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参数资料
| 型号: | MAX1639ESE+T |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 12/13页 |
| 文件大小: | 0K |
| 描述: | IC REG CTRLR BUCK PWM CM 16-SOIC |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 2,500 |
| PWM 型: | 电流模式 |
| 输出数: | 1 |
| 频率 - 最大: | 1.2MHz |
| 占空比: | 84% |
| 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: | -40°C ~ 85°C |
| 封装/外壳: | 16-SOIC(0.154",3.90mm 宽) |
| 包装: | 带卷 (TR) |
��
�
�High-Speed� Step-Down� Controller� with�
�Synchronous� Rectification� for� CPU� Power�
�P� D� (� low� side� )� =� I� LOAD�
�x� R� DS� (� ON� )� x� ?� 1� ?�
�CC� 1� =�
�C� OUT� x� R� ESR�
�10� k� ?�
�2�
�?�
�?�
�V� OUT� ?�
�V� IN� ?� ?�
�Resistor� RC1� sets� a� zero� that� can� be� used� to� compen-�
�sate� for� the� sampling� pole� generated� by� the� switching�
�frequency.� Set� RC1� to� the� following:�
�Gate-charge� losses� are� dissipated� in� the� IC,� and� do� not�
�heat� the� MOSFETs.� Ensure� that� both� MOSFETs� are� at� a�
�safe� junction� temperature� by� calculating� the� temperature�
�rise� according� to� package� thermal-resistance� specifica-�
�?� 1� +�
�RC� 1� =�
�?� V� OUT� ?�
�?�
�?� V� IN� ?�
�2� f� OSC� x� CC� 1�
�tions.� The� high-side� MOSFET’s� worst-case� dissipation�
�occurs� at� the� maximum� output� voltage� and� minimum�
�input� voltage.� For� the� low-side� MOSFET,� the� worst� case�
�is� at� the� maximum� input� voltage� when� the� output� is� short-�
�circuited� (consider� the� duty� factor� to� be� 100%).�
�The� CC1� pin’s� output� resistance� is� 10k� ?� .�
�Setting� the� Dominant� Pole�
�and� Canceling� the� Load� and� Output� Filter� Pole�
�Compensate� the� slow-voltage� feedback� loop� by� adding�
�a� ceramic� capacitor� from� the� CC2� pin� to� AGND.� This� is�
�an� integrator� loop� used� to� cancel� out� the� DC� load-�
�regulation� error.� Selection� of� capacitor� CC2� sets� the�
�dominant� pole� and� a� compensation� zero.� The� zero� is� typ-�
�ically� used� to� cancel� the� unwanted� pole� generated� by� the�
�load� and� output� filter� capacitor� at� the� maximum� load� cur-�
�rent.� Select� CC2� to� place� the� zero� close� to� or� slightly�
�lower� than� the� frequency� of� the� unwanted� pole,� as� fol-�
�lows:�
�Calculating� IC� Power� Dissipation�
�Power� dissipation� in� the� IC� is� dominated� by� average�
�gate-charge� current� into� both� MOSFETs.� Average� cur-�
�rent� is� approximately:�
�I� DD� =� (Q� G1� +� Q� G2� )� x� f� OSC�
�where� I� DD� is� the� drive� current,� Q� G� is� the� total� gate�
�charge� for� each� MOSFET,� and� f� OSC� is� the� switching�
�frequency.�
�Power� dissipation� of� the� IC� is:�
�P� D� =� I� CC� x� V� CC� +� I� DD� x� V� DD�
�where� I� CC� is� the� quiescent� supply� current� of� the� IC.�
�Junction� temperature� for� the� IC� is� primarily� a� function� of�
�the� PC� board� layout,� since� most� of� the� heat� is� removed�
�CC� 2� =�
�1� mmho� x� C� OUT�
�4�
�x�
�V� OUT�
�I� OUT� (� MAX� )�
�through� the� traces� connected� to� the� pins� and� the�
�ground� and� power� planes.� A� 16-pin� narrow� SO� on� a�
�typical� four-layer� board� with� ground� and� power� planes�
�The� transconductance� of� the� integrator� amplifier� at� CC2�
�is� 1mmho.� The� voltage� swing� at� CC2� is� internally�
�clamped� around� 2.4V� to� 3V� minimum� and� 4V� to� V� CC�
�maximum� to� improve� transient� response� times.� CC2�
�can� source� and� sink� up� to� 100μA.�
�Choosing� the� MOSFET� Switches�
�The� two� high-current� N-channel� MOSFETs� must� be�
�logic-level� types� with� guaranteed� on-resistance� specifi-�
�cations� at� V� GS� =� 4.5V.� Lower� gate-threshold� specs� are�
�better� (i.e.,� 2V� max� rather� than� 3V� max).� Gate� charge�
�should� be� less� than� 200nC� to� minimize� switching� losses�
�and� reduce� power� dissipation.�
�I� 2� R� losses� are� the� greatest� heat� contributor� to� MOSFET�
�power� dissipation� and� are� distributed� between� the�
�high-� and� low-side� MOSFETs� according� to� duty� factor,�
�as� follows:�
�show� equivalent� junction-to-ambient� thermal�
�impedance� of� (� θ� JA� )� about� 80°C/W.� Junction� tempera-�
�ture� of� the� die� is� approximately:�
�T� J� =� P� D� x� θ� JA� +� T� A�
�where� T� A� is� the� ambient� temperature.�
�Selecting� the� Rectifier� Diode�
�The� rectifier� diode� D1� is� a� clamp� that� catches� the� nega-�
�tive� inductor� swing� during� the� 30ns� typical� dead� time�
�between� turning� off� the� high-side� MOSFET� and� turning�
�on� the� low-side� MOSFET� synchronous� rectifier.� D1� must�
�be� a� Schottky� diode,� to� prevent� the� MOSFET� body�
�diode� from� conducting.� It� is� acceptable� to� omit� D1� and�
�let� the� body� diode� clamp� the� negative� inductor� swing,�
�but� efficiency� will� drop� about� 1%.� Use� a� 1N5819� diode�
�for� loads� up� to� 3A,� or� a� 1N5822� for� loads� up� to� 10A.�
�Adding� the� BST� Supply� Diode�
�P� D� (� high� side� )� =� I� LOAD�
�2�
�x� R� DS� (� ON� )� x�
�V� OUT�
�V� IN�
�and� Capacitor�
�A� signal� diode,� such� as� a� 1N4148,� works� well� for� D2� in�
�most� applications,� although� a� low-leakage� Schottky�
�diode� provides� slightly� improved� efficiency.� Do� not� use�
�12�
�______________________________________________________________________________________�
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