参数资料
| 型号: | MAX1801EKA+T |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 11/16页 |
| 文件大小: | 0K |
| 描述: | IC CNTRLR DC-DC SOT23-8 |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 2,500 |
| 应用: | 控制器,数字式相机 |
| 输入电压: | 2.7 V ~ 5.5 V |
| 输出数: | 1 |
| 工作温度: | 0°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | SOT-23-8 |
| 供应商设备封装: | SOT-23-8 |
| 包装: | 带卷 (TR) |
��
�
�Digital� Camera� Step-Up� Slave�
�DC-DC� Controller�
�P� 2� ≈� OUT� L� OSC� T�
�Since� the� external� gate� drive� (DL)� swings� between� IN�
�and� GND,� use� a� MOSFET� whose� on-resistance� is� spec-�
�ified� at� or� below� V� IN� .� The� gate� charge,� Qg,� includes� all�
�capacitance� associated� with� gate� charging� and� helps�
�to� predict� the� transition� time� required� to� drive� the� MOS-�
�FET� between� on� and� off� states.� The� power� dissipated� in�
�the� MOSFET� is� due� to� on-resistance� and� transition� loss-�
�es.� The� on-resistance� loss� is:�
�P� 1� ≈� D� I� L� 2� R� DS(ON)�
�where� D� is� the� duty� cycle,� I� L� is� the� average� inductor�
�current,� and� R� DS(ON)� is� the� on-resistance� of� the� MOS-�
�FET.� The� transition� loss� is� approximately:�
�V� I� f� t�
�3�
�where� V� OUT� is� the� output� voltage,� I� L� is� the� average�
�inductor� current,� f� OSC� is� the� converter� switching� fre-�
�quency,� and� t� T� is� the� transition� time.� The� transition� time�
�is� approximately� Q� g� /� I� G� ,� where� Q� g� is� the� total� gate�
�charge� and� I� G� is� the� gate� drive� current� (typically� 0.5A).�
�The� total� power� dissipation� in� the� MOSFET� is:�
�P� MOSFET� =� P� 1� +� P� 2�
�Diode� Selection�
�For� low-output-voltage� applications,� use� a� Schottky�
�diode� to� rectify� the� output� voltage� because� of� the�
�diode� ’� s� low� forward� voltage� and� fast� recovery� time.�
�Schottky� diodes� exhibit� significant� leakage� current� at�
�high� reverse� voltages� and� high� temperatures.� Thus,� for�
�high-voltage,� high-temperature� applications,� use� ultra-�
�fast� junction� rectifiers.�
�Compensation� Design�
�MAX1801� converters� use� voltage� mode� to� regulate� their�
�The� frequency� of� the� single� pole� due� to� the� PWM� con-�
�verter� is:�
�P� O� =� (2� V� OUT� –� V� IN� )� /� (2� π� (V� OUT� –� V� IN� )� R� LOAD� C� OUT� )�
�And� the� DC� gain� of� the� PWM� controller� is:�
�A� VO� =� 2� V� OUT� (V� OUT� –� V� IN� )� R� LOAD� /� ((2� V� OUT� –� V� IN� )� D)�
�Note� that� the� pole� frequency� decreases� and� the� DC�
�gain� increases� proportionally� as� the� load� resistance�
�(RLOAD)� is� increased.� Since� the� crossover� frequency�
�is� the� product� of� the� pole� frequency� and� the� DC� gain,� it�
�remains� independent� of� the� load.�
�The� gain� through� the� voltage-divider� is:�
�A� VDV� =� V� REF� /� V� OUT�
�And� the� DC� gain� of� the� error� amplifier� is� A� VEA� =� 2000V/V.�
�Thus,� the� DC� loop� gain� is:�
�A� VDC� =� A� VDV� A� VEA� A� VO�
�The� compensation� resistor-capacitor� pair� at� COMP� cause�
�a� pole� and� zero� at� frequencies� (in� Hz):�
�P� C� =� G� EA� /� (4000� π� C� C� )� =� 1� /� (4� x� 10� 7� π� C� C� )�
�Z� C� =� 1� /� (2� π� R� C� C� C� )�
�And� the� ESR� of� the� output� filter� capacitor� causes� a� zero�
�in� the� loop� response� at� the� frequency� (in� Hz):�
�Z� O� =� 1� /� (2� π� C� OUT� ESR)�
�The� DC� gain� and� the� poles� and� zeros� are� shown� in� the�
�Bode� plot� of� Figure� 4.�
�To� achieve� a� stable� circuit� with� the� Bode� plot� of� Figure�
�4,� perform� the� following� procedure:�
�output� voltages.� The� following� explains� how� to� compen-�
�sate� the� control� system� for� optimal� performance.� The�
�compensation� differs� depending� on� whether� the� induc-�
�tor� current� is� continuous� or� discontinuous.�
�80�
�A� VDC�
�60�
�P� C�
�180°�
�PHASE�
�Discontinuous� Inductor� Current�
�For� discontinuous� inductor� current,� the� PWM� converter�
�has� a� single� pole.� The� pole� frequency� and� DC� gain� of�
�the� PWM� controller� are� dependent� on� the� operating�
�GAIN�
�(dB)�
�40�
�20�
�Z� C� = P� O�
�90°�
�PHASE�
�duty� cycle,� which� is:�
�GAIN�
�D� =� (2� L� f� OSC� /� R� E� )� 1/2�
�O�
�0°�
�where� R� E� is� the� equivalent� load� resistance,� or:�
�R� E� =� V� IN2� R� LOAD� /� (V� OUT� (V� OUT� –� V� IN� ))�
�-20�
�FREQUENCY�
�Z� O�
�Figure� 4.� MAX1801� Discontinuous-Current,� Voltage-Mode,�
�Step-Up� Converter� Bode� Plot�
�______________________________________________________________________________________�
�11�
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