LM1117规格书

概述LM1117是一个低压差电压调节器系列。

其压差在1.2V输出，负载电流为800mA时为1.2V。

它与国家半导体的工业标准器件LM317有相同的管脚排列。

LM1117有可调电压的版本，通过2个外部电阻可实现1.25～13.8V输出电压范围。

另外还有5个固定电压输出（1.8V、2.5V、2.85V、3.3V和5V）的型号。

LM1117提供电流限制和热保护。

电路包含1个齐纳调节的带隙参考电压以确保输出电压的精度在±1%以内。

LM1117系列具有LLP、TO-263、SOT-223、TO-220和TO-252 D-PAK封装。

输出端需要一个至少10uF的钽电容来改善瞬态响应和稳定性。

替换型号X1117是IC网络超市自主的品牌，可以很好的替换LM1117。

X1117是一款正电压输出的低压降三端线性稳压电路，在1A输出电流下的压降为1.2V。

分为两个版本，固定电压输出版本和可调电压输出版本。

固定输出电压1.5V、1.8V、2.5V、3.3V、5.0V和可调版本的电压精度为1%；固定电压为1.2V的产品输出电压精度为2%。

内部集成过热保护和限流电路，适用于各类电子产品。

A1117是台湾亿光研发生产的高效率低压降三端线性稳压器，A1117提供电流限制和热保护，以确保芯片和功率稳定性系统。

而在芯片上保证输出电压精度在±2%。

同时也提供了固定电压输出版本和可调电压输出版本，可调版本能输出从1.25V到13.8V。

特性提供1.8V、2.5V、2.85V、3.3V、5V和可调电压的型号节省空间的SOT-223和LLP封装电流限制和热保护功能输出电流可达800mA线性调整率：0.2% (Max)负载调整率：0.4% (Max).. 温度范围－LM1117：0℃~125℃－LM1117I：-40℃~125℃应用2.85V模块可用于SCSI-2有源终端开关DC/DC转换器的主调压器高效线性调整器电池充电器电池供电装置典型应用电路图。

1A LDO稳压器电路概述是一款正电压输出的低压降三端线性稳压电路，在1A输出电流下的压降为1.2V。

分为两个版本，固定电压输出版本和可调电压输出版本。

固定输出电压1.5V、1.8V、2.5V、3.3V、5.0V和可调版本的电压精度为1％；固定电压为1.2V的产品输出电压精度为2％。

内部集成过热保护和限流电路，适用于各类电子产品。

特点*固定输出电压为1.5V、1.8V、2.5V、3.3V、5.0V和可调版本的电压精度为1％*固定电压为1.2V的输出电压精度为2％*低漏失电压：1A输出电流时仅为 1.2V*限流功能*过热切断*温度范围：-40°C~ 125°C应用*膝上型电脑，掌上电脑和笔记本电脑*电池充电器* SCSI-II主动终端*移动电话*无绳电话*电池供电系统*便携式设备* SMPS波斯特稳压器产品规格分类（温度范围：-40°C~ 125°C）X1117X1117X1117X1117X1117换页UX产品名称封装打印名称材料包装X 1117H - ADJ无铅编带X 1117H- 1.8TRX 1117H - 1.8编带X 1117H- 3.3TRX 1117H - 3.3编带SOT-223-3LX 1117H- ADJTR编带编带编带无铅无铅X 1117H- ADJTRX 1117H- 1.8TRX 1117H- 3.3TRX 1117H - ADJX 1117H - 3.3X 1117H - 1.8无卤无卤无卤内部框图3带隙限流TSD21AVOUTADJ/GNDVIN固定版本:F1和F2连接A断开可调版本: A连接， F1和 F2断开F1F2X1117换页极限参数参数符号范围单位输入工作电压引脚温度 (焊接5秒)TLead260°C工作结温范围TJ150°C储存温度TSTG-65 ~ +150°C功耗PD内部限制 (注1)mWESD能力 (最小值)ESD2000V注1：最大允许功耗是最大工作结温TJ (max)，结对空热阻θJA和环境温度Tamb的函数。

10Power Supply RecommendationsThe input supply to the LM1117must be kept at a voltage level such that its maximum rating is not exceeded. The minimum dropout voltage must also be met with extra headroom when possible to keep the LM1117in regulation.An input capacitor is recommended.For more information regarding capacitor selection,refer to External Capacitors.11Layout11.1Layout GuidelinesSome layout guidelines must be followed to ensure proper regulation of the output voltage with minimum noise. Traces carrying the load current must be wide to reduce the amount of parasitic trace inductance and the feedback loop from V OUT to ADJ must be kept as short as possible.To improve PSRR,a bypass capacitor can be placed at the ADJ pin and must be located as close as possible to the IC.In cases when V IN shorts to ground, an external diode must be placed from V OUT to V IN to divert the surge current from the output capacitor and protect the IC.The diode must be placed close to the corresponding IC pins to increase their effectiveness.11.1.1Heatsink RequirementsWhen an integrated circuit operates with an appreciable current,its junction temperature is elevated.It is important to quantify its thermal limits in order to achieve acceptable performance and reliability.This limit is determined by summing the individual parts consisting of a series of temperature rises from the semiconductor junction to the operating environment.A one-dimensional steady-state model of conduction heat transfer is demonstrated in Figure22.The heat generated at the device junction flows through the die to the die attach pad, through the lead frame to the surrounding case material,to the printed circuit board,and eventually to the ambient environment.Below is a list of variables that may affect the thermal resistance and in turn the need for a heatsink.ponent and Application VariablesRθJC(COMPONENT VARIABLES)RθJA(APPLICATION VARIABLES)Leadframe Size and Material Mounting Pad Size,Material,and LocationNo.of Conduction Pins Placement of Mounting PadDie Size PCB Size and MaterialDie Attach Material Traces Length and WidthMolding Compound Size and Material Adjacent Heat SourcesVolume of AirAmbient TemperatueShape of Mounting PadThe case temperature is measured at the point where the leads contact with the mounting pad surfaceFigure22.Cross-Sectional View of Integrated Circuit Mounted on a Printed Circuit BoardPACKAGING INFORMATIONAddendum-Page 1Addendum-Page 2Device PackageType PackageDrawingPins SPQ ReelDiameter(mm)ReelWidthW1(mm)A0(mm)B0(mm)K0(mm)P1(mm)W(mm)Pin1QuadrantLM1117LD-ADJ/NOPB WSON NGN81000178.012.4 4.3 4.3 1.38.012.0Q1 LM1117LDX-1.8/NOPB WSON NGN84500330.012.4 4.3 4.3 1.38.012.0Q1 LM1117LDX-ADJ/NOPB WSON NGN84500330.012.4 4.3 4.3 1.38.012.0Q1 LM1117MP-1.8/NOPB SOT-223DCY41000330.016.47.07.5 2.212.016.0Q3 LM1117MP-2.5/NOPB SOT-223DCY41000330.016.47.07.5 2.212.016.0Q3 LM1117MP-3.3/NOPB SOT-223DCY41000330.016.47.07.5 2.212.016.0Q3 LM1117MP-5.0/NOPB SOT-223DCY41000330.016.47.07.5 2.212.016.0Q3 LM1117MP-ADJ/NOPB SOT-223DCY41000330.016.47.07.5 2.212.016.0Q3 LM1117MPX-1.8/NOPB SOT-223DCY42000330.016.47.07.5 2.212.016.0Q3 LM1117MPX-2.5/NOPB SOT-223DCY42000330.016.47.07.5 2.212.016.0Q3 LM1117MPX-3.3SOT-223DCY42000330.016.47.07.5 2.212.016.0Q3 LM1117MPX-3.3/NOPB SOT-223DCY42000330.016.47.07.5 2.212.016.0Q3 LM1117MPX-5.0/NOPB SOT-223DCY42000330.016.47.07.5 2.212.016.0Q3 LM1117MPX-ADJ/NOPB SOT-223DCY42000330.016.47.07.5 2.212.016.0Q3 LM1117SX-3.3/NOPB DDPAK/TO-263KTT3500330.024.410.7514.85 5.016.024.0Q2LM1117SX-5.0/NOPB DDPAK/TO-263KTT3500330.024.410.7514.85 5.016.024.0Q2LM1117SX-ADJ/NOPB DDPAK/TO-263KTT3500330.024.410.7514.85 5.016.024.0Q2。

