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参数资料
| 型号: | ADD5203ACPZ-RL |
| 厂商: | Analog Devices Inc |
| 文件页数: | 17/24页 |
| 文件大小: | 0K |
| 描述: | IC LED DRVR WHITE BCKLGT 28LFCSP |
| 标准包装: | 1 |
| 恒定电流: | 是 |
| 拓扑: | PWM,升压(升压) |
| 输出数: | 8 |
| 内部驱动器: | 是 |
| 类型 - 主要: | 背光 |
| 类型 - 次要: | 白色 LED |
| 频率: | 350kHz ~ 1MHz |
| 电源电压: | 6 V ~ 21 V |
| 输出电压: | 45V |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 28-WFQFN 裸露焊盘,CSP |
| 供应商设备封装: | 28-LFCSP-WQ(4x4) |
| 包装: | 标准包装 |
| 工作温度: | -25°C ~ 85°C |
| 其它名称: | ADD5203ACPZ-RLDKR |
��
�
�ADD5203�
�EXTERNAL� COMPONENT� SELECTION� GUIDE�
�Inductor� Selection�
�The� inductor� is� an� integral� part� of� the� step-up� converter.� It� stores�
�energy� during� the� switch-on� time� and� transfers� that� energy� to�
�the� output� through� the� output� diode� during� the� switch-off� time.�
�An� inductor� in� the� range� of� 4.7� μH� to� 22� μH� is� recommended.�
�In� general,� lower� inductance� values� result� in� higher� saturation�
�current� and� lower� series� resistance� for� a� given� physical� size.�
�However,� lower� inductance� results� in� higher� peak� current,� which�
�can� lead� to� reduced� efficiency� and� greater� input� and/or� output�
�ripple� and� noise.� Peak-to-peak� inductor� ripple� current� at� close�
�to� 30%� of� the� maximum� dc� input� current� typically� yields� an�
�optimal� compromise.�
�The� input� (V� IN� )� and� output� (V� OUT� )� voltages� determine� the�
�switch� duty� cycle� (D),� which� in� turn� can� be� used� to� determine�
�are� preferred� because� of� their� low� ESR� characteristics.�
�Alternatively,� use� a� high� value,� medium� ESR� capacitor� in�
�parallel� with� a� 0.1� μF� low� ESR� capacitor� as� close� as� possible� to�
�the� ADD5203.�
�The� output� capacitor� maintains� the� output� voltage� and� supplies�
�current� to� the� load� while� the� ADD5203� switch� is� on.� The� value�
�and� characteristics� of� the� output� capacitor� greatly� affect� the�
�output� voltage� ripple� and� stability� of� the� regulator.� Use� a� low�
�ESR� output� capacitor;� ceramic� dielectric� capacitors� are� preferred.�
�For� very� low� ESR� capacitors,� such� as� ceramic� capacitors,� the�
�ripple� current� due� to� the� capacitance� is� calculated� as� follows.�
�Because� the� capacitor� discharges� during� the� on� time� (t� ON� ),� the�
�charge� removed� from� the� capacitor� (Q� C� )� is� the� load� current�
�multiplied� by� the� on� time.� Therefore,� the� output� voltage� ripple�
�(ΔV� OUT� )� is�
�V� OUT� ?� V� IN�
�the� inductor� ripple� current.�
�D� =�
�V� OUT�
�Δ� V� OUT� =�
�where:�
�Q� C�
�C� OUT�
�=�
�I� L� � t� ON�
�C� OUT�
�Use� the� duty� cycle� and� switching� frequency� (f� SW� )� to� determine�
�the� on� time.�
�C� OUT� is� the� output� capacitance.�
�I� L� is� the� average� inductor� current.�
�t� ON� =�
�D�
�f� SW�
�Using� the� duty� cycle� and� switching� frequency� (f� SW� ),� users� can�
�determine� the� on� time� with� the� following� equation:�
�V� � t� ON�
�V� IN� � t� ON�
�t� ON� =�
�V� OUT� ?� V� IN�
�I� L� � (� V� OUT� ?� V� IN� )�
�f� SW� ×� V� OUT� ×� Δ� V� OUT�
�The� inductor� ripple� current� (ΔI� L� )� in� a� steady� state� is�
�Δ� I� L� =� IN�
�L�
�Solve� for� the� inductance� value� (L).�
�L� =�
�Δ� I� L�
�Make� sure� that� the� peak� inductor� current� (that� is,� the� maximum�
�input� current� plus� half� of� the� inductor� ripple� current)� is� less�
�than� the� rated� saturation� current� of� the� inductor.� In� addition,�
�ensure� that� the� maximum� rated� rms� current� of� the� inductor� is�
�greater� than� the� maximum� dc� input� current� to� the� regulator.�
�For� duty� cycles� greater� than� 50%� that� occur� with� input� voltages�
�greater� than� half� the� output� voltage,� slope� compensation� is� required�
�to� maintain� stability� of� the� current-mode� regulator.� The� inherent�
�open-loop� stability� causes� subharmonic� instability� when� the�
�duty� ratio� is� greater� than� 50%.� To� avoid� subharmonic� instability,�
�the� slope� of� the� inductor� current� should� be� less� than� half� of� the�
�compensation� slope.�
�Inductor� manufacturers� include� Coilcraft,� Inc.,� Sumida�
�Corporation,� and� Toko.�
�Input� and� Output� Capacitors� Selection�
�The� ADD5203� requires� input� and� output� bypass� capacitors� to�
�supply� transient� currents� while� maintaining� a� constant� input�
�and� output� voltage.� Use� a� low� effective� series� resistance� (ESR)�
�10� μF� or� greater� capacitor� for� the� input� capacitor� to� prevent� noise�
�at� the� ADD5203� input.� Place� the� input� between� the� VIN� and�
�GND,� as� close� as� possible� to� the� ADD5203.� Ceramic� capacitors�
�D�
�f� SW�
�The� input� (V� IN� )� and� output� (V� OUT� )� voltages� determine� the�
�switch� duty� cycle� (D)� with� the� following� equation:�
�D� =�
�V� OUT�
�Choose� the� output� capacitor� based� on� the� following� equation:�
�C� OUT� ≥�
�Capacitor� manufacturers� include� Murata� Manufacturing� Co.,�
�Ltd.,� AVX,� Sanyo,� and� Taiyo� Yuden� Co.,� Ltd.�
�Diode� Selection�
�The� output� diode� conducts� the� inductor� current� to� the� output�
�capacitor� and� loads� while� the� switch� is� off.� For� high� efficiency,�
�minimize� the� forward� voltage� drop� of� the� diode.� Schottky� diodes�
�are� recommended.� However,� for� high� voltage,� high� temperature�
�applications,� where� the� Schottky� diode� reverse� leakage� current�
�becomes� significant� and� can� degrade� efficiency,� use� an� ultrafast�
�junction� diode.� The� output� diode� for� a� boost� regulator� must� be�
�chosen� depending� on� the� output� voltage� and� the� output� current.�
�The� diode� must� be� rated� for� a� reverse� voltage� equal� to� or� greater�
�than� the� output� voltage� used.� The� average� current� rating� must�
�be� greater� than� the� maximum� load� current� expected,� and� the� peak�
�current� rating� must� be� greater� than� the� peak� inductor� current.�
�Using� Schottky� diodes� with� lower� forward� voltage� drop� decreases�
�power� dissipation� and� increases� efficiency.� The� diode� must� be�
�rated� to� handle� the� average� output� load� current.� Many� diode�
�Rev.� 0� |� Page� 17� of� 24�
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