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| 型号: | LTC3734EUH#TR |
| 厂商: | Linear Technology |
| 文件页数: | 21/28页 |
| 文件大小: | 0K |
| 描述: | IC CTRLR DC/DC 1PH HI EFF 32QFN |
| 标准包装: | 2,500 |
| 应用: | 控制器,Intel 移动式 CPU |
| 输入电压: | 4 V ~ 30 V |
| 输出数: | 1 |
| 输出电压: | 0.7 V ~ 1.71 V |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 32-WFQFN 裸露焊盘 |
| 供应商设备封装: | 32-QFN 裸露焊盘(5x5) |
| 包装: | 带卷 (TR) |
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�
�LTC3734�
�APPLICATIONS� INFORMATION�
�Transition� Loss� =� V� IN2� ?�
�I� OUT�
�?� f� ?� C� RSS� ?� R� DR� ?�
�?� V� DR� –� V� TH(MIN)�
�V� TH(MIN)� ?�
�output.EfficiencyvariesastheinversesquareofV� OUT� for�
�the� same� external� components� and� output� power� level.�
�The� combined� effects� of� increasingly� lower� output� voltages�
�and� higher� currents� required� by� high� performance� digital�
�systems� is� not� doubling� but� quadrupling� the� importance�
�of� loss� terms� in� the� switching� regulator� system!�
�2)� Transition� losses� apply� only� to� the� topside� MOSFET(s),�
�and� are� significant� only� when� operating� at� high� input� volt-�
�ages� (typically� 12V� or� greater).� Transition� losses� can� be�
�estimated� from:�
�2�
�?� 1� 1� ?�
�?� +� ?�
�3)� PV� CC� drives� both� top� and� bottom� MOSFETs.� The� MOSFET�
�driver� current� results� from� switching� the� gate� capacitance�
�of� the� power� MOSFETs.� Each� time� a� MOSFET� gate� is�
�switched� from� low� to� high� to� low� again,� a� packet� of� charge�
�dQ� moves� from� PV� CC� to� ground.� The� resulting� dQ/dt� is� a�
�current� out� of� PV� CC� that� is� typically� much� larger� than� the�
�control� circuit� current.� In� continuous� mode,� I� GATECHG� =�
�(Q� T� +� Q� B� )f,� where� Q� T� and� Q� B� are� the� gate� charges� of� the�
�topside� and� bottom� side� MOSFETs� and� f� is� the� switching�
�frequency.�
�4)� The� input� capacitor� has� the� difficult� job� of� filtering� the�
�large� RMS� input� current� to� the� regulator.� It� must� have� a�
�very� low� ESR� to� minimize� the� AC� I� 2� R� loss� and� sufficient�
�capacitance� to� prevent� the� RMS� current� from� causing�
�additional� upstream� losses� in� fuses� or� batteries.�
�Other� losses,� including� C� OUT� ESR� loss,� Schottky� diode�
�conduction� loss� during� dead� time,� inductor� core� loss� and�
�internal� control� circuitry� supply� current� generally� account�
�for� less� than� 2%� additional� loss.�
�Checking� Transient� Response�
�The� regulator� loop� response� can� be� checked� by� look-�
�ing� at� the� load� transient� response.� Switching� regulators�
�take� several� cycles� to� respond� to� a� step� in� DC� (resistive)�
�load� current.� When� a� load� step� occurs,� V� OUT� shifts� by� an�
�amount� equal� to� ?I� LOAD� (ESR),� where� ESR� is� the� effective�
�series� resistance� of� C� OUT� .� ?I� LOAD� also� begins� to� charge� or�
�discharge� C� OUT� generating� the� feedback� error� signal� that�
�forces� the� regulator� to� adapt� to� the� current� change� and�
�return� V� OUT� to� its� steady-state� value.� During� this� recovery�
�time� V� OUT� can� be� monitored� for� excessive� overshoot� or�
�ringing,� which� would� indicate� a� stability� problem.� The�
�availability� of� the� I� TH� pin� not� only� allows� optimization� of�
�control� loop� behavior� but� also� provides� a� DC� coupled� and�
�AC� filtered� closed� loop� response� test� point.� The� DC� step,�
�rise� time,� and� settling� at� this� test� point� truly� reflects� the�
�closed� loop� response.� Assuming� a� predominantly� second�
�order� system,� phase� margin� and/or� damping� factor� can� be�
�estimated� using� the� percentage� of� overshoot� seen� at� this�
�pin.� The� bandwidth� can� also� be� estimated� by� examining� the�
�rise� time� at� the� pin.� The� I� TH� external� components� shown�
�in� the� Figure� 1� circuit� will� provide� an� adequate� starting�
�point� for� most� applications.�
�The� I� TH� series� R� C� -C� C� filter� sets� the� dominant� pole-zero�
�loop� compensation.� The� values� can� be� modified� slightly�
�(from� 0.2� to� 5� times� their� suggested� values)� to� optimize�
�transient� response� once� the� final� PC� layout� is� done� and�
�the� particular� output� capacitor� type� and� value� have� been�
�determined.� The� output� capacitors� need� to� be� decided�
�upon� first� because� the� various� types� and� values� determine�
�the� loop� gain� and� phase.� An� output� current� pulse� of� 20%�
�to� 80%� of� full-load� current� having� a� rise� time� of� <1μs� will�
�produce� output� voltage� and� I� TH� pin� waveforms� that� will�
�give� a� sense� of� the� overall� loop� stability� without� breaking�
�the� feedback� loop.� The� initial� output� voltage� step� result-�
�ing� from� the� step� change� in� output� current� may� not� be�
�within� the� bandwidth� of� the� feedback� loop,� so� this� signal�
�cannot� be� used� to� determine� phase� margin.� This� is� why�
�it� is� better� to� look� at� the� I� TH� pin� signal� which� is� in� the�
�feedback� loop� and� is� the� filtered� and� compensated� control�
�loop� response.� The� gain� of� the� loop� will� be� increased�
�by� increasing� R� C� and� the� bandwidth� of� the� loop� will� be�
�increased� by� decreasing� C� C� .� If� R� C� is� increased� by� the�
�same� factor� that� C� C� is� decreased,� the� zero� frequency� will�
�be� kept� the� same,� thereby� keeping� the� phase� the� same� in�
�the� most� critical� frequency� range� of� the� feedback� loop.�
�The� output� voltage� settling� behavior� is� related� to� the�
�stability� of� the� closed-loop� system� and� will� demonstrate�
�the� actual� overall� supply� performance.�
�3734fa�
�21�
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