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| 型号: | MAX864EEE+T |
| 厂商: | Maxim Integrated Products |
| 文件页数: | 7/12页 |
| 文件大小: | 0K |
| 描述: | IC REG SWTCHD CAP DBL INV 16QSOP |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 2,500 |
| 类型: | 切换式电容器(充电泵),倍增器,反相 |
| 输出类型: | 可调式 |
| 输出数: | 2 |
| 输出电压: | ±3.5 V ~ ±12 V |
| 输入电压: | 1.75 V ~ 6 V |
| 频率 - 开关: | 185kHz |
| 电流 - 输出: | 35mA |
| 同步整流器: | 无 |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 16-SSOP(0.154",3.90mm 宽) |
| 包装: | 带卷 (TR) |
| 供应商设备封装: | 16-QSOP |
��
�
�Dual-Output� Charge� Pump� with� Shutdown�
�(� )�
�(� )(� )�
�=� C1� ?� V� +�
�?� 2� V� +�
�V� IN� ?�
�(� )�
�(� )�
�+�
�C� 2� ?� V� +�
�?� V� ?� ?�
�Charge-Pump� Output�
�The� MAX864� is� not� a� voltage� regulator:� the� output�
�source� resistance� of� either� charge� pump� is� approxi-�
�mately� 55� ?� at� room� temperature� (with� V� IN� =� 5V);� and� V+�
�and� V-� approach� +10V� and� -10V,� respectively,� when�
�lightly� loaded.� Both� V+� and� V-� will� droop� toward� GND� as�
�the� current� draw� from� either� V+� or� V-� increases,� since� V-�
�is� derived� from� V+.� Treating� each� converter� separately,�
�the� droop� of� the� negative� supply� (V� DROOP-� )� is� the� prod-�
�uct� of� the� current� draw� from� V-� (I� V-� )� and� the� source�
�resistance� of� the� negative� converter� (RS-):�
�V� DROOP-� =� I� V� -� x� RS� -�
�The� droop� of� the� positive� supply� (V� DROOP+� )� is� the�
�product� of� the� current� draw� from� the� positive� supply�
�(I� LOAD+� )� and� the� source� resistance� of� the� positive� con-�
�verter� (RS+),� where� I� LOAD+� is� the� combination� of� I� V-�
�and� the� external� load� on� V+� (I� V+� ):�
�V� DROOP+� =� I� LOAD+� x� RS+� =� (� I� V+� +� I� V� -� )� x� RS+�
�Determine� V+� and� V-� as� follows:�
�V+� =� 2V� IN� -� V� DROOP+�
�V� -� =� (V+� -� V� DROOP� )�
�=� -(2V� IN� -V� DROOP+� -V� DROOP-� )�
�The� output� resistances� for� the� positive� and� negative�
�charge� pumps� are� tested� and� specified� separately.� The�
�positive� charge� pump� is� tested� with� V-� unloaded.� The�
�negative� charge� pump� is� tested� with� V+� supplied� from�
�an� external� source,� isolating� the� negative� charge� pump.�
�Current� draw� from� either� V+� or� V-� is� supplied� by� the�
�reservoir� capacitor� alone� during� one� half� cycle� of� the�
�clock.� Calculate� the� resulting� ripple� voltage� on� either�
�output� as� follows:�
�Shutdown�
�The� MAX864� features� a� shutdown� mode� that� reduces�
�the� maximum� supply� current� to� 1μA� over� temperature.�
�The� SHDN� pin� is� an� active-low� TTL� logic-level� input.� If�
�the� shutdown� feature� is� unused,� connect� SHDN� to� IN.�
�In� shutdown� mode,� V+� connects� to� IN� through� a� 22� ?�
�switch� and� V-� connects� to� GND� through� a� 6� ?� switch.�
�_________Efficiency� Considerations�
�Theoretically,� a� charge-pump� voltage� multiplier� can�
�approach� 100%� efficiency� under� the� following� condi-�
�tions:�
�?� The� charge-pump� switches� have� virtually� no� offset,�
�and� extremely� low� on-resistance.�
�?� The� drive� circuitry� consumes� minimal� power.�
�?� The� impedances� of� the� reservoir� and� pump� capaci-�
�tors� are� negligible.�
�For� the� MAX864,� the� energy� loss� per� clock� cycle� is� the�
�sum� of� the� energy� loss� in� the� positive� and� negative�
�converters,� as� follows:�
�LOSS� CYCLE� =� LOSS� POS� +� LOSS� NEG�
�1� ?� 2� ?�
�2� ?� ?�
�1� ?� 2� 2� ?�
�2� ?� ?�
�where� V+� and� V-� are� the� actual� measured� output� volt-�
�ages.�
�The� average� power� loss� is� simply:�
�Resulting� in� an� efficiency� of:�
�P� LOSS� =� LOSS� CYCLE� x� f� PUMP�
�V� RIPPLE� =�
�1�
�2�
�I� LOAD� (1� /� f� PUMP� )� (1� /� C� RESERVOIR� )�
�η� =� Total� Output� Power� /� (� Total� Output� Power� ?� P� LOSS�
�)�
�where� I� LOAD� is� the� load� on� either� V+� or� V-.� For� exam-�
�ple,� with� an� f� PUMP� of� 33kHz� and� 6.8μF� reservoir� capaci-�
�tors,� the� ripple� is� 26mV� when� I� LOAD� is� 12mA.�
�Remember� that,� in� most� applications,� the� total� load� on�
�V+� is� the� V+� load� current� (I� V+� )� and� the� current� taken� by�
�the� negative� charge� pump� (I� V-� ).�
�There� will� be� a� substantial� voltage� difference� between�
�(V+� -� V� IN� )� and� V� IN� for� the� positive� pump,� and� between�
�V+� and� V-� if� the� impedances� of� the� pump� capacitors�
�(C1� and� C2)� are� large� with� respect� to� their� respective�
�output� loads.�
�Larger� reservoir� capacitor� (C3� and� C4)� values� will�
�reduce� output� ripple.� Larger� values� of� both� pump� and�
�reservoir� capacitors� will� improve� efficiency.�
�_______________________________________________________________________________________�
�7�
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