1A Low Dropout Positive Voltage RegulatorLM1117L3Features Description●Adjustable or Fixed Output The LM1117 series of positive adjustable and fixed ●Output Current of 1A regulators are designed to provide 1A with high ●Low Dropout, 1.3V max at 1A Output Current efficiency. All internal circuitry is designed to ●0.04% Line Regulation operate down to 1.3V input to output differential. ●0.2% Load Regulation On-chip trimming adjusts the reference voltage to ●100% Thermal Limit Burn-in 1%.●Fast Transient ResponseApplications●High Efficiency Linear Regulators● Post Regulators for Switching Supplies● Adjustable Power SupplyTypical Application DataFixed V oltage RegulatorAdjustable V oltage RegulatorV OUT =V REF ×(1+R2/R1)+I ADJ ×R21) C1 needed if device is far from filter capacitors2) C2 minimum value required for stabilityC2 10μF Tant.MinV OUT =3.3V C110μF Tant V IN >4.75V 1 23IN TAB GND OUT +V OUT =3.45V C2 10μF Tant.Min R2 232 Ohm,1%C1 10μF, Tant V IN >4.75V + IN TAB ADJ OUT+Package InformationSOT-223Absolute Maximum RatingsSymbol ParameterMaximum Units PD Power DissipationInternally Limited W VIN Input Voltage7 V TJ Operating Junction Temperature RangeControl SectionPower Transistor0 to 125 0 to 150 ℃ TSTG Storage Temperature-65 to 150 ℃ TLEAD Lead Temperature(Soldering, 10 sec) 300 ℃Device Selection GuideDeviceOutput Voltage LM1117-AdjAdjustable LM1117-1.51.5V LM1117-1.81.8V LM1117-2.52.5V LM1117-2.852.8 5V LM1117-3.03. 0V LM1117-3.33.3V LM1117-3.53.5V LM1117-5.05.0VElectrical Characteristics @I LOAD =0mA,T J =25℃, unless otherwise specifiedParameter DeviceTest Conditions Min Typ Max Units V IN =5V,I LOAD =10mA 1.238 1.250 1.262Reference voltage(Note 1) Adj VersionV IN =2.65V to 7V,I LOAD =10mA to 1A * 1.225 1.250 1.275V V IN =V OUT +1.5VVariator from nominal V OUT-1 +1 % V IN =V OUT +1.5V to 7VI LOAD =0mA to 1AOutput Voltage (Note 1) Al fixedversion Variator from nominal V OUT * -2 +2 %Line Regulation (Note 1) All I LOAD =10mA,(V OUT +1.5V)≦V ≦7V * 0.040.2Load Regualtion (Note 1) All V IN =V OUT +1.5V, I LOAD =10mA to 1A * 0.2 0.4%Minimum Load Current Adj Version V IN =5V,V ADJ =0V * 3 7mAGround Pin Current All fixed version V IN =V OUT +1.5V,I LOAD =10mA to 1A *713mAAdjust Pin CurrentAdj Version V IN =2.65V to 7V, I LOAD =10mA * 55 90µA Pin Function1 ADJ/GND2 OUTPUT3 INPUT 1 2 3Current Limit All (V IN -V OUT )=1.5V* 1 A Ripple Rejection (Note 2)All V IN =V OUT +1.5V,I LOAD =1A6072dB Dropout Voltage (Note 1,3)All V IN ≧2.65V, I LOAD = 1A* 1.15 1.3V Temperature CoefficientAll V IN =V OUT=1.5V, I LOAD = 10mA * 0.005 %/℃The * denotes the specifications which apply over the full temperature range.Note 1:Low duty pulse testing with Kelvin connections required.Note 2:120Hz input ripple(CADJ for ADJ=25μF)Note 3:△VOUT, △VREF=1%.Representative Circuit DiagramGND V INV OUT FOR FIXEDVOLTAGEDEVICEFORADJUSTABLEVOLTAGEDEVICE ADJ*: TypicalInches Millimeters Inches Millimeters DIM Min. Max. Min. Max. DIM Min. Max. Min. Max.A 0.1142 0.1220 2.90 3.10 G 0.0551 0.0709 1.40 1.80B 0.2638 0.2874 6.70 7.30 H 0.0098 0.0138 0.25 0.35C 0.1299 0.1457 3.30 3.70 I 0.0008 0.0039 0.02 0.10D 0.0236 0.0315 0.60 0.80 a1 *13o - *13o -E *0.0906 - *2.30 - a2 0 o 10 o 0 o 10 oF 0.2480 0.2638 6.30 6.70Notes: 1.Controlling dimension: millimeters.2.Maximum lead thickness includes lead finish thickness, and minimum lead thickness is the minimum thickness of base material.3.If there is any question with packing specification or packing method, please contact your local CYStek sales office. Material:• Lead: 42 Alloy; solder plating• Mold Compound: Epoxy resin family, flammability solid burning class: UL94V-0Important Notice:• All rights are reserved. Reproduction in whole or in part is prohibited without the prior written approval of CYStek.• CYStek reserves the right to make changes to its products without notice.• CYStek semiconductor products are not warranted to be suitable for use in Life-Support Applications, or systems.• CYStek assumes no liability for any consequence of customer product design, infringement of patents, or application assistance.321FB AC D EG H a1a2I Style: Pin 1.Adj/Gnd 2.Output3.Input3-Lead SOT-223 Plastic Surface Mounted PackageCYStek Package Code: L3左一: 西元年末碼左二: 月碼, 1=A,2=B,…8=H,9=J, …,12=M左三-四: 流水號 Date CodePart number:XX: 15 for 1.5V18 for 1.8V25 for 2.5V33 for 3.3V50 for 5.0VBlank for ADJ。

