� and� voltage� during� each� switch� transition.�
�This� regulator� has� a� 30� ns� turn� ?� off� time� and� associated�
�power� loss� is� equal� to�
�COMPONENT� SELECTION�
�Input� Capacitor�
�In� a� buck� converter,� the� input� capacitor� supplies� pulsed�
�current� with� an� amplitude� equal� to� the� load� current.� This�
�pulsed� current� and� the� ESR� of� the� input� capacitors� determine�
�the� V� IN� ripple� voltage,� which� is� shown� in� Figure� 13.� For� V� IN�
�ripple,� low� ESR� is� a� critical� requirement� for� the� input�
�capacitor� selection.� The� pulsed� input� current� has� a�
�significant� AC� component,� which� is� absorbed� by� the� input�
�capacitors.� The� RMS� current� of� the� input� capacitor� can� be�
�calculated� using:�
�IRMS� +� IO� D(1� *� D)�
�where:�
�D� =� switching� duty� cycle� which� is� equal� to� V� O� /V� IN� .�
�I� O� =� load� current.�
�WS� +� S�
�I�
�2�
�VIN�
�30� ns�
�fS�
�The� turn� ?� on� time� is� much� shorter� and� thus� turn� ?� on� loss� is�
�not� considered� here.�
�The� total� power� dissipated� by� the� IC� is� sum� of� all� the� above�
�WIC� +� WQ� )� WDRV� )� WBASE� )� WSAT� )� WS�
�The� IC� junction� temperature� can� be� calculated� from� the�
�ambient� temperature,� IC� power� dissipation� and� thermal�
�resistance� of� the� package.� The� equation� is� shown� as� follows,�
�TJ� +� WIC� R� q� JA� )� TA�
�Minimum� Load� Requirement�
�As� pointed� out� in� the� previous� section,� a� minimum� load� is�
�required� for� this� regulator� due� to� the� pre� ?� driver� current�
�feeding� the� output.� Placing� a� resistor� equal� to� V� O� divided� by�
�12� mA� should� prevent� any� voltage� overshoot� at� light� load�
�conditions.� Alternatively,� the� feedback� resistors� can� be�
�valued� properly� to� consume� 12� mA� current.�
�Figure� 13.� Input� Voltage� Ripple� in� a� Buck� Converter�
�To� calculate� the� RMS� current,� multiply� the� load� current�
�with� the� constant� given� by� Figure� 14� at� each� duty� cycle.� It�
�is� a� common� practice� to� select� the� input� capacitor� with� an�
�RMS� current� rating� more� than� half� the� maximum� load�
�current.� If� multiple� capacitors� are� paralleled,� the� RMS�
�current� for� each� capacitor� should� be� the� total� current� divided�
�by� the� number� of� capacitors.�
�0.6�
�0.5�
�0.4�
�0.3�
�0.2�
�0.1�
�0�
�0�
�0.2�
�0.4�
�0.6�
�0.8�
�1.0�
�DUTY� CYCLE�
�Figure� 14.� Input� Capacitor� RMS� Current� can� be�
�Calculated� by� Multiplying� Y� Value� with� Maximum� Load�
�Current� at� any� Duty� Cycle�
�http://onsemi.com�
�10�
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