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参数资料
| 型号: | ADP1111ANZ-12 |
| 厂商: | Analog Devices Inc |
| 文件页数: | 8/15页 |
| 文件大小: | 0K |
| 描述: | IC REG BUCK BST INV 12V .2A 8DIP |
| 标准包装: | 50 |
| 类型: | 降压(降压),升压(升压),反相 |
| 输出类型: | 固定 |
| 输出数: | 1 |
| 输出电压: | 12V |
| 输入电压: | 2 V ~ 30 V |
| 频率 - 开关: | 72kHz |
| 电流 - 输出: | 200mA |
| 同步整流器: | 无 |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 通孔 |
| 封装/外壳: | 8-DIP(0.300",7.62mm) |
| 包装: | 管件 |
| 供应商设备封装: | 8-PDIP |
��
�
�ADP1111�
�As� previously� mentioned,� the� switch� voltage� is� higher� in� step-�
�down� mode� than� in� step-up� mode.� V� SW� is� a� function� of� switch�
�During� each� switching� cycle,� the� inductor� must� supply� the�
�following� energy:�
�current� and� is� therefore� a� function� of� V� IN� ,� L,� time� and� V� OUT� .�
�For� most� applications,� a� V� SW� value� of� 1.5� V� is� recommended.�
�The� inductor� value� can� now� be� calculated:�
�P� L�
�f� OSC�
�=�
�275� mW�
�72� kHz�
�=� 3.8� μ� J�
�L� =�
�V� IN� (� MIN� )� ?� V� SW� ?� V� OUT�
�I� PEAK�
�?� t� ON�
�(Equation� 7)�
�Using� a� standard� inductor� value� of� 56� μ� H� with� 0.2� Ω� dc�
�resistance� will� produce� a� peak� switch� current� of:�
�?� 1� ?� e�
�?� =� 445� mA�
�where� t� ON� =� switch� ON� time� (7� μ� s).�
�If� the� input� voltage� will� vary� (such� as� an� application� that� must�
�I� PEAK� =�
�4.5� V� ?� 0.75� V� ?�
�0.65� Ω� +� 0.2� Ω� ?�
�?� 0.85� Ω ?� 7� μ� s� ?�
�56� μ� H�
�?�
�operate� from� a� 9� V,� 12� V� or� 15� V� source),� an� R� LIM� resistor�
�should� be� selected� from� Figure� 6.� The� R� LIM� resistor� will� keep�
�switch� current� constant� as� the� input� voltage� rises.� Note� that�
�Once� the� peak� current� is� known,� the� inductor� energy� can� be�
�calculated� from� (Equation� 9):�
�there� are� separate� R� LIM� values� for� step-up� and� step-down� modes�
�of� operation.�
�For� example,� assume� that� +5� V� at� 300� mA� is� required� from� a�
�E� L� =�
�1�
�2�
�(� 56� μ� H� )� ?� (� 445� mA� )� 2� =� 5.54� μ� J�
�+12� V� to� +24� V� source.� Deriving� the� peak� current� from�
�Equation� 6� yields:�
�Since� the� inductor� energy� of� 5.54� μ� J� is� greater� than� the� P� L� /f� OSC�
�requirement� of� 3.82� μ� J� ,� the� 56� μ� H� inductor� will� work� in� this�
�?� 12� ?� 1.5� +� 0.5� ?� =� 600� mA�
�?� ?�
�I� PEAK� =�
�2� ?� 300� mA� ?� 5� +� 0.5� ?�
�0.5�
�application.�
�The� input� voltage� only� varies� between� 4.5� V� and� 5.5� V� in� this�
�application.� Therefore,� the� peak� current� will� not� change� enough�
�Then,� the� peak� current� can� be� inserted� into� Equation� 7� to�
�calculate� the� inductor� value:�
�to� require� an� R� LIM� resistor� and� the� I� LIM� pin� can� be� connected�
�directly� to� V� IN� .� Care� should� be� taken,� of� course,� to� ensure� that�
�the� peak� current� does� not� exceed� 650� mA.�
�L� =�
�12� ?� 1.5� ?� 5�
�600� mA�
�?� 7� μ� s� =� 64� μ� H�
�CAPACITOR� SELECTION�
�P� L� =� (� V� +� V� D� )� ?� (� I� OUT� )�
�Since 64 μH is not a standard value, the next lower standard�
�value� of� 56� μ� H� would� be� specified.�
�To� avoid� exceeding� the� maximum� switch� current� when� the�
�input� voltage� is� at� +24� V,� an� R� LIM� resistor� should� be� specified.�
�Using� the� step-down� curve� of� Figure� 6,� a� value� of� 560� Ω� will�
�limit� the� switch� current� to� 600� mA.�
�INDUCTOR� SELECTION–POSITIVE-TO-NEGATIVE�
�CONVERTER�
�The� configuration� for� a� positive-to-negative� converter� using� the�
�ADP1111� is� shown� in� Figure� 22.� As� with� the� step-up� converter,�
�all� of� the� output� power� for� the� inverting� circuit� must� be� supplied�
�by� the� inductor.� The� required� inductor� power� is� derived� from�
�the� formula:�
�OUT� (Equation� 8)�
�The� ADP1111� power� switch� does� not� saturate� in� positive-to-�
�negative� mode.� The� voltage� drop� across� the� switch� can� be�
�modeled� as� a� 0.75� V� base-emitter� diode� in� series� with� a� 0.65� Ω�
�resistor.� When� the� switch� turns� on,� inductor� current� will� rise� at�
�a� rate� determined� by:�
�For� optimum� performance,� the� ADP1111’s� output� capacitor�
�must� be� selected� carefully.� Choosing� an� inappropriate� capacitor�
�can� result� in� low� efficiency� and/or� high� output� ripple.�
�Ordinary� aluminum� electrolytic� capacitors� are� inexpensive� but�
�often� have� poor� Equivalent� Series� Resistance� (ESR)� and�
�Equivalent� Series� Inductance� (ESL).� Low� ESR� aluminum�
�capacitors,� specifically� designed� for� switch� mode� converter�
�applications,� are� also� available,� and� these� are� a� better� choice�
�than� general� purpose� devices.� Even� better� performance� can� be�
�achieved� with� tantalum� capacitors,� although� their� cost� is� higher.�
�Very� low� values� of� ESR� can� be� achieved� by� using� OS-CON�
�capacitors� (Sanyo� Corporation,� San� Diego,� CA).� These� devices�
�are� fairly� small,� available� with� tape-and-reel� packaging� and� have�
�very� low� ESR.�
�The� effects� of� capacitor� selection� on� output� ripple� are� demon-�
�strated� in� Figures� 15,� 16� and� 17.� These� figures� show� the� output�
�of� the� same� ADP1111� converter� that� was� evaluated� with� three�
�different� output� capacitors.� In� each� case,� the� peak� switch�
�current� is� 500� mA,� and� the� capacitor� value� is� 100� μ� F.� Figure� 15�
�shows� a� Panasonic� HF-series� 16-volt� radial� cap.� When� the�
�switch� turns� off,� the� output� voltage� jumps� by� about� 90� mV� and�
�then� decays� as� the� inductor� discharges� into� the� capacitor.� The�
�I� L� (� )� =�
�?� 1� ?� e� L� ?�
�t�
�V� L�
�R� '�
�?� ?� R� '� t� ?�
�?� ?�
�(Equation� 9)�
�rise� in� voltage� indicates� an� ESR� of� about� 0.18� Ω� .� In� Figure� 16,�
�the� aluminum� electrolytic� has� been� replaced� by� a� Sprague� 293D�
�series,� a� 6� V� tantalum� device.� In� this� case� the� output� jumps�
�where:� R'� =� 0.65� Ω� +� R� L(DC)�
�V� L� =� V� IN� –� 0.75� V�
�For� example,� assume� that� a� –5� V� output� at� 50� mA� is� to� be�
�generated� from� a� +4.5� V� to� +5.5� V� source.� The� power� in� the�
�inductor� is� calculated� from� Equation� 8:�
�P� L� =� (� |� ?� 5� V� |� +� 0.5� V� |� )� ?� (� 50� mA� )� =� 275� mW�
�–8� –�
�about� 30� mV,� which� indicates� an� ESR� of� 0.06� Ω� .� Figure� 17�
�shows� an� OS-CON� 16–volt� capacitor� in� the� same� circuit,� and�
�ESR� is� only� 0.02� Ω� .�
�0�
�REV.� A�
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