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参数资料
| 型号: | MAX15026CATD+T |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 18/23页 |
| 文件大小: | 0K |
| 描述: | IC REG CTRLR BUCK PWM VM 14TDFN |
| 产品培训模块: | Obsolescence Mitigation Program |
| 标准包装: | 2,500 |
| PWM 型: | 电压模式 |
| 输出数: | 1 |
| 频率 - 最大: | 2.4MHz |
| 占空比: | 88% |
| 电源电压: | 4.5 V ~ 28 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 ~ 125°C |
| 封装/外壳: | 14-WFDFN 裸露焊盘 |
| 包装: | 带卷 (TR) |
��
�
�MAX15026�
�Low-Cost,� Small,� 4.5V� to� 28V� Wide� Operating�
�Range,� DC-DC� Synchronous� Buck� Controller�
�Boost� Capacitor�
�The� MAX15026� uses� a� bootstrap� circuit� to� generate� the�
�necessary� gate-to-source� voltage� to� turn� on� the� high-�
�side� MOSFET.� The� selected� n-channel� high-side�
�MOSFET� determines� the� appropriate� boost� capaci-�
�tance� value� (C� BST� in� the� Typical� Application� Circuits)�
�according� to� the� following� equation:�
�estimation� of� the� junction� temperature� requires� a� direct�
�measurement� of� the� case� temperature� (T� C� )� when� actual�
�operating� conditions� significantly� deviate� from� those�
�described� in� the� JEDEC� standards.� The� junction� tem-�
�perature� is� then:�
�T� J� =� T� C� +� (P� T� x� θ� JC� )�
�Use� 8.7°C/W� as� θ� JC� thermal� impedance� for� the� 14-pin�
�C� BST� =�
�Q� G�
�?� V� BST�
�TDFN� package.� The� case-to-ambient� thermal� imped-�
�ance� (� θ� CA� )� is� dependent� on� how� well� the� heat� is� trans-�
�ferred� from� the� PCB� to� the� ambient.� Solder� the� exposed�
�where� Q� G� is� the� total� gate� charge� of� the� high-side�
�MOSFET� and� ?� V� BST� is� the� voltage� variation� allowed� on�
�the� high-side� MOSFET� driver� after� turn-on.� Choose�
�?� V� BST� so� the� available� gate-drive� voltage� is� not� signifi-�
�cantly� degraded� (e.g.� ?� V� BST� =� 100mV� to� 300mV)� when�
�determining� C� BST� .� Use� a� low-ESR� ceramic� capacitor� as�
�the� boost� flying� capacitor� with� a� minimum� value� of�
�100nF.�
�Power� Dissipation�
�The� maximum� power� dissipation� of� the� device� depends�
�on� the� thermal� resistance� from� the� die� to� the� ambient�
�environment� and� the� ambient� temperature.� The� thermal�
�resistance� depends� on� the� device� package,� PCB� cop-�
�per� area,� other� thermal� mass,� and� airflow.�
�The� power� dissipated� into� the� package� (P� T� )� depends�
�on� the� supply� configuration� (see� the� Typical� Application�
�Circuits).� Use� the� following� equation� to� calculate� power�
�dissipation:�
�P� T� =� (V� IN� -� V� CC� )� x� I� LDO� +� V� DRV� x� I� DRV� +� V� CC� x� I� IN�
�where� I� LDO� is� the� current� supplied� by� the� internal� regu-�
�lator,� I� DRV� is� the� supply� current� consumed� by� the� dri-�
�vers� at� DRV,� and� I� IN� is� the� supply� current� of� the�
�MAX15026� without� the� contribution� of� the� I� DRV� ,� as� given�
�in� the� Typical� Operating� Characteristics.� For� example,� in�
�the� application� circuit� of� Figure� 5,� I� LDO� =� I� DRV� +� I� IN� and�
�V� DRV� =� V� CC� so� that� P� T� =� V� IN� x� (I� DRV� +� I� IN� ).�
�Use� the� following� equation� to� estimate� the� temperature�
�rise� of� the� die:�
�T� J� =� T� A� +� (P� T� x� θ� JA� )�
�where� θ� JA� is� the� junction-to-ambient� thermal� imped-�
�ance� of� the� package,� P� T� is� power� dissipated� in� the�
�device,� and� T� A� is� the� ambient� temperature.� The� θ� JA� is�
�24.4°C/W� for� 14-pin� TDFN� package� on� multilayer�
�boards,� with� the� conditions� specified� by� the� respective�
�JEDEC� standards� (JESD51-5,� JESD51-7).� An� accurate�
�18�
�pad� of� the� TDFN� package� to� a� large� copper� area� to�
�spread� heat� through� the� board� surface,� minimizing� the�
�case-to-ambient� thermal� impedance.� Use� large� copper�
�areas� to� keep� the� PCB� temperature� low.�
�PCB� Layout� Guidelines�
�Place� all� power� components� on� the� top� side� of� the�
�board,� and� run� the� power� stage� currents� using� traces�
�or� copper� fills� on� the� top� side� only.� Make� a� star� connec-�
�tion� on� the� top� side� of� traces� to� GND� to� minimize� volt-�
�age� drops� in� signal� paths.�
�Keep� the� power� traces� and� load� connections� short,�
�especially� at� the� ground� terminals.� This� practice� is�
�essential� for� high� efficiency� and� jitter-free� operation.� Use�
�thick� copper� PCBs� (2oz� or� above)� to� enhance� efficiency.�
�Place� the� MAX15026� adjacent� to� the� synchronous� recti-�
�fier� MOSFET,� preferably� on� the� back� side,� to� keep� LX,�
�GND,� DH,� and� DL� traces� short� and� wide.� Use� multiple�
�small� vias� to� route� these� signals� from� the� top� to� the� bot-�
�tom� side.� Use� an� internal� quiet� copper� plane� to� shield�
�the� analog� components� on� the� bottom� side� from� the�
�power� components� on� the� top� side.�
�Make� the� MAX15026� ground� connections� as� follows:�
�create� a� small� analog� ground� plane� near� the� device.�
�Connect� this� plane� to� GND� and� use� this� plane� for� the�
�ground� connection� for� the� V� IN� bypass� capacitor,� com-�
�pensation� components,� feedback� dividers,� V� CC� capaci-�
�tor,� RT� resistor,� and� LIM� resistor.�
�Use� Kelvin� sense� connections� for� LX� and� GND� to� the�
�synchronous� rectifier� MOSFET� for� current� limiting� to�
�guarantee� the� current-limit� accuracy.�
�Route� high-speed� switching� nodes� (BST,� LX,� DH,� and� DL)�
�away� from� the� sensitive� analog� areas� (RT,� COMP,� LIM,�
�and� FB).� Group� all� GND-referred� and� feedback� compo-�
�nents� close� to� the� device.� Keep� the� FB� and� compensation�
�network� as� small� as� possible� to� prevent� noise� pickup.�
�Maxim� Integrated�
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