361R332M6R3EK2中文资料

LM161/LM261/LM361High Speed Differential ComparatorsGeneral DescriptionThe LM161/LM261/LM361is a very high speed differential input,complementary TTL output voltage comparator with improved characteristics over the SE529/NE529for which it is a pin-for-pin replacement.The device has been optimized for greater speed performance and lower input offset volt-age.Typically delay varies only 3ns for over-drive variations of 5mV to 500mV.It may be operated from op amp supplies (±15V).Complementary outputs having maximum skew are pro-vided.Applications involve high speed analog to digital con-verters and zero-crossing detectors in disk file systems.Featuresn Independent strobesn Guaranteed high speed:20ns max n Tight delay matching on both outputs n Complementary TTL outputsn Operates from op amp supplies:±15V n Low speed variation with overdrive variation n Low input offset voltagenVersatile supply voltage rangeConnection DiagramsDual-In-Line PackageDS005708-2Top ViewOrder Number LM161J LM361M or LM361NSee NS Package Number M14A or N14AMetal Can PackageDS005708-3Order Number LM161H/883(Note 1),or LM361HSee NS Package Number H10CNote 1:Also available per SMD #5962-8757203May 1999LM161/LM261/LM361High Speed Differential Comparators©1999National Semiconductor Corporation Logic DiagramDS005708-4 *Output is low when current is drawn from strobe pin.2Absolute Maximum Ratings(Note2)If Military/Aerospace specified devices are required, please contact the National Semiconductor Sales Office/ Distributors for availability and specifications.Positive Supply Voltage,V++16V Negative Supply Voltage,V−−16V Gate Supply Voltage,V CC+7V Output Voltage+7V Differential Input Voltage±5V Input Common Mode Voltage±6V Power Dissipation600mW Storage Temperature Range−65˚C to+150˚C Operating Temperature Range T MIN T MAX LM161−55˚C to+125˚C LM261−25˚C to+85˚C LM3610˚C to+70˚C Lead Temp.(Soldering,10seconds)260˚C For Any Device Lead Below V−0.3V Operating ConditionsMin Typ Max Supply Voltage V+LM161/LM2615V15V LM3615V15V Supply Voltage V−LM161/LM261−6V−15V LM361−6V−15V Supply Voltage V CCLM161/LM261 4.5V5V 5.5V LM361 4.75V5V 5.25VESD Tolerance(Note6)1600V Soldering InformationDual-In-Line PackageSoldering(10seconds)260˚C Small Outline PackageVapor Phase(60seconds)215˚C Infrared(15seconds)220˚C See AN-450“Surface Mounting Methods and Their Effect on Product Reliability”for other methods of soldering surface mount devices.Electrical Characteristics(V+=+10V,V CC=+5V,V−=−10V,T MIN≤T A≤T MAX,unless noted)LimitsParameter Conditions LM161/LM261LM361UnitsMin Typ Max Min Typ MaxInput Offset Voltage1315mV Input Bias Current T A=25˚C510µA2030µA Input Offset Current T A=25˚C22µA35µA Voltage Gain T A=25˚C33V/mV Input Resistance T A=25˚C,f=1kHz2020kΩLogical“1”Output Voltage V CC=4.75V, 2.4 3.3 2.4 3.3VI SOURCE=−0.5mALogical“0”Output Voltage V CC=4.75V,0.40.4VI SINK=6.4mAStrobe Input“1”Current V CC=5.25V,200200µA (Output Enabled)V STROBE=2.4VStrobe Input“0”Current V CC=5.25V,−1.6−1.6mA (Output Disabled)V STROBE=0.4VStrobe Input“0”Voltage V CC=4.75V0.80.8V Strobe Input“1”Voltage V CC=4.75V22V Output Short Circuit Current V CC=5.25V,V OUT=0V−18−55−18−55mAV+=10V,V−=−10V,V CC=5.25V,−55˚C≤T A≤125˚CSupply Current I+ 4.5mAV+=10V,V−=−10V,V CC=5.25V,0˚C≤T A≤70˚CSupply Current I+5mAV+=10V,V−=−10V,V CC=5.25V,−55˚C≤T A≤125˚CSupply Current I−10mA3Electrical Characteristics(Continued)(V +=+10V,V CC =+5V,V −=−10V,T MIN ≤T A ≤T MAX ,unless noted)LimitsParameterConditionsLM161/LM261LM361UnitsMinTypMaxMinTypMax V +=10V,V −=−10V,V CC =5.25V,0˚C ≤T A ≤70˚C Supply Current I−10mAV +=10V,V −=−10V,Supply Current I CC V CC =5.25V,18mA−55˚C ≤T A ≤125˚C V +=10V,V −=−10V,Supply Current I CC V CC =5.25V,20mA0˚C ≤T A ≤70˚CTransient ResponseV IN =50mV overdrive (Note 4)Propagation Delay Time (t pd(0))T A =25˚C 14201420ns Propagation Delay Time (t pd(1))T A =25˚C 14201420ns Delay Between Output A and B T A =25˚C 2525ns Strobe Delay Time (t pd(0))T A =25˚C 88ns Strobe Delay Time (t pd(1))T A =25˚C88nsNote 2:The device may be damaged by use beyond the maximum ratings.Note 3:Typical thermal impedances are as follows:Note 4:Measurements using AC Test circuit,Fanout =1.The devices are faster at low supply voltages.Note 5:Refer to RETS161X for LM161H and LM161J military specifications.Note 6:Human body model,1.5k Ωin series with 100pF.Typical Performance CharacteristicsDS005708-17Offset VoltageDS005708-8Input Currents vs Ambient TemperatureDS005708-9Input CharacteristicsDS005708-10 4Typical Performance Characteristics(Continued)Supply Current vs Ambient TemperatureDS005708-11Supply Current vs Supply VoltageDS005708-12Propagation Delay vs Ambient TemperatureDS005708-13Delay of Output 1With Respect to Output 2vs Ambient TemperatureDS005708-14Strobe Delay vs Ambient Temperature DS005708-15Common-Mode Pulse ResponseDS005708-16Propagation Delay vs Supply VoltageDS005708-75AC Test CircuitDS005708-6V IN=±50mV FANOUT=1FANOUT=4V+=+10V R=2.4k R=680ΩV−=−10V C=15pF C=30pFV CC=5.25V6Schematic DiagramLM161DS005708-1R10,R16:85R11,R17:2057Physical Dimensions inches(millimeters)unless otherwise notedMetal Can Package(H)Order Number LM161H/883,or LM361HNS Package Number H10CCeramic Dual-In-Line Package(J)Order Number LM161JNS Package Number J14A 8Physical Dimensions inches(millimeters)unless otherwise noted(Continued)Order Number LM361MNS Package Number M14AMolded Dual-In-Line Package(N)Order Number LM361NNS Package Number N14A9NotesLIFE 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 or systems 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 life support 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.National Semiconductor Corporation AmericasTel:1-800-272-9959Fax:1-800-737-7018Email:support@National Semiconductor EuropeFax:+49(0)180-5308586Email:europe.support@Deutsch Tel:+49(0)180-5308585English Tel:+49(0)180-5327832Français Tel:+49(0)180-5329358Italiano Tel:+49(0)180-5341680National Semiconductor Asia Pacific Customer Response Group Tel:65-2544466Fax:65-2504466Email:sea.support@National Semiconductor Japan Ltd.Tel:81-3-5639-7560Fax:81-3-5639-7507L M 161/L M 261/L M 361H i g h S p e e d D i f f e r e n t i a l C o m p a r a t o r sNational 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.。

