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参数资料
| 型号: | ADP3050-BL1-EVZ |
| 厂商: | Analog Devices Inc |
| 文件页数: | 11/20页 |
| 文件大小: | 0K |
| 描述: | BOARD EVALUATION FOR ADP3050 |
| 标准包装: | 1 |
| 系列: | * |
��
��
��V� IN� (� MAX� )� ?� V� OUT� 1� V� OUT�
�12� ?� 5� 1� 5�
�200� � 10� 3�
�I� SW� (� PK� )� =� I� OUT� (� MAX� )� +� I� RIPPLE� =� 0� .� 8� +� 0� .� 155� =� 0� .� 95� A�
�1�
�V� IN� (� MAX� )� ?� V� OUT� 1� V� OUT�
�2� � I� OUT�
�L� DIS� =� � � (4)�
�DataSheet�
�APPLICATIONS� INFORMATION�
�ADIsimPower� DESIGN� TOOL�
�The� ADP3050� is� supported� by� the� ADIsimPower� design� tool� set.�
�ADIsimPower� is� a� collection� of� tools� that� produce� complete� power�
�designs� optimized� for� a� specific� design� goal.� The� tools� enable�
�the� user� to� generate� a� full� schematic,� bill� of� materials,� and� calculate�
�performance� in� minutes.� ADIsimPower� can� optimize� designs� for�
�cost,� area,� efficiency,� and� parts� count� while� taking� into� considera-�
�tion� the� operating� conditions� and� limitations� of� the� IC� and� all� real�
�external� components.� For� more� information� about� ADIsimPower�
�design� tools,� refer� to� www.analog.com/ADIsimPower� .� The� tool�
�set� is� available� from� this� website,� and� users� can� request� an�
�unpopulated� board� through� the� tool.�
�The� complete� process� for� designing� a� step-down� switching�
�regulator� using� the� ADP3050� is� provided� in� the� following�
�sections.� Each� section� includes� a� list� of� recommended� devices.�
�These� lists� do� not� include� every� available� device� or� manufacturer.�
�They� contain� only� surface-mount� devices.� Equivalent� through-�
�hole� devices� can� be� substituted� if� needed.� In� choosing� components,�
�keep� in� mind� what� is� most� important� to� the� design,� for� example,�
�efficiency,� cost,� and� size.� These� ultimately� determine� which� compo-�
�nents� are� used.� It� is� also� important� to� ensure� that� the� design�
�specifications� are� clearly� defined� and� reflect� the� worst-case�
�conditions.� Key� specifications� include� the� minimum� and�
�maximum� input� voltage,� the� output� voltage� and� ripple,� and� the�
�minimum� and� maximum� load� current.�
�INDUCTOR� SELECTION�
�The� inductor� value� determines� the� mode� of� operation� for� the�
�regulator:� continuous� mode,� where� the� inductor� current� flows�
�continuously;� or� discontinuous� mode,� where� the� inductor� current�
�reduces� to� zero� during� every� switch� cycle.� Continuous� mode� is�
�the� best� choice� for� many� applications.� It� provides� higher� output�
�power,� lower� peak� currents� in� the� switch,� inductor,� and� diode,�
�and� a� lower� inductor� ripple� current,� which� means� lower� output�
�ripple� voltage.� Discontinuous� mode� allows� the� use� of� smaller�
�magnetics,� but� at� a� price:� lower� available� load� current� and�
�higher� peak� and� ripple� currents.� Designs� with� a� high� input�
�voltage� or� a� low� load� current� often� operate� in� discontinuous�
�mode� to� minimize� inductor� value� and� size.� The� ADP3050� is�
�designed� to� work� well� in� both� modes� of� operation.�
�Continuous� Mode�
�The� inductor� current� in� a� continuous� mode� system� is� a� triangular�
�waveform� (equal� to� the� ripple� current)� centered� around� a� dc�
�value� (equal� to� the� load� current).� The� amount� of� ripple� current�
�is� determined� by� the� inductor� value,� and� is� usually� between� 20%�
�and� 40%� of� the� maximum� load� current.� To� reduce� the� inductor�
�size,� ripple� currents� between� 40%� and� 80%� are� often� used� in�
�continuous� mode� designs� with� a� high� input� voltage� or� a� low�
�output� current.�
�ADP3050�
�The� inductor� value� is� calculated� using� the� following� equation:�
�L� =� � � (2)�
�I� RIPPLE� f� SW� V� IN� (� MAX� )�
�Where� V� IN(MAX)� is� the� maximum� input� voltage,� V� OUT� is� the�
�regulated� output� voltage,� and� f� SW� is� the� switching� frequency�
�(200� kHz).� The� initial� choice� for� the� amount� of� ripple� current�
�may� seem� arbitrary,� but� it� serves� as� a� good� starting� point� for�
�finding� a� standard� off-the-shelf� inductor� value,� such� as�
�10� μH,� 15� μH,� 22� μH,� 33� μH,� and� 47� μH.� If� a� specific� inductance�
�value� is� to� be� used,� simply� rearrange� Equation� 2� to� find� the�
�ripple� current.� For� an� 800� mA,� 12� V� to� 5� V� system,� and� a� ripple�
�current� of� 320� mA� (40%� of� 800� mA)� is� chosen,� the� inductance� is�
�L� =� ×� ×� =� 45.5� μH�
�0.32� 12�
�A� 47� μH� inductor� is� the� closest� standard� value� that� gives� a� ripple�
�current� of� about� 310� mA.� The� peak� switch� current� is� equal� to�
�the� load� current� plus� one-half� the� ripple� current� (this� is� also� the�
�peak� current� for� the� inductor� and� the� catch� diode).�
�(3)�
�2�
�Pick� an� inductor� with� a� dc� (or� saturation)� current� rating� about� 20%�
�larger� than� I� SW(PK)� to� ensure� that� the� inductor� is� not� running� near�
�the� edge� of� saturation.� For� this� example,� 1.20� � 0.95� A� =� 1.14� A,� use�
�an� inductor� with� a� dc� current� rating� of� at� least� 1.2� A.� The� maxi-�
�mum� switch� current� is� internally� limited� to� 1.5� A,� and� this� limit,�
�along� with� the� ripple� current,� determines� the� maximum� load�
�current� the� system� can� provide.�
�If� the� load� current� decreases� to� below� one-half� the� ripple�
�current,� the� regulator� operates� in� discontinuous� mode.�
�Discontinuous� Mode�
�For� load� currents� less� than� approximately� 0.5� A,� discontinuous�
�mode� operation� can� be� used.� This� allows� the� use� of� a� smaller�
�inductor,� but� the� ripple� current� is� much� higher� (which� means� a�
�higher� output� ripple� voltage).� If� a� larger� output� capacitor� must�
�be� used� to� reduce� the� output� ripple� voltage,� the� overall� system�
�may� take� up� more� board� area� than� if� a� larger� inductor� is� used.�
�The� operation� and� equations� for� the� two� modes� are� quite� different,�
�but� the� boundary� between� these� two� modes� occurs� when� the� ripple�
�current� is� equal� to� twice� the� load� current� (when� I� RIPPLE� =� 2� � I� OUT� ).�
�From� this,� Equation� 2� is� used� to� find� the� minimum� inductor�
�value� needed� to� keep� the� system� in� continuous� mode� operation�
�(solve� for� the� inductor� value� with� I� RIPPLE� =� 2� � I� OUT� ).�
�f� SW� V� IN� (� MAX� )�
�Using� an� inductor� below� this� value� causes� the� system� to� operate�
�in� discontinuous� mode.�
�Rev.� C� |� Page� 11� of� 20�
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相关代理商/技术参数 |
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| ADP3050-EVAL | 功能描述:BOARD EVAL FOR ADP3050 RoHS:否 类别:编程器,开发系统 >> 评估板 - DC/DC 与 AC/DC(离线)SMPS 系列:- 标准包装:1 系列:- 主要目的:DC/DC,步降 输出及类型:1,非隔离 功率 - 输出:- 输出电压:3.3V 电流 - 输出:3A 输入电压:4.5 V ~ 28 V 稳压器拓扑结构:降压 频率 - 开关:250kHz 板类型:完全填充 已供物品:板 已用 IC / 零件:L7981 其它名称:497-12113STEVAL-ISA094V1-ND |
| 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 |
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