详解LDO的几个重要参数（LDO）学名低压差（线性稳压器），那么今天以LM1117的（规格）书，去看一下LDO的几个重要的（参数）。

热阻LDO算是个耗能器件，它会吃掉多余的压降。

LDO的输出（电流）几乎等于输入电流，多余的功率（LDO上的压降×负载电流）都会以热量的形式散发出去。

所以LDO的热阻是一个很重要的因素，且不同封装下的LDO有不同的热阻，封装越大热阻越小（散热越好）。

通过LDO的热阻和功率大概计算出LDO的温度。

比如下图的LM1117的SOT-223封装的热阻为61.6℃/W，那么假设输入电压5V，输出电压3.3V，输出电流为0.1A，那么P热=（5-3.3）*0.1=0.17WT温度=0.17*61.6+25=35.47℃（假设环境温度为25℃）所以这也是为什么大压差的情况下不建议使用LDO的原因（若负载电流比较小，温度算下来也在运行温度范围内，大压差也可以用LDO ）。

最小压降往往这个参数是比较容易忽略的一个参数，就是Dropout Voltage，这个用通俗的语言就是，LDO这个器件需要吃掉的最少的压降（Vin-Vout），且这个Dropout Voltage随着电流的增大而增大。

比如这个LM1117他就不适合用在普通的电池（供电）得场景，家里的小玩具3.7V的（锂电池），充满电后大概电压为4.2V，随着玩具的使用，电池电压会越来越低（电池电压降低非线性变化），降低到3V左右实际上就没电了。

那么假如锂电池电压为3.7V，那么最多LM1117只能输出电压为3.7V-1.1V=2.6V，就不满足使用了。

（对此类锂电池应用（推荐）类似ME6230的最低压差很小的LDO ）静态电流这个参数对低功耗（产品）来说很重要，静态电流的意思就是，就算负载电流为零，LDO静态下需要消耗的电流，LM1117的静态电流最大10mA，这个数值可以说相对是比较大了。

