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| 型号: | MAX1897ETP+T |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 25/33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�
�?� ?� ?� I�
�?�
�?� V�
�LOAD� ?� R�
�PD� (� N� L� Re� sistive� )� =� ?� 1� ?� ?� ?� ?� ?�
�?�
�η�
�?� V� IN� (� MAX� )� ?� ?� ?� ?�
�?�
�?� ?�
�I� LOAD� =� η� I� VALLEY� (� MAX� )� +� ?� ?�
�?� ?�
�V� IN(MAX)� ,� consider� choosing� another� MOSFET� with�
�lower� parasitic� capacitance.�
�For� the� low-side� MOSFET� (N� L� ),� the� worst-case� power�
�dissipation� always� occurs� at� maximum� input� voltage:�
�2�
�OUT�
�DS� (� ON� )�
�The� worst� case� for� MOSFET� power� dissipation� occurs�
�under� heavy� overloads� that� are� greater� than�
�I� LOAD(MAX)� but� are� not� quite� high� enough� to� exceed�
�the� current� limit� and� cause� the� fault� latch� to� trip.� To� pro-�
�tect� against� this� possibility,� “� overdesign� ”� the� circuit� to�
�tolerate:�
�?� I� LOAD(MAX)� LIR� ?�
�2�
�where� I� VALLEY(MAX)� is� the� maximum� valley� current�
�allowed� by� the� current-limit� circuit,� including� threshold�
�tolerance� and� on-resistance� variation.� The� MOSFETs�
�must� have� a� good-sized� heatsink� to� handle� the� over-�
�load� power� dissipation.�
�Choose� a� Schottky� diode� (D1)� with� a� forward� voltage�
�low� enough� to� prevent� the� low-side� MOSFET� body�
�diode� from� turning� on� during� the� dead� time.� As� a� gen-�
�eral� rule,� select� a� diode� with� a� DC� current� rating� equal�
�to� 1/(3� η� )� of� the� load� current.� This� diode� is� optional� and�
�can� be� removed� if� efficiency� is� not� critical.�
�Current� Balance� Compensation� (COMP)�
�The� current� balance� compensation� capacitor� (C� COMP� )�
�integrates� the� difference� of� the� master� and� slave� cur-�
�rent-sense� signals,� while� the� compensation� resistor�
�improves� transient� response� by� increasing� the� phase�
�margin.� This� allows� the� user� to� optimize� the� dynamics�
�of� the� current� balance� loop.� Excessively� large� capacitor�
�values� increase� the� integration� time� constant,� resulting�
�in� larger� current� differences� between� the� phases� during�
�transients.� Excessively� small� capacitor� values� allow� the�
�current� loop� to� respond� cycle� by� cycle� but� can� result� in�
�small� DC� current� variations� between� the� phases.�
�Likewise,� excessively� large� series� resistance� can� also�
�cause� DC� current� variations� between� the� phases.� Small�
�series� resistance� reduces� the� phase� margin,� resulting�
�in� marginal� stability� in� the� current� balance� loop.� For�
�most� applications,� a� 470pF� capacitor� and� 10k� ?� series�
�resistor� from� COMP� to� the� converter� ’� s� output� voltage�
�works� well.�
�The� compensation� network� can� be� tied� to� V� OUT� to�
�include� the� feed-forward� term� due� to� the� master� ’� s� on�
�time� (see� the� On-time� Control� and� Active� Current�
�Balancing� section).� To� reduce� noise� pick-up� in� applica-�
�tions� that� have� a� widely� distributed� layout,� it� is� some-�
�times� helpful� to� connect� the� compensation� network� to�
�quiet� analog� ground� rather� than� V� OUT� .�
�Applications� Information�
�Voltage� Positioning� and�
�Effective� Efficiency�
�Powering� new� mobile� processors� requires� careful�
�attention� to� detail� to� reduce� cost,� size,� and� power� dissi-�
�pation.� As� CPUs� became� more� power� hungry,� it� was�
�recognized� that� even� the� fastest� DC-DC� converters�
�were� inadequate� to� handle� the� transient� power� require-�
�ments.� After� a� load� transient,� the� output� instantly�
�changes� by� ESR� COUT� ?� ?� I� LOAD� .� Conventional� DC-DC�
�converters� respond� by� regulating� the� output� voltage�
�back� to� its� nominal� state� after� the� load� transient� occurs�
�(Figure� 7).� However,� the� CPU� only� requires� that� the� out-�
�put� voltage� remain� above� a� specified� minimum� value.�
�Dynamically� positioning� the� output� voltage� to� this� lower�
�limit� allows� the� use� of� fewer� output� capacitors� and�
�reduces� power� consumption� under� load.�
�For� a� conventional� (nonvoltage-positioned)� circuit,� the�
�total� voltage� change� is:�
�V� P-P� 1� =� 2� ?� (ESR� COUT� ?� ?� I� LOAD� )� +� V� SAG� +� V� SOAR�
�where� V� SAG� and� V� SOAR� are� defined� in� Figure� 8.� Setting�
�the� converter� to� regulate� at� a� lower� voltage� when� under�
�load� allows� a� larger� voltage� step� when� the� output� cur-�
�rent� suddenly� decreases� (Figure� 7).� So� the� total� voltage�
�change� for� a� voltage-positioned� circuit� is:�
�V� P-P� 2� =� (ESR� COUT� ?� ?� I� LOAD� )� +� V� SAG� +� V� SOAR�
�where� V� SAG� and� V� SOAR� are� defined� in� the� Design�
�Procedure� section.� Since� the� amplitudes� are� the� same�
�for� both� circuits� (V� P-P� 1� =� V� P-P� 2),� the� voltage-positioned�
�circuit� tolerates� twice� the� ESR.� Since� the� ESR� specifica-�
�tion� is� achieved� by� paralleling� several� capacitors,� fewer�
�units� are� needed� for� the� voltage-positioned� circuit.�
�An� additional� benefit� of� voltage� positioning� is� reduced�
�power� consumption� at� high� load� currents.� Since� the�
�output� voltage� is� lower� under� load,� the� CPU� draws� less�
�current.� The� result� is� lower� power� dissipation� in� the�
�CPU,� although� some� extra� power� is� dissipated� in�
�R� SENSE� .� For� a� nominal� 1.6V,� 22A� output� (R� LOAD� =�
�72.7m� ?� ),� reducing� the� output� voltage� 2.9%� gives� an�
�output� voltage� of� 1.55V� and� an� output� current� of� 21.3A.�
�Given� these� values,� CPU� power� consumption� is�
�reduced� from� 35.2W� to� 33.03W.� The� additional� power�
�consumption� of� R� SENSE� is:�
�______________________________________________________________________________________�
�25�
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