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参数资料
| 型号: | MAX1897ETP+T |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 19/33页 |
| 文件大小: | 0K |
| 描述: | IC REG CTRLR BUCK PWM 20-TQFN |
| 标准包装: | 2,500 |
| 系列: | Quick-PWM™ |
| PWM 型: | 控制器 |
| 输出数: | 1 |
| 频率 - 最大: | 550kHz |
| 电源电压: | 4.5 V ~ 5.5 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: | 0°C ~ 85°C |
| 封装/外壳: | 20-WQFN 裸露焊盘 |
| 包装: | 带卷 (TR) |
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�Quick-PWM� Slave� Controllers� for�
�Multiphase,� Step-Down� Supplies�
�t� ON� =� K� ?� COMP� ?�
�I� PEAK� =� I� LOAD� (� MAX� )� ?�
�2� η� ?�
�?�
�in� MOSFET� technology� that� are� making� higher� frequen-�
�cies� more� practical.�
�Setting� Switch� On� Time:� The� constant� on-time� control�
�algorithm� in� the� master� results� in� a� nearly� constant�
�switching� frequency� despite� the� lack� of� a� fixed-frequen-�
�cy� clock� generator.� In� the� slave,� the� high-side� switch� on�
�time� is� inversely� proportional� to� V+� and� directly� propor-�
�tional� to� the� compensation� voltage� (V� COMP� ):�
�?� V� ?�
�?� V� IN� ?�
�where� K� is� internally� preset� to� 3.3μs� for� the� MAX1887� or�
�externally� set� by� the� TON� pin-strap� connection� for� the�
�MAX1897� (Table� 3)�
�Set� the� nominal� on� time� in� the� slave� to� match� the� on�
�time� in� the� master.� An� exact� match� is� not� necessary�
�because� the� MAX1887/MAX1897� have� wide� t� ON� adjust-�
�ment� ranges� (±40%).� For� example,� if� t� ON� in� the� master�
�is� set� to� 250kHz,� the� slave� can� be� set� to� either� 200kHz�
�or� 300kHz� and� still� achieve� good� performance.� Care�
�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� ):�
�?� 2� +� LIR� ?�
�?�
�where� η� is� the� number� of� phases.�
�Transient� Response�
�The� inductor� ripple� current� affects� transient-response�
�performance,� especially� at� low� V� IN� -� V� OUT� differentials.�
�Low� inductor� values� allow� the� inductor� current� to� slew�
�faster,� replenishing� charge� removed� from� the� output� fil-�
�ter� capacitors� by� a� sudden� load� step.� The� amount� of�
�output� sag� also� is� a� function� of� the� maximum� duty� fac-�
�tor,� which� can� be� calculated� from� the� on� time� and� mini-�
�mum� off� time:�
�(�
�)�
�L� ?� I� LOAD� (� MAX� )� 2� ?� ?� OUT� ?� +� t� OFF� (� MIN� )� ?�
�?� ?� ?�
�?� ?�
�?� ?� (� V� IN� OUT� )� K� ?�
�2� η� C� OUT� OUT� ?� ?� ?� ?� t� OFF� (� MIN� )� ?�
�?� ?� ?� ?�
�should� be� taken� to� ensure� that� the� COMP� voltage�
�remains� within� its� output� voltage� range� (0.42V� to�
�2.80V).�
�Inductor� Operating� Point:� This� choice� provides� trade-�
�offs� between� size� vs.� efficiency� and� transient� response�
�vs.� output� noise.� Low� inductor� values� provide� better�
�transient� response� and� smaller� physical� size,� but� also�
�V� SAG� =�
�V�
�?� ?� V� K� ?� ?�
�V� IN� ?�
�V� IN�
�?� V� ?�
�(� ?� I� LOAD� (� MAX� )� )�
�2� η� C� OUT� OUT�
�result� in� lower� efficiency� and� higher� output� noise� due� to�
�increased� ripple� current.� The� minimum� practical� induc-�
�tor� value� is� one� that� causes� the� circuit� to� operate� at� the�
�edge� of� critical� conduction� (where� the� inductor� current�
�just� touches� zero� with� every� cycle� at� maximum� load).�
�Inductor� values� lower� than� this� grant� no� further� size-�
�reduction� benefit.� The� optimum� operating� point� is� usu-�
�ally� found� between� 20%� and� 50%� ripple� current.�
�Inductor� Selection�
�The� switching� frequency� and� operating� point� (%� ripple�
�or� LIR)� determine� the� inductor� value� as� follows:�
�where� t� OFF(MIN)� is� the� minimum� off� time� (see� the�
�Electrical� Characteristics� section),� η� is� the� number� of�
�phases,� and� K� is� from� Table� 3.�
�The� amount� of� overshoot� due� to� stored� inductor� energy�
�can� be� calculated� as:�
�2�
�L�
�V� SOAR� ≈�
�V�
�Setting� the� Current� Limits�
�The� master� and� slave� current-limit� thresholds� must� be�
�L� =�
�V� OUT� x� (� V� IN� ?� V� OUT� )� x� η�
�V� IN� xf� SW� xI� LOAD� (� MAX� )� xLIR�
�great� enough� to� support� the� maximum� load� current,�
�even� under� worst-case� operating� conditions.� Since� the�
�master� ’� s� current� limit� determines� the� maximum� load�
�(see� the� Current-Limit� Circuitry� section),� the� procedure�
�where� η� is� the� number� of� phases.� Example:� η� =� 2,�
�I� LOAD� =� 40A,� V� IN� =� 12V,� V� OUT� =� 1.3V,� f� SW� =� 300kHz,�
�30%� ripple� current� or� LIR� =� 0.3:�
�for� setting� the� current� limit� is� sequential.� First,� the� mas-�
�ter� ’� s� current� limit� is� set� based� on� the� operating� condi-�
�tions� and� the� characteristics� of� the� low-side� MOSFETs.�
�L� =�
�1� .� 3� V� x� (� 12� V� ?� 1� .� 3� V� )� x� 2�
�12� V� x� 300� kHz� x� 40� A� x� 0� .� 3�
�=� 0� .� 64� μ� H�
�Then� the� slave� controller� is� configured� to� adjust� the�
�master� ’� s� current-limit� threshold� based� on� the� precise�
�current-sense� resistor� value� and� variation� in� the� MOS-�
�FET� characteristics.� Finally,� the� resulting� valley� current�
�limit� for� the� slave� ’� s� inductor� occurs� above� the� master� ’� s�
�______________________________________________________________________________________�
�19�
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