易格斯直线轴承是一种经过设计和制造的精密机械零件，主要用于工业领域的各种设备和机械中。

它的代号中包含了很多不同的部分和含义，下面将逐一解释易格斯直线轴承代号中各部分的含义。

一、通用代号1. YGSL：表示该轴承为易格斯直线轴承的通用代号；2. 22：表示轴承的系列代号，例如22代表薄壁型系列。

二、型号代号1. 22 0411：其中22表示该型号属于薄壁型系列；0411为该型号的具体代号。

三、封边、封盖和密封代号1. TSU：表示轴承无封边；2. TSS：表示轴承有封边；3. LS：表示具有外部封盖；4. ZZ：表示具有外部金属封盖；5. RS：表示具有内部密封；6. 2RS：表示具有内、外部密封。

四、内部结构代号1. M：表示轴承的内部结构为“单列滚珠”；2. S：表示轴承的内部结构为“双列滚珠”；3. E：表示轴承的内部结构为“一对单列滚珠”。

五、清洗、润滑代号1. P0：表示不清洗不润滑；2. P6：表示预润滑；3. P5：表示轴承经过清洗；4. P6：表示轴承经过磷化处理并预润滑。

六、加强式代号1. C：表示轴承采用加强式设计。

七、稳固性代号1. H：表示轴承为高可靠性稳固性设计。

以上就是易格斯直线轴承代号中各部分的含义，通过了解这些代号的含义，我们可以更好地选择和使用适合自己需求的轴承产品。

让我们来详细解释一下易格斯直线轴承代号中各部分的含义以及其在实际应用中的重要性。

一、通用代号1. YGSL：易格斯直线轴承的通用代号。

这个代号是易格斯直线轴承产品的标志，它代表着产品的品牌和质量保证。

作为制造商，易格斯对轴承产品的品质把控非常严格，保证产品的每一个细节都符合标准，以满足客户的需求。

2. 22：这个数字是轴承产品的系列代号。

在易格斯直线轴承产品中，不同的系列代号代表着轴承产品在外形、尺寸、承载能力等方面的不同特点。

了解并选择适合的系列代号对于使用者来说非常重要，因为不同的系列代号适用于不同的工作环境和工作要求。

DRAMUpdated Date : 11/06/2006DensityOrganization DescriptionRefreshSpeedPackagePart Number(Pb-free)Sample MP EDO DRAM 5V 51225ns 40L-SOJ M11B416256A-25JP Now Now EDO DRAM 5V 51235ns 44-40L-TSOPII M11B416256A-35TG Now Now EDO DRAM 3.3V 51235ns 40L-SOJ M11L416256SA-35JP Now Now EDO DRAM 3.3V 51235ns 40/44L-TSOPIIM11L416256SA-35TGNowNowSDRAMDensityOrganization DescriptionRefresh SpeedPackagePart Number(Pb-free)Sample MP SDRAM 2.5V 2K 143MHz 50L-TSOPII M12S16161A-7TG Now Now SDRAM 2.5V 2K 143MHz VFBGA M12S16161A-7BG Now Now SDRAM 3.3V 2K 143MHz 50L-TSOPII M12L16161A-7T (I)G Now Now SDRAM 3.3V 2K 200MHz 50L-TSOPII M12L16161A-5T (I)G Now Now SDRAM 3.3V 2K 143MHz VFBGA M12L16161A-7B (I)G Now Now 2M*16SDRAM 3.3V 2K 143MHz 54L-TSOPII M12L32162A-7TG Now Now 1M*32SDRAM 3.3V 2K 143MHz 90-FBGA M12L32321A-7BG Now Now SDRAM 2.5V 4K 100MHz 54L-TSOPII M12S64164A-10TG Now Now SDRAM 3.3V 4K 143MHz 54L-TSOPII M12L64164A-7T (I)G Now Now SDRAM 3.3V 4K 200MHz 54L-TSOPII M12L64164A-5TG Now Now SDRAM 2.5V 4K 143MHz 86L-TSOPII M12S64322A-7TG Now Now SDRAM 3.3V 4K 166MHz 86L-TSOPII M12L64322A-6T (I)G Now Now SDRAM 3.3V 4K 200MHz 86L-TSOPII M12L64322A-5TG Now Now SDRAM 2.5V 4K 143MHz 54L-TSOPII M12S128168A-7TG Now Now SDRAM 2.5V 4K 166MHz 54L-TSOPII M12S128168A-6TG Now Now SDRAM 3.3V 4K 143MHz 54L-TSOPII M12L128168A-7TG Now Now SDRAM 3.3V 4K 166MHz 54L-TSOPII M12L128168A-6TG Now Now SDRAM 2.5V 4K 166MHz 90-FBGA M12S128324A-6BG Now Now SDRAM 2.5V 4K 143MHz 86L-TSOPII M12S128324A-7TG Now Now SDRAM 2.5V 4K 166MHz 86L-TSOPII M12S128324A-6TG Now Now SDRAM 3.3V 4K 143MHz 90-FBGA M12L128324A-7B (I)G Now Now SDRAM 3.3V 4K 166MHz 90-FBGA M12L128324A-6B (I)G Now Now SDRAM 3.3V 4K 143MHz 86L-TSOPII M12L128324A-7T (I)G Now Now SDRAM 3.3V4K166MHz86L-TSOPIIM12L128324A-6T (I)GNowNowDDR SDRAM (Dobule-Date-Rate SDRAM)Density Organization DescriptionRefresh SpeedPackagePart Number(Pb-free)Sample MP DDR-SDRAM 2.5V 4K 166MHz 100-LQFP M13S32321A-6L Now Now DDR-SDRAM 2.5V 4K 200MHz 100-LQFP M13S32321A-5L Now Now DDR-SDRAM 2.5V 4K 166MHz 66L-TSOPII M13S64164A-6TG Q2'07Q3'07DDR-SDRAM 2.5V 4K 200MHz 66L-TSOPII M13S64164A-5TG Q2'07Q3'07DDR-SDRAM 2.5V 4K 166MHz 66L-TSOPII M13S128168A-6TG Now Now DDR-SDRAM 2.5V 4K 200MHz 66L-TSOPII M13S128168A-5TG Now Now DDR-SDRAM 2.5V 4K 166MHz 144-FBGA (12x12mm)M13S128324A-6BG Now Now DDR-SDRAM 2.5V 4K 200MHz 144-FBGA (12x12mm)M13S128324A-5BG Now Now 256Mb16Mx16DDR-SDRAM 2.5V 4K200MHz66L-TSOPIIM13S2561616A-5TGNowNow*Identifier of Pb-free as G or P is shown on outer carton.