（适用于低功耗的LDO静态电流uA级别）。

LM1117/LM1117I800mA Low-Dropout Linear RegulatorGeneral DescriptionThe LM1117is a series of low dropout voltage regulators with a dropout of 1.2V at 800mA of load current.It has the same pin-out as National Semiconductor’s industry standard LM317.The LM1117is available in an adjustable version,which can set the output voltage from 1.25V to 13.8V with only two external resistors.In addition,it is also available in five fixed voltages,1.8V,2.5V,2.85V,3.3V,and 5V.The LM1117offers current limiting and thermal shutdown.Its circuit includes a zener trimmed bandgap reference to as-sure output voltage accuracy to within ±1%.The LM1117series is available in LLP ,TO-263,SOT-223,TO-220,and TO-252D-PAK packages.A minimum of 10µF tantalum capacitor is required at the output to improve the transient response and stability.Featuresn Available in 1.8V,2.5V,2.85V,3.3V,5V,and Adjustable Versionsn Space Saving SOT-223and LLP Packages n Current Limiting and Thermal Protection n Output Current 800mA n Line Regulation 0.2%(Max)n Load Regulation 0.4%(Max)n Temperature Range —LM11170˚C to 125˚C —LM1117I −40˚C to 125˚CApplicationsn 2.85V Model for SCSI-2Active Termination n Post Regulator for Switching DC/DC Converter n High Efficiency Linear Regulators n Battery ChargernBattery Powered InstrumentationTypical ApplicationActive Terminator for SCSI-2Bus10091905Fixed Output Regulator10091928June 2004LM1117/LM1117I 800mA Low-Dropout Linear Regulator©2004National Semiconductor Corporation Ordering InformationPackage TemperatureRange Part Number Packaging MarkingTransport Media NSC Drawing 3-lead SOT-2230˚C to +125˚CLM1117MPX-ADJ N03A Tape and Reel MP04ALM1117MPX-1.8N12A Tape and Reel LM1117MPX-2.5N13A Tape and Reel LM1117MPX-2.85N04A Tape and Reel LM1117MPX-3.3N05A Tape and Reel LM1117MPX-5.0N06A Tape and Reel −40˚C to +125˚CLM1117IMPX-ADJ N03B Tape and Reel LM1117IMPX-3.3N05B Tape and Reel LM1117IMPX-5.0N06B Tape and Reel3-lead TO-2200˚C to +125˚CLM1117T-ADJ LM1117T-ADJ Rails T03B LM1117T-1.8LM1117T-1.8Rails LM1117T-2.5LM1117T-2.5Rails LM1117T-2.85LM1117T-2.85Rails LM1117T-3.3LM1117T-3.3Rails LM1117T-5.0LM1117T-5.0Rails 3-lead TO-2520˚C to +125˚CLM1117DTX-ADJ LM1117DT-ADJ Tape and Reel TD03B LM1117DTX-1.8LM1117DT-1.8Tape and Reel LM1117DTX-2.5LM1117DT-2.5Tape and Reel LM1117DTX-2.85LM1117DT-2.85Tape and Reel LM1117DTX-3.3LM1117DT-3.3Tape and Reel LM1117DTX-5.0LM1117DT-5.0Tape and Reel −40˚C to +125˚CLM1117IDTX-ADJ LM1117IDT-ADJ Tape and Reel LM1117IDTX-3.3LM1117IDT-3.3Tape and Reel LM1117IDTX-5.0LM1117IDT-5.0Tape and Reel 8-lead LLP0˚C to +125˚CLM1117LDX-ADJ 1117ADJ Tape and Reel LDC08A LM1117LDX-1.81117-18Tape and Reel LM1117LDX-2.51117-25Tape and Reel LM1117LDX-2.851117-28Tape and Reel LM1117LDX-3.31117-33Tape and Reel LM1117LDX-5.01117-50Tape and Reel −40˚C to 125˚CLM1117ILDX-ADJ 1117IAD Tape and Reel LM1117ILDX-3.31117I33Tape and Reel LM1117ILDX-5.01117I50Tape and Reel TO-2630˚C to +125˚CLM1117SX-ADJ LM1117SADJ Tape and Reel TS3B LM1117SX-2.85LM1117S2.85Tape and Reel LM1117SX-3.3LM1117S3.3Tape and Reel LM1117SX-5.0LM1117S5.0Tape and ReelL M 1117/L M 1117I 2Block Diagram10091901Connection DiagramsSOT-22310091904Top ViewTO-22010091902Top ViewTO-25210091938Top ViewTO-26310091944Top View10091945Side ViewLLP10091946When using the LLP packagePins2,3&4must be connected together andPins5,6&7must be connected togetherTop ViewLM1117/LM1117I3Absolute Maximum Ratings (Note 1)If Military/Aerospace specified devices are required,please contact the National Semiconductor Sales Office/Distributors for availability and specifications.Maximum Input Voltage (V IN to GND)20VPower Dissipation (Note 2)Internally LimitedJunction Temperature (T J )(Note 2)150˚CStorage Temperature Range -65˚C to 150˚CLead TemperatureTO-220(T)Package 260˚C,10sec SOT-223(IMP)Package 260˚C,4secESD Tolerance (Note 3)2000VOperating Ratings (Note 1)Input Voltage (V IN to GND)15VJunction Temperature Range (T J )(Note 2)LM11170˚C to 125˚C LM1117I−40˚C to 125˚CLM1117Electrical CharacteristicsTypicals and limits appearing in normal type apply for T J =25˚C.Limits appearing in Boldface type apply over the entire junc-tion temperature range for operation,0˚C to 125˚C.Symbol Parameter ConditionsMin (Note 5)Typ (Note 4)Max (Note 5)UnitsV REFReference VoltageLM1117-ADJI OUT =10mA,V IN -V OUT =2V,T J =25˚C 10mA ≤I OUT ≤800mA,1.4V ≤V IN -V OUT ≤10V1.2381.2251.2501.2501.2621.270V VV OUTOutput VoltageLM1117-1.8I OUT =10mA,V IN =3.8V,T J =25˚C 0≤I OUT ≤800mA,3.2V ≤V IN ≤10V 1.7821.746 1.8001.800 1.8181.854V V LM1117-2.5I OUT =10mA,V IN =4.5V,T J =25˚C 0≤I OUT ≤800mA,3.9V ≤V IN ≤10V 2.4752.450 2.5002.500 2.5252.550V V LM1117-2.85I OUT =10mA,V IN =4.85V,T J =25˚C 0≤I OUT ≤800mA,4.25V ≤V IN ≤10V 0≤I OUT ≤500mA,V IN =4.10V 2.8202.7902.790 2.8502.8502.850 2.8802.9102.910V V V LM1117-3.3I OUT =10mA,V IN =5V T J =25˚C 0≤I OUT ≤800mA,4.75V ≤V IN ≤10V 3.2673.235 3.3003.300 3.3333.365V V LM1117-5.0I OUT =10mA,V IN =7V,T J =25˚C 0≤I OUT ≤800mA,6.5V ≤V IN ≤12V4.9504.9005.0005.000 5.0505.100V V ∆V OUTLine Regulation (Note 6)LM1117-ADJI OUT =10mA,1.5V ≤V IN -V OUT ≤13.75V 0.0350.2%LM1117-1.8I OUT =0mA,3.2V ≤V IN ≤10V 16mV LM1117-2.5I OUT =0mA,3.9V ≤V IN ≤10V 16mVLM1117-2.85I OUT =0mA,4.25V ≤V IN ≤10V 16mV LM1117-3.3I OUT =0mA,4.75V ≤V IN ≤15V 16mV LM1117-5.0I OUT =0mA,6.5V ≤V IN ≤15V110mVL M 1117/L M 1117I 4LM1117Electrical Characteristics(Continued)Typicals and limits appearing in normal type apply for T J=25˚C.Limits appearing in Boldface type apply over the entire junc-tion temperature range for operation,0˚C to125˚C.Symbol Parameter ConditionsMin(Note5)Typ(Note4)Max(Note5)Units∆V OUT Load Regulation(Note6)LM1117-ADJV IN-V OUT=3V,10≤I OUT≤800mA0.20.4% LM1117-1.8V IN=3.2V,0≤I OUT≤800mA110mVLM1117-2.5V IN=3.9V,0≤I OUT≤800mA110mVLM1117-2.85V IN=4.25V,0≤I OUT≤800mA110mV LM1117-3.3V IN=4.75V,0≤I OUT≤800mA110mV LM1117-5.0V IN=6.5V,0≤I OUT≤800mA115mVV IN-V OUT Dropout Voltage(Note7)I OUT=100mA 1.10 1.20V I OUT=500mA 1.15 1.25V I OUT=800mA 1.20 1.30VI LIMIT Current Limit V IN-V OUT=5V,T J=25˚C80012001500mAMinimum Load Current(Note8)LM1117-ADJV IN=15V 1.75mAQuiescent Current LM1117-1.8V IN≤15V510mALM1117-2.5V IN≤15V510mALM1117-2.85V IN≤10V510mALM1117-3.3V IN≤15V510mALM1117-5.0V IN≤15V510mA Thermal Regulation T A=25˚C,30ms Pulse0.010.1%/W Ripple Regulation f RIPPLE=120Hz,V IN-V OUT=3V V RIPPLE=1V PP6075dB Adjust Pin Current60120µAAdjust Pin Current Change 10≤I OUT≤800mA,1.4V≤V IN-V OUT≤10V0.25µATemperature Stability0.5% Long Term Stability T A=125˚C,1000Hrs0.3% RMS Output Noise(%of V OUT),10Hz≤f≤10kHz0.003%Thermal Resistance Junction-to-Case 3-Lead SOT-22315.0˚C/W 3-Lead TO-220 3.0˚C/W 3-Lead TO-25210˚C/WThermal Resistance Junction-to-Ambient (No air flow)3-Lead SOT-223(No heat sink)136˚C/W3-Lead TO-220(No heat sink)79˚C/W3-Lead TO-252(Note9)(No heat sink)92˚C/W3-Lead TO-26355˚C/W8-Lead LLP(Note10)40˚C/WLM1117/LM1117I5LM1117I Electrical CharacteristicsTypicals and limits appearing in normal type apply for T J =25˚C.Limits appearing in Boldface type apply over the entire junc-tion temperature range for operation,−40˚C to 125˚C.Symbol Parameter ConditionsMin (Note 5)Typ (Note 4)Max (Note 5)UnitsV REFReference VoltageLM1117I-ADJI OUT =10mA,V IN -V OUT =2V,T J =25˚C 10mA ≤I OUT ≤800mA,1.4V ≤V IN -V OUT ≤10V1.2381.2001.2501.2501.2621.290V VV OUTOutput VoltageLM1117I-3.3I OUT =10mA,V IN =5V,T J =25˚C 0≤I OUT ≤800mA,4.75V ≤V IN ≤10V 3.2673.168 3.3003.300 3.3333.432V V LM1117I-5.0I OUT =10mA,V IN =7V,T J =25˚C 0≤I OUT ≤800mA,6.5V ≤V IN ≤12V4.9504.8005.0005.000 5.0505.200V V ∆V OUTLine Regulation (Note 6)LM1117I-ADJI OUT =10mA,1.5V ≤V IN -V