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参数资料
| 型号: | MAX1912EUB+T |
| 厂商: | Maxim Integrated |
| 文件页数: | 5/11页 |
| 文件大小: | 0K |
| 描述: | IC LED DRVR WHITE BCKLGT 10-MSOP |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 2,500 |
| 拓扑: | 升压(升压),切换式电容器(充电泵) |
| 输出数: | 1 |
| 内部驱动器: | 是 |
| 类型 - 主要: | 背光 |
| 类型 - 次要: | 白色 LED |
| 频率: | 625kHz ~ 875kHz |
| 电源电压: | 2.7 V ~ 5.3 V |
| 输出电压: | 5V |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 10-TFSOP,10-MSOP(0.118",3.00mm 宽) |
| 供应商设备封装: | 10-µMAX |
| 包装: | 带卷 (TR) |
| 工作温度: | -40°C ~ 85°C |
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�1.5x/2x� High-Efficiency� White� LED�
�Charge� Pumps�
�R� 1� =� R� 2� ?� OUT� -� 1� ?�
�charge-pump� topologies� because� the� charge� trans-�
�ferred� per� cycle� is� only� the� amount� required� to� supply�
�the� output� load.�
�Soft-Start�
�The� MAX1910/MAX1912� include� soft-start� circuitry� to�
�limit� inrush� current� at� turn-on.� When� starting� up� with� the�
�output� voltage� at� zero,� the� output� capacitor� charges�
�through� a� ramped� current� source,� directly� from� the�
�input� with� no� charge-pump� action� until� the� output� volt-�
�age� is� near� the� input� voltage.� If� the� output� is� shorted� to�
�ground,� the� part� remains� in� this� mode� without� damage�
�until� the� short� is� removed.�
�Once� the� output� capacitor� charges� to� the� input� voltage,�
�the� charge-pumping� action� begins.� Startup� surge� cur-�
�rent� is� minimized� by� ramping� up� charge� on� the� transfer�
�capacitors.� As� soon� as� regulation� is� reached,� soft-start�
�ends� and� the� part� operates� normally.� If� the� SET� voltage�
�reaches� regulation� within� 2048� clock� cycles� (typically�
�2.7ms),� the� part� begins� to� run� in� normal� mode.� If� the�
�SET� voltage� is� not� reached� by� 2048� cycles,� the� soft-�
�start� sequence� is� repeated.� The� devices� continue� to�
�repeat� the� soft-start� sequence� until� the� SET� voltage�
�reaches� the� regulation� point.�
�Shutdown� Mode�
�When� driven� low,� SHDN� turns� off� the� charge� pump.�
�This� reduces� the� quiescent� current� to� approximately�
�0.1μA.� The� output� is� high� impedance� in� shutdown.�
�Drive� SHDN� high� or� connect� to� IN� for� normal� operation.�
�Thermal� Shutdown�
�The� MAX1910/MAX1912� shut� down� when� their� die� tem-�
�perature� reaches� +160°C.� Normal� operation� continues�
�after� the� die� cools� by� 15°C.� This� prevents� damage� if� an�
�excessive� load� is� applied� or� the� output� is� shorted� to�
�ground.�
�Design� Procedure�
�Setting� Output� Current�
�The� MAX1910/MAX1912� have� a� SET� voltage� threshold�
�of� 0.2V,� used� for� LED� current� regulation� (Figure� 2).� The�
�current� through� the� resistor� and� LED� is:�
�I� LED� =� 0.2/R� SET�
�If� additional� matching� LEDs� with� ballast� resistors� are�
�connected� to� the� output� as� in� Figure� 2,� the� current�
�through� each� additional� LED� is� the� same� as� that� in� the�
�regulated� LED.�
�In� Figure� 2,� total� LED� current� depends� somewhat� on�
�LED� matching.� Figure� 3� shows� a� connection� that� regu-�
�lates� the� average� of� all� the� LED� currents� to� reduce� the�
�impact� of� mismatched� LEDs.� Figure� 4’s� circuit� improves�
�LED� current� matching� by� raising� the� ballast� resistance�
�while� maintaining� a� 200mV� V� SET� .� The� increased� ballast�
�resistance� tolerates� wider� LED� mismatch,� but� reduces�
�efficiency� and� raises� the� minimum� input� voltage�
�required� for� regulation.�
�Yet� another� method� of� biasing� LEDs� is� shown� in� Figure�
�5.� In� this� case,� the� current� through� the� complete� paral-�
�lel� combination� of� LEDs� is� set� by� R5.� R1–R4� are� only�
�used� to� compensate� for� LED� variations.� This� method� of�
�biasing� is� useful� for� parallel� LED� arrays� that� do� not�
�allow� connection� to� individual� LEDs.�
�Setting� Output� Voltage�
�The� MAX1910� has� a� SET� voltage� threshold� of� 0.2V.�
�Output� voltage� can� be� set� by� connecting� a� resistor� volt-�
�age-divider� as� shown� in� Figure� 6.� The� output� voltage� is�
�adjustable� from� V� IN� to� 5V.� To� set� the� output� voltage,�
�select� a� value� for� R2� that� is� less� than� 20k� Ω� ,� then� solve�
�for� R1� using� the� following� equation:�
�?� V� ?�
�?� 0� .� 2� ?�
�Capacitor� Selection�
�Use� low-ESR� ceramic� capacitors.� Recommended� values�
�are� 0.47μF� for� the� transfer� capacitors,� 2.2μF� to� 10μF� for�
�the� input� capacitor,� and� 2.2μF� to� 4.7μF� for� the� output�
�capacitor.� To� ensure� stability� over� a� wide� temperature�
�range,� ceramic� capacitors� with� an� X7R� dielectric� are� rec-�
�ommended.� Place� these� capacitors� as� close� to� the� IC� as�
�possible.� Increasing� the� value� of� the� input� and� output�
�capacitors� further� reduces� input� and� output� ripple.� With�
�a� 10μF� input� capacitor� and� a� 4.7μF� output� capacitor,�
�input� ripple� is� less� than� 5mV� peak-to-peak� and� output�
�ripple� is� less� than� 15mV� peak-to-peak� for� 60mA� of� output�
�current.� A� constant� 750kHz� switching� frequency� and�
�fixed� 50%� duty� cycle� create� input� and� output� ripple� with�
�a� predictable� frequency� spectrum.�
�Decoupling� the� input� with� a� 1� Ω� resistor� (as� shown� in�
�Figures� 2–9)� improves� stability� when� operating� from� low-�
�impedance� sources� such� as� high-current� laboratory�
�bench� power� supplies.� This� resistor� can� be� omitted�
�when� operating� from� higher� impedance� sources� such�
�as� lithium� or� alkaline� batteries.�
�For� some� designs,� such� as� an� LED� driver,� input� ripple� is�
�more� important� than� output� ripple.� Input� ripple� depends�
�on� the� source� supply’s� impedance.� Adding� a� lowpass� fil-�
�ter� to� the� input� further� reduces� ripple.� Figure� 7� shows� a� C-�
�R-C� filter� used� to� reduce� input� ripple.� With� 10μF-1� Ω� -10μF,�
�input� ripple� is� less� than� 1mV� when� driving� a� 60mA� load.�
�_______________________________________________________________________________________�
�5�
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