**Industrial spec : (I) Operating temperature -40ºC ~+85 ºC.2M*3264Mb4Mb*1632Mb4Mb 256Kb*161Mb*1616Mb 128Mb8M*164Mx324M*32128Mb8M*1632Mb 64Mb1M*324M*16Mobile SDRAMDensityOrganizationDescriptionRefresh Speed Package & MCPPart Number(Pb-free)Sample MP Mobile SDRAM 2.5V4K 100MHz 50L-TSOPII M52S16161A-10T (I)G Now Now Mobile SDRAM 2.5V 4K 125MHz 50L-TSOPII M52S16161A-8T (I)G Now Now Mobile SDRAM 1.8V4K 100MHz50L-TSOPIIM52D16161A-10T (I)G Now Now Mobile SDRAM 2.5V 4K 100MHz 54L-TSOPII M52S32162A-10T (I)G Now Now Mobile SDRAM 2.5V 4K 100MHz 54-FBGA M52S32162A-10B (I)G Now Now Mobile SDRAM 2.5V 4K 133MHz 54L-TSOPII M52S32162A-7.5T (I)G Now Now Mobile SDRAM 2.5V 4K 133MHz 54-FBGA M52S32162A-7.5B (I)G Now Now Mobile SDRAM 1.8V 4K 100MHz 54L-TSOPII M52D32162A-10T (I)G Now Now Mobile SDRAM 1.8V 4K 100MHz 54-FBGA M52D32162A-10B (I)G Now Now Mobile SDRAM 1.8V 4K 100MHz 54L-TSOPII M52D32162A-7.5T (I)G Now Now Mobile SDRAM 1.8V 4K 133MHz 54-FBGA M52D32162A-7.5B (I)G Now Now Mobile SDRAM 2.5V 4K 100MHz 90-FBGA M52S32321A-10B (I)G Now Now Mobile SDRAM 2.5V 4K 133MHz 90-FBGA M52S32321A-7.5B (I)G Now Now Mobile SDRAM 1.8V 4K 100MHz 90-FBGA M52D32321A-10B (I)G Now Now Mobile SDRAM 1.8V 4K 133MHz 90-FBGA M52D32321A-7.5B (I)G Now Now Mobile SDRAM 2.5V 4K 100MHz 54L-TSOPII M52S64164A-10T (I)G Q2 '07Q3 '07Mobile SDRAM 2.5V 4K 100MHz 54-FBGA M52S64164A-10B (I)G Q2 '07Q3 '07Mobile SDRAM 2.5V 4K 133MHz 54L-TSOPII M52S64164A-7.5T (I)G Q2 '07Q3 '07Mobile SDRAM 2.5V 4K 133MHz 54-FBGA M52S64164A-7.5B (I)G Q2 '07Q3 '07Mobile SDRAM 1.8V 4K 100MHz 54L-TSOPII M52D64164A-10T (I)G Q2 '07Q3 '07Mobile SDRAM 1.8V 4K 100MHz 54-FBGA M52D64164A-10B (I)G Q2 '07Q3 '07Mobile SDRAM 1.8V 4K 100MHz 54L-TSOPII M52D64164A-7.5T (I)G Q2 '07Q3 '07Mobile SDRAM 1.8V 4K 133MHz 54-FBGA M52D64164A-7.5B (I)G Q2 '07Q3 '07Mobile SDRAM 2.5V 4K 100MHz 86L-TSOPII M52S64322A-10T (I)G Q2 '07Q3 '07Mobile SDRAM 2.5V 4K 100MHz 90-FBGA M52S64322A-10B (I)G Q2 '07Q3 '07Mobile SDRAM 2.5V 4K 133MHz 86L-TSOPII M52S64322A-7.5T (I)G Q2 '07Q3 '07Mobile SDRAM 2.5V 4K 133MHz 90-FBGA M52S64322A-7.5B (I)G Q2 '07Q3 '07Mobile SDRAM 1.8V 4K 100MHz 86L-TSOPII M52D64322A-10T (I)G Q2 '07Q3 '07Mobile SDRAM 1.8V 4K 100MHz 90-FBGA M52D64322A-10B (I)G Q2 '07Q3 '07Mobile SDRAM 1.8V 4K 100MHz 86L-TSOPII M52D64322A-7.5T (I)G Q2 '07Q3 '07Mobile SDRAM 1.8V4K133MHz 90-FBGAM52D64322A-7.5B (I)GQ2 '07Q3 '07*Identifier of Pb-free as G or P is shown on outer carton.**Industrial spec : (I) Operating temperature -40ºC ~+85 ºC.64Mb4Mx162Mx32(1)All Mobile functions are included : PASR,TCSR,DS,Deep power down mode.(2)Max. Icc6 : Self-refresh current with full bank in 70 ºC .1Mx16Max. Icc6= 75uA (1.8V)16Mb32Mb2Mx161Mx32。

