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| 型号: | ADP3050-EVAL |
| 厂商: | Analog Devices Inc |
| 文件页数: | 12/20页 |
| 文件大小: | 0K |
| 描述: | BOARD EVAL FOR ADP3050 |
| 标准包装: | 1 |
| 主要目的: | DC/DC,步降 |
| 输入电压: | 3.6 ~ 30 V |
| 稳压器拓扑结构: | 降压 |
| 板类型: | 完全填充 |
| 已供物品: | 板 |
| 已用 IC / 零件: | ADP3050 |
| 相关产品: | ADP3050ARZ-3.3-RL7TR-ND - IC REG BUCK 3.3V 1A 8SOIC ADP3050ARZ-3.3-RLTR-ND - IC REG BUCK 3.3V 1A 8SOIC ADP3050ARZ-3.3-ND - IC REG BUCK 3.3V 1A 8SOIC ADP3050ARZ-R7DKR-ND - IC REG BUCK ADJ 1A 8SOIC ADP3050ARZ-R7CT-ND - IC REG BUCK ADJ 1A 8SOIC ADP3050ARZ-R7TR-ND - IC REG BUCK ADJ 1A 8SOIC ADP3050ARZ-5-ND - IC REG BUCK 5V 1A 8SOIC ADP3050ARZ-RLTR-ND - IC REG BUCK ADJ 1A 8SOIC ADP3050ARZ-5-REEL7TR-ND - IC REG BUCK 5V 1A 8SOIC ADP3050ARZ-5-REELTR-ND - IC REG BUCK 5V 1A 8SOIC 更多... |
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�ADP3050�
�For� a� 400� mA,� 24� V� to� 5� V� system�
�Data� Sheet�
�in� the� Inductor� Selection� section).� Contact� the� manufacturers�
�L� DIS� ≤�
�24� ?� 5�
�2� � 0� .� 4�
��
�1�
�200� � 10� 3�
��
�5�
�24�
�≤� 24� .� 7� μH�
�for� their� full� product� offering,� availability,� and� pricing.� The�
�manufacturers� offer� many� more� values� and� package� sizes� to� suit�
�numerous� applications.�
�If� the� chosen� inductor� value� is� too� small,� the� internal� current�
�limit� trips� each� cycle� and� the� regulator� has� trouble� providing� the�
�necessary� load� current.�
�1.�
�Choose� a� mode� of� operation,� then� calculate� the� inductor�
�value� using� the� appropriate� equation.� For� continuous� mode�
�systems,� a� ripple� current� of� 40%� of� the� maximum� load� current�
�Inductor� Core� Types� and� Materials�
�Many� types� of� inductors� are� currently� available.� Numerous� core�
�styles� along� with� numerous� core� materials� often� make� the� selection�
�process� seem� even� more� confusing.� A� quick� overview� of� the�
�types� of� inductors� available� makes� the� selection� process� a� little�
�easier� to� understand.�
�Open� core� geometries� (bobbin� core)� are� usually� less� expensive�
�than� closed� core� geometries� (toroidal� core)� and� are� a� good� choice�
�for� some� applications,� but� care� must� be� taken� when� they� are�
�used.� In� open� core� inductors,� the� magnetic� flux� is� not� completely�
�contained� inside� the� core.� The� radiating� magnetic� field� generates�
�electromagnetic� interference� (EMI),� often� inducing� voltages�
�onto� nearby� circuit� board� traces.� These� inductors� may� not� be�
�suitable� for� systems� that� contain� very� high� accuracy� circuits� or�
�sensitive� magnetics.� A� few� manufacturers� have� semiclosed� and�
�shielded� cores,� where� an� outer� magnetic� shield� surrounds� a�
�bobbin� core.� These� devices� have� less� EMI� than� the� standard�
�open� core� and� are� usually� smaller� than� a� closed� core.�
�Most� core� materials� used� in� surface-mount� inductors� are� either�
�powdered� iron� or� ferrite.� For� many� designs,� material� choice� is�
�arbitrary,� but� the� properties� of� each� material� should� be� recognized.�
�Ferrites� have� lower� core� losses� than� powdered� iron,� but� the�
�lower� loss� means� a� higher� price.� Powdered� iron� cores� saturate�
�softly� (the� inductance� gradually� reduces� as� current� rating� is�
�exceeded),� whereas� ferrite� cores� saturate� much� more� abruptly�
�(the� inductance� rapidly� reduces).� Kool� Mμ?� is� one� type� of� ferrite�
�that� is� specially� designed� to� minimize� core� losses� and� heat�
�generation� (especially� at� switching� frequencies� above� 100� kHz),�
�but� again,� these� devices� are� more� expensive.�
�The� winding� dc� resistance� (DCR)� of� the� inductor� must� not� be�
�overlooked.� A� high� DCR� can� decrease� system� efficiency� by� 2%�
�to� 5%� for� lower� output� voltages� at� heavy� loads.� To� obtain� a�
�lower� DCR� means� using� a� physically� larger� inductor,� so� a� trade-�
�off� in� size� and� efficiency� must� be� made.� The� power� loss� due� to� this�
�resistance� is� I� OUT2� � DCR.� For� an� 800� mA,� 5� V� to� 3.3� V� system�
�with� an� inductor� DCR� of� 100� mΩ,� the� winding� resistance�
�dissipates�
�(0.82� A)� 2� ×� 0.1� Ω� =� 64� mW.� This� represents� a� power� loss� to� the�
�system� of� 64� mW/(3.3� V� � 800� mA)� =� 2.4%.� Typical� DCR�
�values� are� between� 10� mΩ� and� 200� mΩ.�
�Choosing� an� Inductor�
�Several� considerations� must� be� made� when� choosing� an� inductor:�
�cost,� size,� EMI,� core� and� copper� losses,� and� maximum� current�
�rating.� Use� the� following� steps� to� choose� an� inductor� that� is�
�right� for� the� system� (refer� to� the� calculations� and� descriptions�
�is� a� good� starting� point.� The� inductor� value� can� then� be�
�increased� or� decreased,� if� desired.�
�2.� Calculate� the� peak� switch� current� (this� is� the� maximum�
�current� seen� by� the� inductor).� Make� sure� that� the� dc� (or�
�saturation)� current� rating� of� the� inductor� is� high� enough�
�(around� 1.2� the� peak� switch� current).� Inductors� with� dc�
�current� ratings� of� at� least� 1� A� should� be� used� for� all�
�designs.� This� provides� a� safety� margin� for� start-up� and�
�fault� conditions� where� the� inductor� current� is� higher� than�
�normal.� If� the� current� rating� of� an� inductor� is� exceeded,� the�
�core� saturates,� causing� the� inductance� value� to� decrease�
�and� the� temperature� of� the� inductor� to� increase.�
�3.� Estimate� the� dc� winding� resistance� based� on� the� inductance�
�value.� A� general� rule� is� to� allow� approximately� 5� m� of�
�resistance� per� μH� of� inductance.�
�4.� Pick� the� core� material� and� type.� First,� decide� if� an� open-�
�core� inductor� can� be� used� with� the� design.� If� this� cannot� be�
�determined,� try� a� few� samples� of� each� type� (open� core,�
�semi� closed� core,� shielded� core,� and� closed� core).� Do� not� be�
�discouraged� from� using� open� core� inductors� because� they�
�require� extra� care;� just� be� aware� of� what� to� look� for� if� used.�
�They� are� quite� small� and� inexpensive,� and� are� used�
�successfully� in� many� different� applications.�
�OUTPUT� CAPACITOR� SELECTION�
�The� ADP3050� can� be� used� with� any� type� of� output� capacitor.�
�The� trade-offs� between� price,� component� size,� and� regulator�
�performance� can� be� evaluated� to� determine� the� best� choice� for�
�each� application.� The� effective� series� resistance� (ESR)� of� the�
�capacitor� plays� an� important� role� in� both� the� loop� compensation�
�and� the� system� performance.� The� ESR� provides� a� 0� in� the�
�feedback� loop;� therefore,� the� ESR� value� must� be� known� so� the�
�loop� can� be� compensated� correctly� (most� manufacturers� specify�
�maximum� ESR� in� their� data� sheets).� The� capacitor� ESR� also�
�contributes� to� the� output� ripple� voltage� (V� RIPPLE� =� ESR� � I� RIPPLE� ).�
�Solid� tantalum� or� multilayer� ceramic� capacitors� are� recommended,�
�providing� good� performance� with� a� small� size� and� reasonable� cost.�
�Solid� tantalum� capacitors� have� a� good� combination� of� low� ESR�
�and� high� capacitance,� and� are� available� from� several� different�
�manufacturers.� Capacitance� values� from� 22� μF� to� more� than� 500� μF�
�can� be� used,� but� values� of� 47� μF� to� 220� μF� are� sufficient� for� most�
�designs.� A� smaller� value� can� be� used,� but� ESR� is� size-dependent,�
�so� a� smaller� device� has� a� higher� ESR.� Ensure� that� the� ripple�
�current� of� the� capacitor� rating� is� larger� than� the� inductor� ripple�
�current� (the� ripple� current� flows� into� the� output� capacitor).�
�Multilayer� ceramic� capacitors� can� be� used� in� applications� where�
�minimum� output� voltage� ripple� is� a� priority.� They� have� a� very�
�Rev.� C� |� Page� 12� of� 20�
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相关代理商/技术参数 |
参数描述 |
|---|---|
| ADP3050-EVALZ | 制造商:AD 制造商全称:Analog Devices 功能描述:200 kHz, 1 A High Voltage Step-Down Switching Regulator |
| ADP3051 | 制造商:AD 制造商全称:Analog Devices 功能描述:500 mA PWM Step-Down DC-DC with Synchronous Rectifier |
| ADP3051ARMZ-REEL | 制造商:Analog Devices 功能描述:CONV DC-DC SGL-OUT STEP DOWN 8MSOP - Tape and Reel |
| ADP3051ARMZ-REEL7 | 制造商:Analog Devices 功能描述:Conv DC-DC Single Step Down 2.7V to 5.5V 8-Pin MSOP T/R 制造商:Analog Devices 功能描述:SWITCH REG SYNC BUCK 500MA 8MSOP |
| ADP3088 | 制造商:AD 制造商全称:Analog Devices 功能描述:1 MHz, 750 mA Buck Regulator |
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