OUT ≤13.75V 0.0350.3%LM1117I-3.3I OUT =0mA,4.75V ≤V IN ≤15V 110mV LM1117I-5.0I OUT =0mA,6.5V ≤V IN ≤15V115mV ∆V OUTLoad Regulation (Note 6)LM1117I-ADJV IN -V OUT =3V,10≤I OUT ≤800mA 0.20.5%LM1117I-3.3V IN =4.75V,0≤I OUT ≤800mA 115mV LM1117I-5.0V IN =6.5V,0≤I OUT ≤800mA120mV V IN -V OUTDropout Voltage (Note 7)I OUT =100mA 1.10 1.30V I OUT =500mA 1.15 1.35V I OUT =800mA1.20 1.40V I LIMITCurrent Limit V IN -V OUT =5V,T J =25˚C 80012001500mA Minimum Load Current (Note 8)LM1117I-ADJ V IN =15V 1.75mA Quiescent CurrentLM1117I-3.3V IN ≤15V 515mA LM1117I-5.0V IN ≤15V515mA Thermal Regulation T A =25˚C,30ms Pulse0.010.1%/W Ripple Regulation f RIPPLE =120Hz,V IN -V OUT =3V V RIPPLE =1V PP6075dBAdjust Pin Current 60120µA Adjust Pin Current Change10≤I OUT ≤800mA,1.4V ≤V IN -V OUT ≤10V 0.210µA Temperature Stability 0.5%Long Term Stability T A =125˚C,1000Hrs0.3%RMS Output Noise (%of V OUT ),10Hz ≤f ≤10kHz 0.003%Thermal Resistance Junction-to-Case 3-Lead SOT-22315.0˚C/W 3-Lead TO-25210˚C/W Thermal Resistance Junction-to-Ambient No air flow)3-Lead SOT-223(No heat sink)136˚C/W 3-Lead TO-252(No heat sink)(Note 9)92˚C/W 8-Lead LLP(Note 10)40˚C/WNote 1:Absolute Maximum Ratings indicate limits beyond which damage to the device may occur.Operating Ratings indicate conditions for which the device is intended to be functional,but specific performance is not guaranteed.For guaranteed specifications and the test conditions,see the Electrical Characteristics.L M 1117/L M 1117I 6Note 2:The maximum power dissipation is a function of T J(max),θJA ,and T A .The maximum allowable power dissipation at any ambient temperature is P D =(T J(max)–T A )/θJA .All numbers apply for packages soldered directly into a PC board.Note 3:For testing purposes,ESD was applied using human body model,1.5k Ωin series with 100pF.Note 4:Typical Values represent the most likely parametric norm.Note 5:All limits are guaranteed by testing or statistical analysis.Note 6:Load and line regulation are measured at constant junction room temperature.Note 7:The dropout voltage is the input/output differential at which the circuit ceases to regulate against further reduction in input voltage.It is measured when the output voltage has dropped 100mV from the nominal value obtained at V IN =V OUT +1.5V.Note 8:The minimum output current required to maintain regulation.Note 9:Minimum pad size of 0.038in 2Note 10:Thermal Performance for the LLP was obtained using JESD51-7board with six vias and an ambient temperature of 22˚C.For information about improved thermal performance and power dissipation for the LLP ,refer to Application Note AN-1187.Typical Performance CharacteristicsDropout Voltage (V IN -VOUT )Short-Circuit Current1009192210091923Load Regulation LM1117-ADJ Ripple Rejection1009194310091906LM1117/LM1117I7Typical Performance Characteristics(Continued)LM1117-ADJ Ripple Rejection vs.CurrentTemperature Stability1009190710091925Adjust Pin Current LM1117-2.85Load Transient Response1009192610091908LM1117-5.0Load Transient Response LM1117-2.85Line Transient Response1009190910091910L M 1117/L M 1117I 8Typical Performance Characteristics(Continued) LM1117-5.0Line Transient Response10091911Application Note1.0External Capacitors/Stability1.1Input Bypass CapacitorAn input capacitor is recommended.A10µF tantalum on theinput is a suitable input bypassing for almost all applications.1.2Adjust Terminal Bypass CapacitorThe adjust terminal can be bypassed to ground with a by-pass capacitor(C ADJ)to improve ripple rejection.This by-pass capacitor prevents ripple from being amplified as theoutput voltage is increased.At any ripple frequency,theimpedance of the C ADJ should be less than R1to prevent theripple from being amplified:1/(2π*f RIPPLE*C ADJ)<R1The R1is the resistor between the output and the adjust pin.Its value is normally in the range of100-200Ω.For example,with R1=124Ωand f RIPPLE=120Hz,the C ADJ should be>11µF.1.3Output CapacitorThe output capacitor is critical in maintaining regulator sta-bility,and must meet the required conditions for both mini-mum amount of capacitance and ESR(Equivalent Series Resistance).The minimum output capacitance required by the LM1117is10µF,if a tantalum capacitor is used.Any increase of the output capacitance will merely improve the loop stability and transient response.The ESR of the output capacitor should range between0.3Ω-22Ω.In the case of the adjustable regulator,when the C ADJ is used,a larger output capacitance(22µf tantalum)is required.2.0Output VoltageThe LM1117adjustable version develops a1.25V reference voltage,V REF,between the output and the adjust terminal. As shown in Figure1,this voltage is applied across resistor R1to generate a constant current I1.The current I ADJ from the adjust terminal could introduce error to the output.But since it is very small(60µA)compared with the I1and very constant with line and load changes,the error can be ig-nored.The constant current I1then flows through the output set resistor R2and sets the output voltage to the desired level.For fixed voltage devices,R1and R2are integrated inside the devices.3.0Load RegulationThe LM1117regulates the voltage that appears between itsoutput and ground pins,or between its output and adjustpins.In some cases,line resistances can introduce errors tothe voltage across the load.To obtain the best load regula-tion,a few precautions are needed.Figure2,shows a typical application using a fixed outputregulator.The Rt1and Rt2are the line resistances.It isobvious that the V LOAD is less than the V OUT by the sum ofthe voltage drops along the line resistances.In this case,theload regulation seen at the R LOAD would be degraded fromthe data sheet specification.To improve this,the load shouldbe tied directly to the output terminal on the positive side anddirectly tied to the ground terminal on the negative side.10091917FIGURE1.Basic Adjustable RegulatorLM1117/LM1117I9Application Note(Continued)When the adjustable regulator is used (Figure 3),the best performance is obtained with the positive side of the resistor R1tied directly to the output terminal of the regulator rather than near the load.This eliminates line drops from appearing effectively in series with the reference and degrading regu-lation.For example,a 5V regulator with 0.05Ωresistance between the regulator and load will have a load regulation due to line resistance of 0.05Ωx I L .If R1(=125Ω)is con-nected near the load,the effective line resistance will be 0.05Ω(1+R2/R1)or in this case,it is 4times worse.In addition,the ground side of the resistor R2can be returned near the ground of the load to provide remote ground sens-ing and improve load regulation.4.0Protection DiodesUnder normal operation,the LM1117regulators do not need any protection diode.With the adjustable device,the internal resistance between the adjust and output terminals limits the current.No diode is needed to divert the current around the regulator even with capacitor on the adjust terminal.The adjust pin can take a transient signal of ±25V with respect to the output voltage without damaging the device.When a output capacitor is connected to a regulator and the input is shorted to ground,the output capacitor will discharge into the output of the regulator.The discharge current de-pends on the value of the capacitor,the output voltage of the regulator,and rate of decrease of V IN .In the LM1117regu-lators,the internal diode between the output and input pins can withstand microsecond surge currents of 10A to 20A.With an extremely large output capacitor (≥1000µF),and with input instantaneously