常用纽扣电池型号对照表CR2032是指一种20mm直径，3.2mm高。

IEC标准中，R代表圆柱形，L代表碱性，数字代表电池的大小，数字后面的P代表高功率，这里有一个特殊规定，在表示五号普通锌锰电池时，要标识为R6P，而不是R06或者R6。

CR系列也是一种典型的干电池型号，常见的有CR2025、CR2032等。

其中C是以锂金属为负极，以二氧化锰为正极的化学电池体系，R表示电池的形状为圆柱形，如果是方形则F替代；20表示电池的直径是20mm，32代表电池的高度为3.2mm。

除了单支干电池型号命名外，还有一些组合干电池型号的标识表示如下：1、9V电池：6F22是由6个扁平形电池叠层的碳性电池；6LR61则是由6个扁平形电池叠层的碱性电池；2、AG系列：是直径很小的CR电池，分为AG1到AG13计13种，属于碱性电池；3、23A和27A：是由八个同一规格的AG电池叠层的，也称12V扣式电池，27A大于23A。

这些组合的干电池型号往往是基于特殊电压或者容量的考虑，也只适用于一些特定领域。

由于这些干电池型号有一定的市场容量，知道它们属于干电池序列这一点，就便于把握其价格与特性。

另外还有非锌锰和锂锰系的干电池，如镁锰电池等，因为比较少见，所以对这种干电池及干电池型号介绍不多。

普通充电电池充电时间计算一、充电常识在这里，首先要说明的是，充电是使用充电电池的重要步骤。

适当合理的充电对延长电池寿命很有好处，而野蛮胡乱充电将会对电池寿命有很大影响。

上一篇曾说过，目前的锂电池基本都是根据各个产品单独封装，互不通用的，因此各个产品也提供各自的充电设备，互不通用，在使用时只要遵循各自的说明书使用即可。

所以本篇对电池充电的介绍主要是指镍镉电池和镍氢电池。

对镍隔电池和镍氢电池充电有两种方式，就是我们大家所熟知的“快充”和“慢充”。

快充和慢充是充电的一个重要概念，只有了解了快充和慢充才能正确掌握充电。

首先，快充和慢充是个相对的概念。

________________General DescriptionThe MAX3222/MAX3232/MAX3237/MAX3241 trans-ceivers have a proprietary low-dropout transmitter out-put stage enabling true RS-232 performance from a 3.0V to 5.5V supply with a dual charge pump. The devices require only four small 0.1µF external charge-pump capacitors. The MAX3222, MAX3232, and MAX3241 are guaranteed to run at data rates of 120kbps while maintaining RS-232 output levels. The MAX3237 is guaranteed to run at data rates of 250kbps in the normal operating mode and 1Mbps in the MegaBaud™ operating mode, while maintaining RS-232output levels.The MAX3222/MAX3232 have 2 receivers and 2 drivers. The MAX3222 features a 1µA shutdown mode that reduces power consumption and extends battery life in portable systems. Its receivers remain active in shutdown mode, allowing external devices such as modems to be monitored using only 1µA supply cur-rent. The MAX3222 and MAX3232 are pin, package,and functionally compatible with the industry-standard MAX242 and MAX232, respectively.The MAX3241 is a complete serial port (3 drivers/5 receivers) designed for notebook and subnotebook computers. The MAX3237 (5 drivers/3 receivers) is ideal for fast modem applications. Both these devices feature a shutdown mode in which all receivers can remain active while using only 1µA supply current. Receivers R1(MAX3237/MAX3241) and R2 (MAX3241) have extra out-puts in addition to their standard outputs. These extra outputs are always active, allowing external devices such as a modem to be monitored without forward bias-ing the protection diodes in circuitry that may have V CC completely removed.The MAX3222, MAX3237, and MAX3241 are available in space-saving TSSOP and SSOP packages.________________________ApplicationsNotebook, Subnotebook, and Palmtop Computers High-Speed Modems Battery-Powered Equipment Hand-Held Equipment Peripherals Printers__Next Generation Device Features♦For Smaller Packaging:MAX3228E/MAX3229E: +2.5V to +5.5V RS-232Transceivers in UCSP™♦For Integrated ESD Protection:MAX3222E/MAX3232E/MAX3237E/MAX3241E*/MAX3246E: ±15kV ESD-Protected, Down to 10nA,3.0V to 5.5V, Up to 1Mbps, True RS-232Transceivers♦For Low-Voltage or Data Cable Applications:MAX3380E/MAX3381E: +2.35V to +5.5V, 1µA, 2 Tx/2 Rx RS-232 Transceivers with ±15kV ESD-Protected I/O and Logic PinsMAX3222/MAX3232/MAX3237/MAX3241*3.0V to 5.5V , Low-Power , up to 1Mbps, T rue RS-232Transceivers Using Four 0.1µF External Capacitors________________________________________________________________Maxim Integrated Products119-0273; Rev 7; 1/07*Covered by U.S. Patent numbers 4,636,930; 4,679,134; 4,777,577; 4,797,899; 4,809,152; 4,897,774; 4,999,761; and other patents pending.Typical Operating Circuits appear at end of data sheet.Ordering Information continued at end of data sheet.For pricing, delivery, and ordering information,please contact Maxim/Dallas Direct!at 1-888-629-4642, or visit Maxim’s website at .+Denotes lead-free package.M A X 3222/M A X 3232/M A X 3237/M A X 3241Transceivers Using Four 0.1µF External Capacitors2_______________________________________________________________________________________ABSOLUTE MAXIMUM RATINGSELECTRICAL CHARACTERISTICS(V CC = +3.0V to +5.5V, C1–C4 = 0.1µF (Note 2), T A = T MIN to T MAX , unless otherwise noted. Typical values are at T A = +25°C.)Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.Note 1:V+ and V- can have a maximum magnitude of 7V, but their absolute difference cannot exceed 13V.V CC ...........................................................................-0.3V to +6V V+ (Note 1)...............................................................-0.3V to +7V V- (Note 1)................................................................+0.3V to -7V V+ + V- (Note 1)...................................................................+13V Input VoltagesT_IN, SHDN , EN ...................................................-0.3V to +6V MBAUD...................................................-0.3V to (V CC + 0.3V)R_IN.................................................................................±25V Output VoltagesT_OUT...........................................................................±13.2V R_OUT....................................................