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参数资料
| 型号: | MAX8513EEI+T |
| 厂商: | Maxim Integrated |
| 文件页数: | 21/35页 |
| 文件大小: | 0K |
| 描述: | IC REG TRPL BUCK/LINEAR 28QSOP |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 2,500 |
| 拓扑: | 降压(降压)(1),线性(LDO)(2) |
| 功能: | 任何功能 |
| 输出数: | 3 |
| 频率 - 开关: | 250kHz ~ 1.5MHz |
| 电压/电流 - 输出 1: | 控制器 |
| 电压/电流 - 输出 2: | 控制器 |
| 电压/电流 - 输出 3: | 控制器 |
| 带 LED 驱动器: | 无 |
| 带监控器: | 无 |
| 带序列发生器: | 无 |
| 电源电压: | 4.5 V ~ 28 V |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 28-SSOP(0.154",3.90mm 宽) |
| 供应商设备封装: | 28-QSOP |
| 包装: | 带卷 (TR) |
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�
�Wide-Input,� High-Frequency,� Triple-Output� Supplies�
�with� Voltage� Monitor� and� Power-On� Reset�
�P� Q� 1� SW� =� V� IN� � I� OUT� 1� � f� S� �
�(� Q� GS� +� Q� GD� )�
�I� GATE�
�1)� Connect� a� scope� probe� to� measure� V� LX� to� GND,�
�and� observe� the� ringing� frequency,� f� R� .�
�2)� Find� the� capacitor� value� (connected� from� LX� to�
�GND)� that� reduces� the� ringing� frequency� by� half.�
�(�
�R� DH� GATE� )�
�L� PAR� =�
�(� 2� π�
�� f� R� )�
�where� I� GATE� is� the� average� DH� high� driver� output-cur-�
�rent� capability� determined� by:�
�2� .� 5� V�
�I� GATE� =�
�+� R�
�where� R� DH� is� the� high-side� MOSFET� driver’s� on-resis-�
�tance� (1.5� ?� typ)� and� R� GATE� is� the� internal� gate� resis-�
�tance� of� the� MOSFET� (� ≈� 2� ?� ).�
�The� circuit� parasitic� capacitance� (C� PAR� )� at� LX� is� then�
�equal� to� 1/3rd� the� value� of� the� added� capacitance� above.�
�The� circuit� parasitic� inductance� (L� PAR� )� is� calculated� by:�
�1�
�2�
�� C� PAR�
�The� resistor� for� critical� dampening� (R� SNUB� )� is� equal� to�
�(2� π� ×� f� R� ×� L� PAR� ).� Adjust� the� resistor� value� up� or� down� to�
�P� Q� 1� DR� =� Q� GS� � V� GS� � f� S� �
�R� GATE�
�(� R� GATE� +� R� DH�
�)�
�tailor� the� desired� damping� and� the� peak� voltage� excur-�
�sion.� The� capacitor� (C� SNUB� )� should� be� at� least� 2� to� 4�
�times� the� value� of� the� C� PAR� to� be� effective.� The� power�
�loss� of� the� snubber� circuit� is� dissipated� in� the� resistor�
�where� V� GS� ≈� V� VL� =� 5V.�
�The� total� power� loss� in� Q1� is:�
�(P� RSNUB� )� and� can� be� calculated� as:�
�P� Q� 1� =� P� Q� 1� CC� +� P� Q� 1� SW� +� P� Q� 1� DR�
�P� RSNUB� =� C� SNUB� � (� V� IN� )�
�2�
�� f� S�
�In� addition� to� the� losses� above,� allow� approximately�
�20%� more� for� additional� losses� due� to� MOSFET� output�
�capacitances� and� Q2� body-diode� reverse� recovery�
�charge� dissipated� in� Q1.� This� is� not� typically� well-�
�defined� in� MOSFET� data� sheets.� Refer� to� the� MOSFET�
�data� sheet� for� the� thermal-resistance� specification� to�
�calculate� the� PC� board� area� needed� to� maintain� the�
�desired� maximum� operating� junction� temperature� with�
�the� above� calculated� power� dissipations.�
�To� reduce� EMI� caused� by� switching� noise,� add� a� 0.1μF�
�or� larger� ceramic� capacitor� from� the� high-side� MOSFET�
�drain� to� the� low-side� MOSFET� source� or� add� resistors�
�in� series� with� DH� and� DL� to� slow� down� the� switching�
�transitions.� However,� adding� series� resistors� with� DH�
�and� DL� increases� the� power� dissipation� in� the� MOSFET�
�when� it� switches,� so� be� sure� this� does� not� overheat� the�
�MOSFET.� The� minimum� load� current� must� exceed� the�
�high-side� MOSFET’s� maximum� leakage� current� over�
�temperature� if� fault� conditions� are� expected.�
�MOSFET� Snubber� Circuit�
�Fast� switching� transitions� cause� ringing� because� of� res-�
�onating� circuit� parasitic� inductance� and� capacitance� at�
�the� switching� nodes.� This� high-frequency� ringing�
�occurs� at� LX’s� rising� and� falling� transitions� and� can�
�interfere� with� circuit� performance� and� generate� EMI.� To�
�dampen� this� ringing,� a� series-RC� snubber� circuit� is�
�added� across� each� switch.� The� following� is� the� proce-�
�dure� for� selecting� the� value� of� the� series-RC� circuit:�
�where� V� IN� is� the� input� voltage� and� f� S� is� the� switching�
�frequency.� Choose� an� R� SNUB� power� rating� that� meets�
�the� specific� application’s� derating� rule� for� the� power�
�dissipation� calculated.�
�Current-Limit� Setting�
�The� MAX8513/MAX8514� can� provide� foldback� current�
�limit� or� constant� current� limit.� Unless� constant� current-�
�limit� operation� is� required,� such� as� when� driving� a� con-�
�stant� current� load,� foldback� current� limit� should� be�
�implemented.� Foldback� current� limit� reduces� the� power�
�dissipation� of� external� components� under� overload� or�
�short-circuit� conditions.�
�Foldback� Current� Limit�
�For� foldback� current� limit,� the� current-limit� threshold� is�
�set� by� an� external� resistive-divider� from� V� OUT1� to� ILIM� to�
�GND� (R17� and� R18� of� the� Typical� Applications� Circuits� ).�
�This� makes� the� voltage� at� ILIM� a� function� of� the� internal�
�5μA� current� source� and� V� OUT1� .� The� current-limit� com-�
�parator� threshold� is� equal� to� V� ILIM� /� 7.5.� This� threshold� is�
�compared� with� V� SENSE� .� V� SENSE� is� either� the� voltage�
�across� the� current-sense� resistor� or,� for� lossless� sens-�
�ing,� the� voltage� across� the� inductor.� When� V� SENSE�
�exceeds� the� current-limit� threshold,� the� high-side�
�MOSFET� turns� off� and� the� low-side� MOSFET� turns� on.�
�This� allows� for� a� current� foldback� feature� that� reduces�
�the� current-limit� threshold� during� a� short� circuit.� This�
�makes� the� current� threshold� limit,� when� V� OUT� =� 0V,� a�
�percentage� of� the� current-limit� threshold,� when� V� OUT1� is�
�at� its� nominal� regulated� value.�
�______________________________________________________________________________________�
�21�
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