shorted to ground,the regulator could be damaged.In this case,an external diode is recommended between the output and input pins to protect the regulator,as shown in Figure 4.5.0Heatsink RequirementsWhen an integrated circuit operates with an appreciable current,its junction temperature is elevated.It is important to quantify its thermal limits in order to achieve acceptable performance and reliability.This limit is determined by sum-ming the individual parts consisting of a series of tempera-ture rises from the semiconductor junction to the operating environment.A one-dimensional steady-state model of con-duction heat transfer is demonstrated in Figure 5.The heat generated at the device junction flows through the die to the die attach pad,through the lead frame to the surrounding case material,to the printed circuit board,and eventually to the ambient environment.Below is a list of variables that may affect the thermal resistance and in turn the need for a heatsink.R θJC (ComponentVariables)R θCA (ApplicationVariables)Leadframe Size &Material Mounting Pad Size,Material,&Location No.of Conduction Pins Placement of Mounting PadDie SizePCB Size &Material Die Attach Material Traces Length &Width Molding Compound Size and MaterialAdjacent Heat Sources Volume of Air Ambient Temperatue Shape of Mounting Pad10091918FIGURE 2.Typical Application using Fixed OutputRegulator 10091919FIGURE 3.Best Load Regulation using AdjustableOutput Regulator 10091915FIGURE 4.Regulator with Protection Diode L M 1117/L M 1117I10Application Note(Continued)The LM1117regulators have internal thermal shutdown to protect the device from over-heating.Under all possible operating conditions,the junction temperature of the LM1117must be within the range of 0˚C to 125˚C.A heatsink may be required depending on the maximum power dissipation and maximum ambient temperature of the application.To deter-mine if a heatsink is needed,the power dissipated by the regulator,P D ,must be calculated:I IN =I L +I GP D =(V IN -V OUT )I L +V IN I GFigure 6shows the voltages and currents which are present in the circuit.The next parameter which must be calculated is the maxi-mum allowable temperature rise,T R (max):T R (max)=T J (max)-T A (max)where T J (max)is the maximum allowable junction tempera-ture (125˚C),and T A (max)is the maximum ambient tem-perature which will be encountered in the application.Using the calculated values for T R (max)and P D ,the maxi-mum allowable value for the junction-to-ambient thermal resistance (θJA )can be calculated:θJA =T R (max)/P DIf the maximum allowable value for θJA is found to be ≥136˚C/W for SOT-223package or ≥79˚C/W for TO-220package or ≥92˚C/W for TO-252package,no heatsink is needed since the package alone will dissipate enough heat to satisfy these requirements.If the calculated value for θJA falls below these limits,a heatsink is required.As a design aid,Table 1shows the value of the θJA of SOT-223and TO-252for different heatsink area.The copper patterns that we used to measure these θJA s are shown at the end of the Application Notes Section.Figure 7and Figure 8reflects the same test results as what are in the Table 1Figure 9and Figure 10shows the maximum allowable power dissipation vs.ambient temperature for the SOT-223and TO-252device.Figures Figure 11and Figure 12shows the maximum allowable power dissipation vs.copper area (in 2)for the SOT-223and TO-252devices.Please see AN1028for power enhancement techniques to be used with SOT-223and TO-252packages.*Application Note AN-1187discusses improved thermal per-formance and power dissipation for the LLP .TABLE 1.θJA Different Heatsink AreaLayout Copper AreaThermal ResistanceTop Side (in 2)*Bottom Side (in 2)(θJA ,˚C/W)SOT-223(θJA ,˚C/W)TO-25210.0123013610320.0660*******.30846040.530755450.76069526106647700.211584800.49870900.689631000.8825711017957120.0660.06612589130.1750.175937210091937FIGURE 5.Cross-sectional view of Integrated Circuit Mounted on a printed circuit board.Note that the case temperature is measured at the point where the leadscontact with the mounting pad surface 10091916FIGURE 6.Power Dissipation DiagramLM1117/LM1117IApplication Note(Continued)TABLE 1.θJA Different Heatsink Area (Continued)Layout Copper AreaThermal Resistance140.2840.2848361150.3920.3927555160.50.57053*Tab of device attached to topside copperL M 1117/L M 1117IApplication Note(Continued)10091913 FIGURE7.θJA vs.1oz Copper Area for SOT-22310091934 FIGURE8.θJA vs.2oz Copper Area for TO-25210091912 FIGURE9.Maximum Allowable Power Dissipation vs.Ambient Temperature for SOT-22310091936FIGURE10.Maximum Allowable Power Dissipation vs.Ambient Temperature for TO-25210091914FIGURE11.Maximum Allowable Power Dissipation vs.1oz Copper Area for SOT-22310091935FIGURE12.Maximum Allowable Power Dissipation vs.2oz Copper Area for TO-252LM1117/LM1117IApplication Note(Continued)10091941FIGURE 13.Top View of the Thermal Test Pattern in Actual ScaleL M 1117/L M 1117IApplication Note(Continued)10091942FIGURE14.Bottom View of the Thermal Test Pattern in Actual Scale LM1117/LM1117ITypical Application Circuits10091930Adjusting Output of Fixed Regulators10091931Regulator with Reference100919291.25V to 10V Adjustable Regulator with ImprovedRipple Rejection100919275V Logic Regulator with Electronic Shutdown*L M 1117/L M 1117ITypical Application Circuits(Continued)10091932Battery Backed-Up Regulated Supply10091933Low Dropout Negative Supply LM1117/LM1117IPhysical Dimensionsinches (millimeters)unless otherwise noted3-Lead SOT-223NS Package Number MP04A3-Lead TO-220NS Package Number T03BL M 1117/L M 1117IPhysical Dimensions inches(millimeters)unless otherwise noted(Continued)3-Lead TO-263NS Package Number TS3B LM1117/LM1117IPhysical Dimensionsinches (millimeters)unless otherwise noted (Continued)3-Lead TO-252NS Package Number TD03B8-Lead LLPNS Package Number LDC08AL M 1117/L M 1117INotesLIFE SUPPORT POLICYNATIONAL’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT AND GENERAL COUNSEL OF NATIONAL SEMICONDUCTOR CORPORATION.As used herein:1.Life support devices or systems are devices orsystems which,(a)are intended for surgical implant into the body,or(b)support or sustain life,and whose failure to perform when properly used in accordance with instructions for use provided in the labeling,can be reasonably expected to result in a significant injury to the user.2.A critical component is any component of a lifesupport device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system,or to affect its safety or effectiveness.BANNED SUBSTANCE COMPLIANCENational Semiconductor certifies that the products and packing materials meet the provisions of the Customer Products Stewardship Specification(CSP-9-111C2)and the Banned Substances and Materials of Interest Specification (CSP-9-111S2)and contain no‘‘Banned Substances’’as defined in CSP-9-111S2.National Semiconductor Americas CustomerSupport CenterEmail:new.feedback@ Tel:1-800-272-9959National SemiconductorEurope Customer Support CenterFax:+49(0)180-5308586Email:europe.support@Deutsch Tel:+49(0)6995086208English Tel:+44(0)8702402171Français Tel:+33(0)141918790National SemiconductorAsia Pacific CustomerSupport CenterEmail:ap.support@National SemiconductorJapan Customer Support CenterFax:81-3-5639-7507Email:jpn.feedback@Tel:81-3-5639-7560 LM1117/LM1117I 800mA Low-Dropout Linear RegulatorNational does not assume any responsibility for use of any circuitry described,no circuit patent licenses are implied and National reserves the right at any time without notice to change said circuitry and specifications.。

