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参数资料
| 型号: | MAX1917EEE+T |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 15/18页 |
| 文件大小: | 0K |
| 描述: | IC CNTRLR SYNC BUCK 16-QSOP |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 2,500 |
| 应用: | 控制器,DDR |
| 输入电压: | 4.5 V ~ 22 V |
| 输出数: | 2 |
| 输出电压: | 0.4 V ~ 5 V |
| 工作温度: | 0°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 16-SSOP(0.154",3.90mm 宽) |
| 供应商设备封装: | 16-QSOP |
| 包装: | 带卷 (TR) |
��
�
�Tracking,� Sinking� and� Sourcing,� Synchronous� Buck�
�Controller� for� DDR� Memory� and� Termination� Supplies�
�(� ?� I� LOAD� (� MAX� )� )� � L�
�Design� Procedure�
�Firmly� establish� the� input� voltage� range� and� maximum�
�load� current� before� choosing� a� switching� frequency�
�and� inductor� operating� point� (ripple� current� ratio).� The�
�V� SAG� =�
�2�
�2� � C� f� � DUTY� � (� V� IN� (� MIN� )� ?� V� OUT� )�
�kHz�
�primary� design� trade-off� is� in� choosing� a� good� switch-�
�ing� frequency� and� inductor� operating� point,� and� the� fol-�
�lowing� four� factors� dictate� the� rest� of� the� design:�
�Output� Inductor� Selection�
�The� switching� frequency� (on� time)� and� operating� point�
�(%� ripple� or� LIR)� determine� the� inductor� value� as� follows:�
�1)� Input� Voltage� Range� .� The� maximum� value�
�(V� IN(MAX)� )� must� accommodate� the� worst-case� high�
�input� voltage.� The� minimum� value� (V� IN(MIN)� )� must�
�L� =�
�V� OUT�
�f� � LIR� � I� LOAD� (� MAX� )�
�account� for� the� lowest� input� voltage� after� drops� due�
�to� connectors,� fuses,� and� battery� selector� switches.�
�If� there� is� a� choice� at� all,� lower� input� voltages� result�
�Example:� I� LOAD(MAX)� =� 7A,� V� OUT� =� 1.25V,� f� =� 550kHz,�
�50%� ripple� current� or� LIR� =� 0.5:�
�in� better� efficiency.�
�2)� Maximum� Load� Current� .� There� are� two� values� to�
�consider.� The� peak� load� current� (I� LOAD(MAX)� )�
�L� =�
�1� .� 25� V�
�550� kHz� � 0� .� 5� � 7� A�
�=� 0� .� 65� μ� H� (� 0� .� 68� μ� H� )�
�determines� the� instantaneous� component� stresses�
�and� filtering� requirements,� and� thus� drives� output�
�capacitor� selection,� inductor� saturation� rating,� and�
�the� design� of� the� current-limit� circuit.� The� continu-�
�ous� load� current� (I� LOAD� )� determines� the� thermal�
�stresses� and� thus� drives� the� selection� of� input�
�capacitors,� MOSFETs,� and� other� critical� heat-con-�
�tributing� components.�
�3)� Switching� Frequency� .� This� determines� the� basic�
�trade-off� between� size� and� efficiency.� The� optimal�
�frequency� is� largely� a� function� of� maximum� input�
�voltage,� due� to� MOSFET� switching� losses� that� are�
�proportional� to� frequency� and� V� IN2� .� The� optimum�
�frequency� is� also� a� moving� target,� due� to� rapid�
�improvements� in� MOSFET� technology� that� are� mak-�
�ing� higher� frequencies� more� practical.�
�4)� Inductor� Operating� Point� .� This� provides� trade-offs�
�between� size� and� efficiency.� Low� inductor� values�
�cause� large� ripple� currents,� resulting� in� the� smallest�
�size� but� poor� efficiency� and� high� output� noise.� The�
�minimum� practical� inductor� value� is� one� that� causes�
�the� circuit� to� operate� at� the� edge� of� critical� conduc-�
�tion� (where� the� inductor� current� just� touches� zero�
�with� every� cycle� at� maximum� load).� Inductor� values�
�Find� a� low-loss� inductor� having� the� lowest� possible� DC�
�resistance� that� fits� in� the� allotted� dimensions.� Ferrite�
�cores� are� often� the� best� choice,� although� powdered�
�iron� is� inexpensive� and� can� work� well� at� 200kHz.� The�
�core� must� be� large� enough� not� to� saturate� at� the� peak�
�inductor� current:�
�(I� PEAK� ):� I� PEAK� =� I� LOAD(MAX)� +� (LIR� /� 2)� (I� LOAD(MAX)� )�
�Output� Capacitor� Selection�
�The� output� filter� capacitor� must� have� low� enough� ESR�
�to� meet� output� ripple� and� load-transient� requirements,�
�yet� have� high� enough� ESR� to� satisfy� stability� require-�
�ments.� Also,� the� capacitance� value� must� be� high�
�enough� to� absorb� the� inductor� energy� going� from� a�
�positive� full-load� to� negative� full-load� condition� or� vice�
�versa� without� incurring� significant� over/undershoot.� In�
�DDR� termination� applications� where� the� output� is� sub-�
�ject� to� violent� load� transients,� the� output� capacitor� ’� s�
�size� depends� on� how� much� ESR� is� needed� to� prevent�
�the� output� from� dipping� too� low� under� a� load� transient.�
�Ignoring� the� sag� due� to� finite� capacitance:�
�lower� than� this� grant� no� further� size-reduction� benefit.�
�The� inductor� ripple� current� also� impacts� transient-�
�response� performance,� especially� at� low� V� IN� -� V� OUT� dif-�
�R� ESR� ≤�
�V� DIP�
�I� LOAD� (� MAX� )�
�=�
�40� mV�
�14� A�
�=� 2� .� 85� m� ?�
�ferentials.� Low� inductor� values� allow� the� inductor�
�current� to� slew� faster,� replenishing� charge� removed�
�from� the� output� filter� capacitors� by� a� sudden� load� step.�
�The� amount� of� output� sag� is� also� a� function� of� the� maxi-�
�In� DDR� applications,� V� DIP� =� 40mV,� the� output� capaci-�
�tor� ’� s� size� depends� on� how� much� ESR� is� needed� to�
�maintain� an� acceptable� level� of� output� voltage� ripple:�
�mum� duty� factor,� which� can� be� calculated� from� the� on�
�time� and� minimum� off� time:�
�R� ESR� ≤�
�V� P� ?� P�
�LIR� � I� LOAD� (� MAX� )�
�=�
�9� mV�
�0� .� 5� � 7� A�
�=� 2� .� 57� m� ?�
�______________________________________________________________________________________�
�15�
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