参数资料
| 型号: | MIC2150YML TR |
| 厂商: | Micrel Inc |
| 文件页数: | 15/27页 |
| 文件大小: | 0K |
| 描述: | IC REG CTRLR BUCK PWM 24MLF |
| 标准包装: | 1 |
| PWM 型: | 电流/电压模式 |
| 输出数: | 2 |
| 频率 - 最大: | 550kHz |
| 占空比: | 80% |
| 电源电压: | 4.5 V ~ 14.5 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: | 24-VFQFN 裸露焊盘,24-MLF? |
| 包装: | 标准包装 |
| 其它名称: | 576-3746-6 |
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��
�
�Micrel,� Inc.�
�MIC2150�
�Application� Information�
�VOUT� PK� ?� PK� ≈� I� RIPPLE� ×� ESR� +�
�I� RIPPLE� � t� ON�
�2� � C� OUT�
�Passive� Component� Selection� Guide�
�Inductor� Selection�
�The� inductor� value� is� responsible� for� the� ripple� current�
�which� causes� some� proportion� of� the� resistive� losses� in�
�the� power� components.� These� losses� are� proportional� to�
�I� RIPPLE2� .� Minimizing� inductor� ripple� current� can� therefore�
�reduce� the� RMS� current� flowing� in� the� power�
�components� and� generally� improve� efficiency;� this� is�
�achieved� by� choosing� a� larger� value� inductor.� Having�
�said� this,� the� actual� value� of� inductance� is� realistically�
�defined� by� space� limitations,� RMS� rating� (I� RMS� )� and�
�saturation� current� (I� SAT� )� of� available� inductors.� If� one�
�looks� at� the� newer� flat� wire� inductors� for� example,� these�
�typically� have� higher� I� SAT� ratings� than� the� I� RMS� for� lower�
�values.� Also,� as� inductance� value� increases,� these�
�figures� tend� to� get� closer� in� value.� This� mirrors� what�
�happens� in� the� converter� with� I� SAT� analogous� to� the�
�maximum� peak� switch� current� and� I� RMS� analogous� to�
�output� current.� As� inductance� increases,� so� I� SWITCH(PK)�
�tends� towards� I� OUT� .� This� is� a� characteristic� that� makes�
�these� types� of� inductor� optimal� for� use� with� high� power�
�buck� converters� such� as� MIC2150.�
�To� determine� the� I� SAT� and� I� RMS� rating� of� the� inductor,� we�
�should� start� with� a� nominal� value� of� ripple� current.� This�
�should� typically� be� no� more� than� I� OUT(MAX)� /2� to� minimize�
�MOSFET� losses� due� to� ripple� current� mentioned� earlier.�
�Therefore:�
�If� therefore,� the� need� is� for� low� output� voltage� noise�
�(e.g.,� in� low� output� voltage� converters),� V� OUT� ripple� can�
�be� directly� reduced� by� increasing� inductor� value,� output�
�capacitor� value� or� reducing� ESR.�
�For� tantalum� capacitors,� ESR� is� typically� >40m� Ω� which�
�usually� makes� loop� stabilization� easier� by� utilizing� a�
�pole-zero� (type� II)� compensator.�
�Due� to� many� advantages� of� multi-layer� ceramic�
�capacitors,� among� them,� cost,� size,� ripple� rating� and�
�ESR,� it� can� be� useful� to� choose� these� in� many� cases.�
�However,� one� disadvantage� is� the� CV� product.� This� is�
�lower� than� tantalum.� A� mixture� of� one� tantalum� and� one�
�ceramic� can� be� a� good� compromise� which� can� still� utilize�
�the� simple� type� II� compensator.�
�With� ceramic� output� capacitors� only,� a� double-pole,�
�double-zero� (type� III)� compensator� is� required� to� ensure�
�system� stability.� Loop� compensation� is� described� in�
�more� detail� later� in� the� data� sheet.�
�Ensure� the� RMS� ripple� current� rating� of� the� capacitor� is�
�above� I� RIPPLE� ×0.6� to� improve� reliability.�
�Input� Capacitor� Selection�
�C� IN� ripple� rating� for� a� single� phase� converter� is� typically�
�I� OUT� /2� under� worst� case� duty� cycle� conditions� of� 50%.�
�This� increases� ~10%� for� a� ripple� current� of� I� OUT� /2.�
�When� both� cycles� are� switching� 180°� out� of� phase,� the�
�ripple� can� reduce� at� DC� <50%� to:�
�L� MIN� ~� 2� �
�V� OUT�
�I� OUT� � F� S�
�� (� 1� ?�
�V� OUT�
�V� IN� � Efficiency�
�)�
�I� RMSCIN� =� I� 1� 2� � D� 1� � (� 1� ?� D� 1� )� +� I� 2� 2� � D� 2� � (� 1� ?� D� 2� )� ?� 2� � I� 1� � I� 2� � D� 1� � D� 2�
�I� RIPPLE� ~�
�� OUT�
�I� LRMS� >� 1.04×I� OUT(MAX)�
�I� LSAT� >� 1.25×I� OUT(MAX)�
�Any� value� chosen� above� L� MIN� will� ensure� these� ratings�
�are� not� exceeded.�
�In� considering� the� actual� value� to� choose,� one� needs� to�
�look� at� the� effect� of� ripple� on� the� other� components� in�
�the� circuit.� The� chosen� inductor� value� will� have� a� ripple�
�current� of:�
�(1� ?� D )� V�
�F� S� L�
�This� value� should� ideally� be� kept� to� a� minimum,� within�
�the� cost� and� size� constraints� of� the� design,� to� reduce�
�unnecessary� heat� dissipation.�
�Output� Capacitor� Selection�
�The� output� capacitor� (C� OUT� )� will� have� the� full� inductor�
�ripple� current� I� RIPPLERMS� flowing� through� it.� This� creates�
�the� output� switching� noise� which� consists� of� two� main�
�components:�
�It� is� however,� also� advisable� to� closely� decouple� the�
�Power� MOSFETs� with� 2×10μF� ceramic� capacitors� to�
�reduce� ringing� and� prevent� noise� related� issues� from�
�causing� problems� in� the� layout� of� the� regulator.� The�
�ripple� rating� of� C� IN� may� therefore,� be� satisfied� by� these�
�decoupling� capacitors;� allowing� the� use� of� perhaps� one�
�more� ceramic� or� tantalum� input� capacitor� at� the� input�
�voltage� node� to� decouple� input� noise� and� localize� high�
�di/dt� signals� to� the� regulator� input.�
�Power� MOSFET� Selection�
�The� MIC2150� drives� N-Channel� MOSFETs� in� both� the�
�upper� and� lower� positions.� This� is� because� the� switching�
�speed� for� a� given� R� DSON� in� the� N-Channel� device� is�
�superior� to� the� P-Channel� device.�
�There� are� different� criteria� for� choosing� the� upper� and�
�lower� MOSFETs� and� these� criteria� are� more� marked� at�
�lower� duty� cycles� such� as� 12V� to� 1.8V� conversion.� In�
�such� an� application,� the� upper� MOSFET� is� required� to�
�switch� as� quickly� as� possible� to� minimize� transition�
�August� 2009�
�15�
�M9999-082809-A�
�(408)� 944-0800�
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相关代理商/技术参数 |
参数描述 |
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| MIC2151 | 制造商:MICREL 制造商全称:Micrel Semiconductor 功能描述:2-Phase Dual Output PWM Synchronous Buck Control IC |
| MIC2151YML | 制造商:Micrel 功能描述:Micrel MIC2151YML |
| MIC2155 | 制造商:MICREL 制造商全称:Micrel Semiconductor 功能描述:2-Phase, Single Output, PWM Synchronous Buck Control IC |
| MIC2155_0911 | 制造商:MICREL 制造商全称:Micrel Semiconductor 功能描述:Two-Phase, Single-Output, PWM Synchronous Buck Control IC |
| MIC2155YML | 制造商:Micrel 功能描述:The Micrel MIC2155YML is a 50A Synchronous Buck Regulator. |
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