9Application and ImplementationNOTEInformation in the following applications sections is not part of the TI componentspecification,and TI does not warrant its accuracy or completeness.TI’s customers areresponsible for determining suitability of components for their purposes.Customers shouldvalidate and test their design implementation to confirm system functionality.9.1Application InformationThe LM1117is a versatile and high performance linear regulator with a wide temperature range and tight line/load regulation operation.An output capacitor is required to further improve transient response and stability. For the adjustable option,the ADJ pin can also be bypassed to achieve very high ripple-rejection ratios.The LM1117is versatile in its applications,including its uses as a post regulator for DC/DC converters,battery chargers,and microprocessor supplies.9.2Typical ApplicationFigure14. 1.25-V to10-V Adjustable Regulator With Improved Ripple Rejection9.2.1Design RequirementsThe device component count is very minimal,employing two resistors as part of a voltage divider circuit and an output capacitor for load regulation.A10-μF tantalum on the input is a suitable input capacitor for almost all applications.An optional bypass capacitor across R2can also be used to improve PSRR.See Recommended Operating Conditions for more information.9.2.2Detailed Design ProcedureThe output voltage is set based on the selection of the two resistors,R1and R2,as shown in Figure14.For details on capacitor selection,refer to External Capacitors.9.2.2.1External Capacitors9.2.2.1.1Input Bypass CapacitorAn input capacitor is recommended.A10-µF tantalum on the input is a suitable input capacitor for almost all applications.LM1117SNOS412O–FEBRUARY2000–REVISED JUNE2020Typical Application(continued)9.2.2.1.2Adjust Terminal Bypass CapacitorThe adjust terminal can be bypassed to ground with a bypass capacitor(C ADJ)to improve ripple rejection.This bypass capacitor prevents ripple from being amplified as the output voltage is increased.At any ripple frequency, the impedance of the C ADJ should be less than R1to prevent the ripple from being amplified: 1/(2π×f RIPPLE×C ADJ)<R1(1) The R1is the resistor between the output and the adjust pin.Its value is normally in the range of100-200Ω.For example,with R1=124Ωand f RIPPLE=120Hz,the C ADJ should be>11µF.9.2.2.1.3Output CapacitorThe output capacitor is critical in maintaining regulator stability,and must meet the required conditions for both minimum amount of capacitance and equivalent series resistance(ESR).The minimum output capacitance required by the LM1117is10µF,if a tantalum capacitor is used.Any increase of the output capacitance will merely improve the loop stability and transient response.The ESR of the output capacitor should range between 0.3Ωto22Ω.In the case of the adjustable regulator,when the C ADJ is used,a larger output capacitance(22-µF tantalum)is required.9.2.3Application CurveAs shown in Figure15,the dropout voltage will vary with output current and temperature.Care should be taken during design to ensure the dropout voltage requirement is met across the entire operating temperature and output current range.Figure15.Dropout Voltage(V IN–V OUT)9.3System ExamplesSeveral circuits can be realized with the LM1117.The circuit diagrams in this section demonstrate multiple system examples that can be utilized in many applications.Figure 16.Fixed Output Regulator Figure 17.Adjusting Output of Fixed RegulatorsFigure 18.Regulator With Reference Figure 19.5-V Logic Regulator With Electronic Shutdown*Figure 20.Battery Backed-Up Regulated SupplyFigure 21.Low Dropout Negative SupplyFigure30.Top View of the Thermal Test Pattern in Actual ScaleFigure31.Bottom View of the Thermal Test Pattern in Actual ScaleLM1117SNOS412O–FEBRUARY2000–REVISED JUNE2020。