-0.3V to (V CC + 0.3V)Short-Circuit DurationT_OUT....................................................................ContinuousContinuous Power Dissipation (T A = +70°C)16-Pin TSSOP (derate 6.7mW/°C above +70°C).............533mW 16-Pin Narrow SO (derate 8.70mW/°C above +70°C)....696mW 16-Pin Wide SO (derate 9.52mW/°C above +70°C)........762mW 16-Pin Plastic DIP (derate 10.53mW/°C above +70°C)...842mW 18-Pin SO (derate 9.52mW/°C above +70°C)..............762mW 18-Pin Plastic DIP (derate 11.11mW/°C above +70°C)..889mW 20-Pin SSOP (derate 7.00mW/°C above +70°C).........559mW 20-Pin TSSOP (derate 8.0mW/°C above +70°C).............640mW 28-Pin TSSOP (derate 8.7mW/°C above +70°C).............696mW 28-Pin SSOP (derate 9.52mW/°C above +70°C).........762mW 28-Pin SO (derate 12.50mW/°C above +70°C).....................1W Operating Temperature RangesMAX32_ _C_ _.....................................................0°C to +70°C MAX32_ _E_ _ .................................................-40°C to +85°C Storage Temperature Range.............................-65°C to +150°C Lead Temperature (soldering, 10s).................................+300°CMAX3222/MAX3232/MAX3237/MAX3241Transceivers Using Four 0.1µF External Capacitors_______________________________________________________________________________________3TIMING CHARACTERISTICS—MAX3222/MAX3232/MAX3241(V CC = +3.0V to +5.5V, C1–C4 = 0.1µF (Note 2), T A = T MIN to T MAX , unless otherwise noted. Typical values are at T A = +25°C.)ELECTRICAL CHARACTERISTICS (continued)(V CC = +3.0V to +5.5V, C1–C4 = 0.1µF (Note 2), T A = T MIN to T MAX , unless otherwise noted. Typical values are at T A = +25°C.)M A X 3222/M A X 3232/M A X 3237/M A X 3241Transceivers Using Four 0.1µF External Capacitors4_________________________________________________________________________________________________________________________________Typical Operating Characteristics(V CC = +3.3V, 235kbps data rate, 0.1µF capacitors, all transmitters loaded with 3k Ω, T A = +25°C, unless otherwise noted.)-6-5-4-3-2-101234560MAX3222/MAX3232TRANSMITTER OUTPUT VOLTAGEvs. LOAD CAPACITANCELOAD CAPACITANCE (pF)T R A N S M I T T E R O U T P U T V O L T A G E (V )20003000100040005000246810121416182022150MAX3222/MAX3232SLEW RATEvs. LOAD CAPACITANCELOAD CAPACITANCE (pF)S L E W R A T E (V /µs )20003000100040005000510152025303540MAX3222/MAX3232SUPPLY CURRENT vs. LOAD CAPACITANCEWHEN TRANSMITTING DATALOAD CAPACITANCE (pF)S U P P L Y C U R R E N T (m A )20003000100040005000TIMING CHARACTERISTICS—MAX3237(V CC = +3.0V to +5.5V, C1–C4 = 0.1µF (Note 2), T A = T MIN to T MAX , unless otherwise noted. Typical values are at T A = +25°C.)Note 2:MAX3222/MAX3232/MAX3241: C1–C4 = 0.1µF tested at 3.3V ±10%; C1 = 0.047µF, C2–C4 = 0.33µF tested at 5.0V ±10%.MAX3237: C1–C4 = 0.1µF tested at 3.3V ±5%; C1–C4 = 0.22µF tested at 3.3V ±10%; C1 = 0.047µF, C2–C4 = 0.33µF tested at 5.0V ±10%.Note 3:Transmitter input hysteresis is typically 250mV.MAX3222/MAX3232/MAX3237/MAX3241Transceivers Using Four 0.1µF External Capacitors_______________________________________________________________________________________5-7.5-5.0-2.502.55.07.50MAX3241TRANSMITTER OUTPUT VOLTAGEvs. LOAD CAPACITANCELOAD CAPACITANCE (pF)T R A N S M I T T E R O U T P U T V O L T A G E (V )2000300010004000500046810121416182022240MAX3241SLEW RATEvs. LOAD CAPACITANCELOAD CAPACITANCE (pF)S L E W R A T E (V /µs )20003000100040005000510152025303545400MAX3241SUPPLY CURRENT vs. LOADCAPACITANCE WHEN TRANSMITTING DATALOAD CAPACITANCE (pF)S U P P L Y C U R R E N T (m A )20003000100040005000-7.5-5.0-2.502.55.07.50MAX3237TRANSMITTER OUTPUT VOLTAGE vs. LOAD CAPACITANCE (MBAUD = GND)LOAD CAPACITANCE (pF)T R A N S M I T T E R O U T P U T V O L T A G E (V )200030001000400050000102030504060700MAX3237SLEW RATE vs. LOAD CAPACITANCE(MBAUD = V CC )LOAD CAPACITANCE (pF)S L E W R A T E (V /µs )500100015002000-7.5-5.0-2.502.55.07.50MAX3237TRANSMITTER OUTPUT VOLTAGE vs. LOAD CAPACITANCE (MBAUD = V CC )LOAD CAPACITANCE (pF)T R A N S M I T T E R O U T P U T V O L T A G E (V )5001000150020001020304050600MAX3237SUPPLY CURRENT vs.LOAD CAPACITANCE (MBAUD = GND)LOAD CAPACITANCE (pF)S U P P L Y C U R R E N T (m A )200030001000400050000246810120MAX3237SLEW RATE vs. LOAD CAPACITANCE(MBAUD = GND)LOAD CAPACITANCE (pF)S L E W R A T E (V /µs )2000300010004000500010302040506070MAX3237SKEW vs. LOAD CAPACITANCE(t PLH - t PHL )LOAD CAPACITANCE (pF)1000150050020002500_____________________________Typical Operating Characteristics (continued)(V CC = +3.3V, 235kbps data rate, 0.1µF capacitors, all transmitters loaded with 3k Ω, T A = +25°C, unless otherwise noted.)M A X 3222/M A X 3232/M A X 3237/M A X 3241Transceivers Using Four 0.1µF External Capacitors6_____________________________________________________________________________________________________________________________________________________Pin DescriptionMAX3222/MAX3232/MAX3237/MAX3241Transceivers Using Four 0.1µF External Capacitors_______________________________________________________________________________________7_______________Detailed