参数资料
| 型号: | NCP3020BDR2G |
| 厂商: | ON Semiconductor |
| 文件页数: | 17/23页 |
| 文件大小: | 0K |
| 描述: | IC REG CTRLR BUCK PWM VM 8-SOIC |
| 标准包装: | 1 |
| PWM 型: | 电压模式 |
| 输出数: | 1 |
| 频率 - 最大: | 670kHz |
| 占空比: | 80% |
| 电源电压: | 4.7 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: | 8-SOIC(0.154",3.90mm 宽) |
| 包装: | 标准包装 |
| 其它名称: | NCP3020BDR2GOSDKR |
��
�
�NCP3020A,� NCP3020B,� NCV3020A,� NCV3020B�
�16� V� out� =� 3.3� V�
�15�
�12� V�
�9V�
�I� PP� +�
�LP� CU� +� I� RMS� 2� @� DCR�
�1� )� ra� 3� 10.02� A�
�I� RMS� +� I� OUT� @�
�12�
�+� 10� A� @�
�1� )�
�18�
�17�
�18� V�
�14�
�13� 15� V�
�12�
�11�
�10�
�9�
�8�
�7�
�6�
�5�
�4�
�3�
�2�
�1�
�0�
�10%� 15%� 20%� 25%� 30%� 35%� 40%�
�V� IN� ,� (V)�
�Figure� 32.� Ripple� Current� Ratio� vs.� Inductance�
�To� keep� within� the� bounds� of� the� parts� maximum� rating,�
�calculate� the� RMS� current� and� peak� current.�
�2�
�(eq.� 8)�
�(0.24)� 2�
�12�
�V� OUT� (1� *� D)�
�(eq.� 11)�
�L� OUT� @� F� SW�
�Ipp� is� the� peak� to� peak� current� of� the� inductor.� From� this�
�equation� 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� consists� of� both�
�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� they� usually� contribute� to� 90%� of� the� losses�
�of� the� inductor� shown� below:�
�(eq.� 12)�
�The� core� losses� and� ac� copper� losses� will� depend� on� the�
�geometry� of� the� selected� core,� core� material,� and� wire� used.�
�Most� vendors� will� provide� the� appropriate� information� to�
�make� accurate� calculations� of� the� power� dissipation� then� the�
�total� inductor� losses� can� be� capture� buy� the� equation� below:�
�LP� tot� +� LP� CU_DC� )� LP� CU_AC� )� LP� Core� (eq.� 13)�
�Input� Capacitor� Selection�
�The� input� capacitor� has� to� sustain� the� ripple� current�
�I� PK� +� I� OUT� @� 1� )�
�ra�
�2�
�3� 11.2� A� +� 10� A� @� 1� )�
�(0.24)�
�2�
�(eq.� 9)�
�produced� during� the� on� time� of� the� upper� MOSFET,� so� it�
�must� have� a� low� ESR� to� minimize� the� losses.� The� RMS� value�
�of� this� ripple� is:�
�SlewRate� LOUT� +� 3� 2.6� +�
�L� OUT�
�(eq.� 15)�
�I� INRUSH� +�
�An� inductor� for� this� example� would� be� around� 3.3� m� H� and�
�should� support� an� rms� current� of� 10.02� A� and� a� peak� current�
�of� 11.2� A.�
�The� final� selection� of� an� output� inductor� has� both�
�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� 10.�
�V� IN� *� V� OUT� A 12 V� *� 3.3 V�
�m� s� 3.3� m� H�
�(eq.� 10)�
�This� equation� implies� that� larger� inductor� values� limit� the�
�regulator� ’s� ability� to� slew� current� through� the� output�
�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.� This�
�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� the� necessary� capacitance,� at� the�
�expense� of� higher� ripple� current.� The� peak� ?� to� ?� peak� ripple�
�current� for� the� NCP3020A� is� given� by� the� following�
�Iin� RMS� +� I� OUT� @� D� @� (1� *� D)� (eq.� 14)�
�D� is� the� duty� cycle,� Iin� RMS� is� the� input� RMS� current,� and�
�I� OUT� is� the� load� current.�
�The� equation� reaches� its� maximum� value� with� D� =� 0.5.�
�Loss� in� the� input� capacitors� can� be� calculated� with� the�
�following� equation:�
�2�
�P� CIN� +� ESR� CIN� @� I� IN� *� RMS�
�P� CIN� is� the� power� loss� in� the� input� capacitors� and� ESR� CIN�
�is� the� effective� series� resistance� of� the� input� capacitance.�
�Due� to� large� dI/dt� through� the� input� capacitors,� electrolytic�
�or� ceramics� should� be� used.� If� a� tantalum� must� be� used,� it�
�must� by� surge� protected.� Otherwise,� capacitor� failure� could�
�occur.�
�Input� Start� ?� up� Current�
�To� calculate� the� input� startup� current,� the� following�
�equation� can� be� used.�
�C� OUT� @� V� OUT�
�(eq.� 16)�
�t� SS�
�I� inrush� is� the� input� current� during� startup,� C� OUT� is� the� total�
�output� capacitance,� V� OUT� is� the� desired� output� voltage,� and�
�t� SS� is� the� soft� start� interval.� If� the� inrush� current� is� higher� than�
�the� steady� state� input� current� during� max� load,� then� the� input�
�fuse� should� be� rated� accordingly,� if� one� is� used.�
�equation:�
�http://onsemi.com�
�17�
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