l m1117使用说明-CAL-FENGHAI.-(YICAI)-Company One1概述LM1117是一个低压差电压调节器系列。

其压差在输出，负载电流为800mA时为。

它与国家半导体的工业标准器件LM317有相同的管脚排列。

LM1117有可调电压的版本，通过2个外部电阻可实现～输出电压范围。

另外还有5个固定电压输出（、、、和5V）的型号。

LM1117提供电流限制和热保护。

电路包含1个齐纳调节的带隙参考电压以确保输出电压的精度在±1%以内。

LM1117系列具有LLP、TO-263、SOT-223、TO-220和TO-252 D-PAK封装。

输出端需要一个至少10uF的钽电容来改善瞬态响应和稳定性。

替换型号X1117是IC网络超市自主的品牌，可以很好的替换LM1117。

X1117是一款正电压输出的低压降三端线性稳压电路，在1A输出电流下的压降为。

分为两个版本，固定电压输出版本和可调电压输出版本。

固定输出电压、、、、和可调版本的电压精度为1%；固定电压为的产品输出电压精度为2%。

内部集成过热保护和限流电路，适用于各类电子产品。

A1117是台湾亿光研发生产的高效率低压降三端线性稳压器，A1117提供电流限制和热保护，以确保芯片和功率稳定性系统。

而在芯片上保证输出电压精度在±2%。

同时也提供了固定电压输出版本和可调电压输出版本，可调版本能输出从到。

特性提供、、、、5V和可调电压的型号节省空间的SOT-223和LLP封装电流限制和热保护功能输出电流可达800mA线性调整率：% (Max)负载调整率：% (Max)温度范围－LM1117：0℃~125℃－LM1117I：-40℃~125℃应用模块可用于SCSI-2有源终端开关DC/DC转换器的主调压器高效线性调整器电池充电器电池供电装置典型应用电路图。

概述LM1117是一个低压差三端可调稳压集成电路。

其压差在1.2V输出，负载电流为800mA时为1.2V。

它与国家半导体的工业标准器件LM317有相同的管脚排列。

LM1117有可调电压的版本，通过2个外部电阻可实现1.25～13.8V输出电压范围。

另外还有5个固定电压输出（1.8V、2.5V、2.85V、3.3V和5V）的型号。

LM1117提供电流限制和热保护。

电路包含1个齐纳调节的带隙参考电压以确保输出电压的精度在±1%以内。

LM1117系列具有LLP、TO-263、SOT-223、TO-220和TO-252 D-PAK封装。

输出端需要一个至少10uF的钽电容来改善瞬态响应和稳定性。

特性•提供1.8V、2.5V、2.85V、3.3V、5V和可调电压的型号•节省空间的SOT-223和LLP封装•电流限制和热保护功能•输出电流可达800mA•线性调整率：0.2% (Max)•负载调整率：0.4% (Max)•温度范围•－LM1117：0℃~125℃－LM1117I：-40℃~125℃替换型号•X1117是IC网络超市自主的品牌，可以很好的替换LM1117。

X1117是一款正电压输出的低压降三端线性稳压电路，在1A输出电流下的压降为1.2V。

分为两个版本，固定电压输出版本和可调电压输出版本。

固定输出电压1.5V、1.8V、2.5V、3.3V、5.0V和可调版本的电压精度为1％；固定电压为1.2V的产品输出电压精度为2％。

内部集成过热保护和限流电路，适用于各类电子产品。

A1117是台湾亿光研发生产的高效率低压降三端线性稳压器，A1117提供电流限制和热保护，以确保芯片和功率稳定性系统。

而在芯片上保证输出电压精度在±2％。

同时也提供了固定电压输出版本和可调电压输出版本，可调版本能输出从1.25V到13.8V。

应用•开关DC/DC转换器的主调压器•高效线性调整器•电池充电器•电池供电装置lm1117典型应用电路采用SOT-223和LLP封装，输出电流可达800mA，负载调整率：0.4% (Max)，线性调整率：0.2% (Max)。

概述LM1117是一个低压差三端可调稳压集成电路。

其压差在1.2V输出，负载电流为800mA时为1.2V。

它与国家半导体的工业标准器件LM317有相同的管脚排列。

LM1117有可调电压的版本，通过2个外部电阻可实现1.25～13.8V输出电压范围。

另外还有5个固定电压输出（1.8V、2.5V、2.85V、3.3V和5V）的型号。

LM1117提供电流限制和热保护。

电路包含1个齐纳调节的带隙参考电压以确保输出电压的精度在±1%以内。

LM1117系列具有LLP、TO-263、SOT-223、TO-220和TO-252 D-PAK封装。

输出端需要一个至少10uF的钽电容来改善瞬态响应和稳定性。

特性•提供1.8V、2.5V、2.85V、3.3V、5V和可调电压的型号•节省空间的SOT-223和LLP封装•电流限制和热保护功能•输出电流可达800mA•线性调整率：0.2% (Max)•负载调整率：0.4% (Max)•温度范围•－LM1117：0℃~125℃－LM1117I：-40℃~125℃替换型号•X1117是IC网络超市自主的品牌，可以很好的替换LM1117。

X1117是一款正电压输出的低压降三端线性稳压电路，在1A输出电流下的压降为1.2V。

分为两个版本，固定电压输出版本和可调电压输出版本。

固定输出电压1.5V、1.8V、2.5V、3.3V、5.0V和可调版本的电压精度为1％；固定电压为1.2V的产品输出电压精度为2％。

内部集成过热保护和限流电路，适用于各类电子产品。

A1117是台湾亿光研发生产的高效率低压降三端线性稳压器，A1117提供电流限制和热保护，以确保芯片和功率稳定性系统。

而在芯片上保证输出电压精度在±2％。

同时也提供了固定电压输出版本和可调电压输出版本，可调版本能输出从1.25V到13.8V。

应用•开关DC/DC转换器的主调压器•高效线性调整器•电池充电器•电池供电装置lm1117典型应用电路采用SOT-223和LLP封装，输出电流可达800mA，负载调整率：0.4% (Max)，线性调整率：0.2% (Max)。