DescriptionDual Charge-Pump Voltage ConverterThe MAX3222/MAX3232/MAX3237/MAX3241’s internal power supply consists of a regulated dual charge pump that provides output voltages of +5.5V (doubling charge pump) and -5.5V (inverting charge pump), regardless of the input voltage (V CC ) over the 3.0V to 5.5V range. The charge pumps operate in a discontinuous mode; if the output voltages are less than 5.5V, the charge pumps are enabled, and if the output voltages exceed 5.5V, the charge pumps are disabled. Each charge pump requires a flying capacitor (C1, C2) and a reservoir capacitor (C3, C4) to generate the V+ and V- supplies.RS-232 TransmittersThe transmitters are inverting level translators that con-vert CMOS-logic levels to 5.0V EIA/TIA-232 levels.The MAX3222/MAX3232/MAX3241 transmitters guaran-tee a 120kbps data rate with worst-case loads of 3k Ωin parallel with 1000pF, providing compatibility with PC-to-PC communication software (such as LapLink™).Typically, these three devices can operate at data rates of 235kbps. Transmitters can be paralleled to drive multi-ple receivers or mice.The MAX3222/MAX3237/MAX3241’s output stage is turned off (high impedance) when the device is in shut-down mode. When the power is off, the MAX3222/MAX3232/MAX3237/MAX3241 permit the outputs to be driven up to ±12V.The transmitter inputs do not have pullup resistors.Connect unused inputs to GND or V CC .MAX3237 MegaBaud OperationIn normal operating mode (MBAUD = G ND), the MAX3237 transmitters guarantee a 250kbps data rate with worst-case loads of 3k Ωin parallel with 1000pF.This provides compatibility with PC-to-PC communica-tion software, such as Laplink.For higher speed serial communications, the MAX3237features MegaBaud operation. In MegaBaud operating mode (MBAUD = V CC ), the MAX3237 transmitters guar-antee a 1Mbps data rate with worst-case loads of 3k Ωin parallel with 250pF for 3.0V < V CC < 4.5V. For 5V ±10%operation, the MAX3237 transmitters guarantee a 1Mbps data rate into worst-case loads of 3k Ωin parallel with 1000pF.Figure 1. Slew-Rate Test CircuitsLapLink is a trademark of Traveling Software, Inc.M A X 3222/M A X 3232/M A X 3237/M A X 3241Transceivers Using Four 0.1µF External Capacitors8_______________________________________________________________________________________RS-232 ReceiversThe receivers convert RS-232 signals to CMOS-logic out-put levels. The MAX3222/MAX3237/MAX3241 receivers have inverting three-state outputs. In shutdown, the receivers can be active or inactive (Table 1).The complementary outputs on the MAX3237 (R1OUTB)and the MAX3241 (R1OUTB, R2OUTB) are always active,regardless of the state of EN or SHDN . This allows for Ring Indicator applications without forward biasing other devices connected to the receiver outputs. This is ideal for systems where V CC is set to 0V in shutdown to accommodate peripherals, such as UARTs (Figure 2).MAX3222/MAX3237/MAX3241Shutdown ModeSupply current falls to less than 1µA in shutdown mode (SHDN = low). When shut down, the device’s charge pumps are turned off, V+ is pulled down to V CC , V- is pulled to ground, and the transmitter outputs are dis-abled (high impedance). The time required to exit shut-down is typically 100µs, as shown in Figure 3. Connect SHDN to V CC if the shutdown mode is not used. SHDN has no effect on R_OUT or R_OUTB.MAX3222/MAX3237/MAX3241Enable ControlThe inverting receiver outputs (R_OUT) are put into a high-impedance state when EN is high. The complemen-tary outputs R1OUTB and R2OUTB are always active,regardless of the state of EN and SHDN (Table 1). EN has no effect on T_OUT.__________Applications InformationCapacitor SelectionThe capacitor type used for C1–C4 is not critical for proper operation; polarized or nonpolarized capacitors can be used. The charge pump requires 0.1µF capaci-tors for 3.3V operation. For other supply voltages, refer to Table 2 for required capacitor values. Do not use values lower than those listed in Table 2. Increasing the capaci-tor values (e.g., by a factor of 2) reduces ripple on the transmitter outputs and slightly reduces power consump-tion. C2, C3, and C4 can be increased without changing C1’s value. However, do not increase C1 without also increasing the values of C2, C3, and C4, to maintain the proper ratios (C1 to the other capacitors).When using the minimum required capacitor values,make sure the capacitor value does not degrade exces-sively with temperature. If in doubt, use capacitors with a higher nominal value. The capacitor’s equivalent series resistance (ESR), which usually rises at low tempera-tures, influences the amount of ripple on V+ and V-.Figure 2. Detection of RS-232 Activity when the UART and Interface are Shut Down; Comparison of MAX3237/MAX3241(b) with Previous Transceivers (a).MAX3222/MAX3232/MAX3237/MAX3241Transceivers Using Four 0.1µF External Capacitors_______________________________________________________________________________________9Power-Supply DecouplingIn most circumstances, a 0.1µF bypass capacitor is adequate. In