参数资料
| 型号: | NCP5331FTR2G |
| 厂商: | ON Semiconductor |
| 文件页数: | 24/36页 |
| 文件大小: | 0K |
| 描述: | IC CTLR PWM 2PH W/DRVRS 32-LQFP |
| 产品变化通告: | Product Obsolescence 05/Oct/2010 |
| 标准包装: | 1 |
| 应用: | 控制器,AMD Athlon? |
| 输入电压: | 9 V ~ 14 V |
| 输出数: | 2 |
| 输出电压: | 5V |
| 工作温度: | 0°C ~ 70°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 32-LQFP |
| 供应商设备封装: | 32-LQFP(7x7) |
| 包装: | 剪切带 (CT) |
| 其它名称: | NCP5331FTR2GOSCT |
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�NCP5331�
�(VIN� *� VCORE)� @� VCORE�
�(� a� @� IO,MAX� @� VIN� @� fSW)�
�D� IO,MAX�
�D� VO,MAX�
�14.� The� CS� REF� sense� point� should� be� equidistant�
�between� the� output� inductors� to� equalize� the� PCB�
�resistance� added� to� the� current� sense� paths.� This�
�will� insure� acceptable� current� sharing.� Also,� route�
�the� CS� REF� connection� away� from� noisy� traces� such�
�as� the� SWNODEs� and� GATE� traces.� If� noise� from�
�the� SWNODEs� or� GATE� signals� capacitively�
�couples� to� the� CSREF� trace� the� external� ramps�
�will� be� very� noisy� and� voltage� jitter� will� result.�
�15.� Ideally,� the� SWNODEs� are� exactly� the� same� shape�
�and� the� current� sense� points� (connections� to� R� S1�
�and� R� S2� )� are� made� at� identical� locations� to� equalize�
�the� PCB� resistance� added� to� the� current� sense� paths.�
�This� will� help� to� insure� acceptable� current� sharing.�
�16.� Place� the� 1� m� F� ceramic� capacitors,� C� P1� and� C� P2� ,�
�close� to� the� drains� of� the� MOSFETs� Q1� and� Q2,�
�respectively.�
�17.� If� snubbers� are� used,� they� must� be� placed� very�
�close� to� their� associated� MOSFETs� and�
�SWNODE.� The� connections� to� the� snubber�
�components� should� be� as� short� as� possible.�
�Design� Procedure�
�1.� Output� Capacitor� Selection�
�The� output� capacitors� filter� the� current� from� the� output�
�inductor� and� provide� a� low� impedance� for� transient� load�
�current� changes.� Typically,� microprocessor� applications�
�will� require� both� bulk� (electrolytic,� tantalum)� and� low�
�impedance,� high� frequency� (ceramic)� types� of� capacitors.�
�The� bulk� capacitors� provide� “hold� up”� during� transient�
�loading.� The� low� impedance� capacitors� reduce� steady?state�
�ripple� and� bypass� the� bulk� capacitance� when� the� output�
�current� changes� very� quickly.� The� microprocessor�
�manufacturers� usually� specify� a� minimum� number� of�
�ceramic� capacitors.� The� designer� must� determine� the�
�number� of� bulk� capacitors.�
�Choose� the� number� of� bulk� output� capacitors� to� meet� the�
�peak� transient� requirements.� The� following� formula� can� be�
�used� to� provide� a� starting� point� for� the� minimum� number� of�
�bulk� capacitors� (N� OUT,MIN� ).�
�(1)�
�NOUT,MIN� +� ESR� per� capacitor� @�
�In� reality,� both� the� ESR� and� ESL� of� the� bulk� capacitors�
�determine� the� voltage� change� during� a� load� transient�
�according� to�
�D� VO,MAX� +� (� D� IO,MAX� D� t)� @� ESL� )� D� IO,MAX� @� ESR� (2)�
�Unfortunately,� capacitor� manufacturers� do� not� specify� the�
�ESL� of� their� components� and� the� inductance� added� by� the�
�PCB� traces� is� highly� dependent� on� the� layout� and� routing.�
�Therefore,� it� is� necessary� to� start� a� design� with� slightly� more�
�2.� Output� Inductor� Selection�
�The� output� inductor� may� be� the� most� critical� component�
�in� the� converter� because� it� will� directly� effect� the� choice� of�
�other� components� and� dictate� both� the� steady?state� and�
�transient� performance� of� the� converter.� When� selecting� an�
�inductor� the� designer� must� consider� factors� such� as� dc�
�current,� peak� current,� output� voltage� ripple,� core� material,�
�magnetic� saturation,� temperature,� physical� size,� and� cost�
�(usually� the� primary� concern).�
�In� general,� the� output� inductance� value� should� be� as� low�
�and� physically� small� as� possible� to� provide� the� best� transient�
�response� and� minimum� cost.� If� a� large� inductance� value� is�
�used,� the� converter� will� not� respond� quickly� to� rapid� changes�
�in� the� load� current.� On� the� other� hand,� too� low� an� inductance�
�value� will� result� in� very� large� ripple� currents� in� the� power�
�components� (MOSFETs,� capacitors,� etc)� resulting� in�
�increased� dissipation� and� lower� converter� efficiency.� Also,�
�increased� ripple� currents� will� force� the� designer� to� use�
�higher� rated� MOSFETs,� oversize� the� thermal� solution,� and�
�use� more,� higher� rated� input� and� output� capacitors� ?� the�
�converter� cost� will� be� adversely� effected.�
�One� method� of� calculating� an� output� inductor� value� is� to�
�size� the� inductor� to� produce� a� specified� maximum� ripple�
�current� in� the� inductor.� Lower� ripple� currents� will� result� in�
�less� core� and� MOSFET� losses� and� higher� converter�
�efficiency.� Equation� 3� may� be� used� to� calculate� the�
�minimum� inductor� value� to� produce� a� given� maximum�
�ripple� current� (� α� )� per� phase.� The� inductor� value� calculated�
�by� this� equation� is� a� minimum� because� values� less� than� this�
�will� produce� more� ripple� current� than� desired.� Conversely,�
�higher� inductor� values� will� result� in� less� than� the� maximum�
�ripple� current.�
�(3)�
�LoMIN� +�
�α� is� the� ripple� current� as� a� percentage� of� the� maximum�
�output� current� per� phase� (� α� =� 0.15� for� ±� 15%,� α� =� 0.25� for�
�±� 25%,� etc).� If� the� minimum� inductor� value� is� used,� the�
�inductor� current� will� swing� ±� α� %� about� its� value� at� the� center�
�(half� the� dc� output� current� for� a� two?phase� converter).�
�Therefore,� for� a� two?phase� converter,� the� inductor� must� be�
�designed� or� selected� such� that� it� will� not� saturate� with� a� peak�
�current� of� (1� +� α� )� ?� I� O,MAX� /2.�
�The� maximum� inductor� value� is� limited� by� the� transient�
�response� of� the� converter.� If� the� converter� is� to� have� a� fast�
�transient� response� then� the� inductor� should� be� made� as� small�
�as� possible.� If� the� inductor� is� too� large� its� current� will� change�
�too� slowly,� the� output� voltage� will� droop� excessively,� more�
�bulk� capacitors� will� be� required,� and� the� converter� cost� will�
�be� increased.� For� a� given� inductor� value,� its� interesting� to�
�determine� the� time� required� to� increase� or� decrease� the�
�current.�
�than� the� minimum� number� of� bulk� capacitors� and� perform�
�transient� testing� or� careful� modeling/simulation� to�
�determine� the� final� number� of� bulk� capacitors.�
�http://onsemi.com�
�24�
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