applications that are sensitive to power-supply noise, decouple V CC to ground with a capacitor of the same value as charge-pump capacitor C1. Connect bypass capacitors as close to the IC as possible.Operation Down to 2.7VTransmitter outputs will meet EIA/TIA-562 levels of ±3.7V with supply voltages as low as 2.7V.Transmitter Outputs whenExiting ShutdownFigure 3 shows two transmitter outputs when exiting shutdown mode. As they become active, the two trans-mitter outputs are shown going to opposite RS-232 lev-els (one transmitter input is high, the other is low).Each transmitter is loaded with 3k Ωin parallel with 2500pF. The transmitter outputs display no ringing or undesirable transients as they come out of shutdown.Note that the transmitters are enabled only when the magnitude of V- exceeds approximately 3V.Mouse DriveabilityThe MAX3241 has been specifically designed to power serial mice while operating from low-voltage power sup-plies. It has been tested with leading mouse brands from manufacturers such as Microsoft and Logitech. The MAX3241 successfully drove all serial mice tested and met their respective current and voltage requirements.Figure 4a shows the transmitter output voltages under increasing load current at 3.0V. Figure 4b shows a typical mouse connection using the MAX3241.CC = 3.3V C1–C4 = 0.1µF50µs/divFigure 3. Transmitter Outputs when Exiting Shutdown or Powering UpM A X 3222/M A X 3232/M A X 3237/M A X 3241Transceivers Using Four 0.1µF External Capacitors10______________________________________________________________________________________Figure 4b. Mouse Driver Test Circuit Figure 4a. MAX3241 Transmitter Output Voltage vs. Load Current per TransmitterMAX3222/MAX3232/MAX3237/MAX3241Transceivers Using Four 0.1µF External Capacitors______________________________________________________________________________________11High Data RatesThe MAX3222/MAX3232/MAX3241 maintain the RS-232±5.0V minimum transmitter output voltage even at high data rates. Figure 5 shows a transmitter loopback test circuit. Figure 6 shows a loopback test result at 120kbps, and Figure 7 shows the same test at 235kbps.For Figure 6, all transmitters were driven simultaneously at 120kbps into RS-232 loads in parallel with 1000pF.For Figure 7, a single transmitter was driven at 235kbps,and all transmitters were loaded with an RS-232 receiver in parallel with 1000pF.The MAX3237 maintains the RS-232 ±5.0V minimum transmitter output voltage at data rates up to 1Mbps.Figure 8 shows a loopback test result at 1Mbps with MBAUD = V CC . For Figure 8, all transmitters were loaded with an RS-232 receiver in parallel with 250pF.CC = 3.3V5µs/divFigure 5. Loopback Test CircuitFigure 6. MAX3241 Loopback Test Result at 120kbpsCC = 3.3V2µs/divFigure 7. MAX3241 Loopback Test Result at 235kbps0V +5V 0V -5V +5V 0VT_INT_OUT = R_IN 5k R_OUT 150pF200ns/divCC = 3.3VFigure 8. MAX3237 Loopback Test Result at 1000kbps (MBAUD = V CC )M A X 3222/M A X 3232/M A X 3237/M A X 3241Transceivers Using Four 0.1µF External Capacitors__________________________________________________Typical Operating CircuitsInterconnection with 3V and 5V LogicThe MAX3222/MAX3232/MAX3237/MAX3241 can directly interface with various 5V logic families, includ-ing ACT and HCT CMOS. See Table 3 for more informa-tion on possible combinations of interconnections.Table 3. Logic-Family Compatibility with Various Supply VoltagesMAX3222/MAX3232/MAX3237/MAX3241Transceivers Using Four 0.1µF External Capacitors______________________________________________________________________________________13_____________________________________Typical Operating Circuits (continued)M A X 3222/M A X 3232/M A X 3237/M A X 3241Transceivers Using Four 0.1µF External Capacitors14___________________________________________________________________________________________________________________________________Pin Configurations (continued)MAX3222/MAX3232/MAX3237/MAX3241Transceivers Using Four 0.1µF External Capacitors______________________________________________________________________________________15______3V-Powered EIA/TIA-232 and EIA/TIA-562 Transceivers from MaximOrdering Information (continued)*Dice are tested at T A = +25°C, DC parameters only.+Denotes lead-free package.M A X 3222/M A X 3232/M A X 3237/M A X 3241Transceivers Using Four 0.1µF External Capacitors16_________________________________________________________________________________________________________Chip Topography___________________Chip InformationT1INT2IN 0.127"(3.225mm)0.087"(2.209mm)R2OUTR2IN T2OUTV CCV+C1+SHDNENC1- C2+C2-V-MAX3222TRANSISTOR COUNT: 339SUBSTRATE CONNECTED TO GNDTransceivers Using Four 0.1µF External CapacitorsPackage Information (The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information, go to /packages.)Revision HistoryPages changed at Rev 7: 1, 15, 16, 17Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.17__________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 (408) 737-7600©2007 Maxim Integrated Products is a registered trademark of Maxim Integrated Products, Inc.。

YR系列（IP44）电动机为一般用途绕线转子三相异步电动机，是我国最新设计的更新换代产品，其安装尺寸和功率等级符合国际电工委员会（IEC）旋转电机标准，安装尺寸与功率等级之间的对应关系与西德DIN42679标准一致。

本系列电动机能在较小的起动电流下提供较大的起动转矩，并能在一定范围内调节速度，它广泛用于下述场合：（1）需要比鼠笼转子电动机更大的起动转矩；（2）馈电线路容量不足以起动鼠笼转子电动机；（3）需要小范围调速；（4）联成“电轴”作同步传动。

如压缩机、榨糖机、纺织机、卷扬机、拉丝机、传输机等机械。

本系列电动机的外壳防护等级为IP44，具有良好的防护性能，可用在尘土飞扬的环境，及不含易燃、易爆或腐蚀性气体的一般场所。

在比较潮湿及有轻微腐蚀性气体的环境中，也较防护式结构为佳。

本系列电动机具有效率高、过载能力强、起动转矩大、结构可靠、外形美观等优点。

特别是机座等基本结构件与Y（IP44）基本系列电动机通用，定、转子参数全国统一，给用户配套互换带来方便。

凡原来选用JR02系列电动机者，均可选用YR系列（IP44）电动机代替。

本系列电动机单机或配套出口，尤为适宜。

昆明电机有限责任公司是YR系列电机的生产主导厂，与上海电器科学研究所一起开发、推广了本系列电动机，具有雄厚的技术力量和丰富的生产经验。

可为用户生产各种不同电压、特殊频率、特殊转子电压及接法、F级绝缘等级具有特殊要求的产品。

型号标志例：YR255 M2-6 （IP44）YR表示“绕”线型“异”步电动机系列代号255表示机座中心高M2表示机座及铁心长短6表示极数（IP44）表示防护等级*S短，M中，L长 2第二种铁心长度功率范围4极 2.2-132kW 6极 1.5-110kW 8极 4-90kW技术数据注：表中性能数据为标准保证值额定电压：380V 额定频率：50Hz 工作方式：连续运行传动方式用联轴器或正齿轮传动，除37kW以上的电动机外，亦可采用皮带轮传动。

Highlights• 4000 hour load life• Ripple Current to 16 amps • ESRs to 6 m Ω• > 90% capacitance at –40 °C • Replaces multiple capacitorsSpecificationsOperating Temperature: –55 °C to +105 °C Rated Voltage: 6.3 to 250 VdcCapacitance: 8.2 µF to 33,000 µFCapacitance Tolerance: 6.3 to 100 Vdc; –10 + 75%, 160 to 250 Vdc; –10 +50% Leakage Current: ≤0.5 √CV µA, 4 mA max, 5 minutesCold Impedance: –55 °C multiple of 25 °C Z ≤4 for 6.3 & 7.5 V, 3 for 10 to 50 V, 2 for > 50 V Ambient TemperatureRipple Current Multipliers:45ºC 55ºC 65ºC 75ºC 85ºC 95ºC 105ºC 1.661.521.371.201.000.750.36FrequencyThe Types 300 and 301 are the wide-temperature, low-ESR capaci-tors for power-supply outputs and UPS battery stiffening. The ex-ceptionally low ESRs enable high ripple-current capability. With series inductance of 12 to 16 n Hand ripple currents to 16 amps one of these capacitors can save by replacing three or four of the 12.5 mm diameter capacitors routinely at the output of switching power supplies. Type 300 has three leads for rugged, reverse-proof mount-ing, and Type 301 has two leads. Types 300R and 301R deliver even lower ESR and higher ripple.High Capacitance and Ultra-Low ESR50 Hz60 Hz 120 Hz 360 Hz 1 kHz 5 kHz 10 kHz & upLess than .77” Diameter 6.3 & 7.5 V 0.760.81 1.00 1.23 1.35 1.41 1.4310 to 40 V 0.740.79 1.00 1.29 1.46 1.55 1.5750V 0.720.78 1.00 1.33 1.54 1.67 1.6963 & 75 V 0.710.76 1.00 1.38 1.64 1.82 1.86100 to 250 V 0.680.741.001.512.002.512.67.77” Diameter 6.3 & 7.5 V 0.820.86 1.00 1.15 1.21 1.24 1.2510 to 40 V 0.780.83 1.00 1.20 1.30 1.351.3650V 0.760.81 1.00 1.25 1.38 1.45 1.4763 & 75 V 0.740.80 1.00 1.28 1.43 1.52 1.54100 to 250 V 0.760.811.001.241.371.441.46.895” Diameter 6.3 & 7.5 V 0.820.86 1.00 1.14 1.20 1.23 1.2410 to 40 V 0.800.84 1.00 1.17 1.25 1.29 1.3050V 0.750.80 1.00 1.27 1.42 1.50 1.52 63 & 75 V 0.750.80 1.00 1.26 1.40 1.48 1.50 100 to 250 V 0.760.811.001.251.381.461.481.02” Diameter 6.3 & 7.5 V 0.840.88 1.00 1.12 1.17 1.19 1.2010 to 40 V 0.810.86 1.00 1.15 1.22 1.25 1.2650V 0.760.81 1.00 1.23 1.35 1.42 1.44 63 & 75 V 0.770.81 1.00 1.23 1.35 1.42 1.44 100 to 250 V0.760.811.001.241.371.441.46Load Life: 4000 h at full load at 85 °C∆ capacitance ± 20%ESR 200 % of limitDCL 100 % of limitShelf Life: 500 h at 105 °C, capacitance, ESR and DCL, initial r equirementsVibration: 10 to 55 Hz, 0.06” and 10 g max, 2 h each planeOu tline Drawing s0.77”, 0.895” and 1.02” Diameters0.51”, 0.65” and .73” DiametersCase DimensionsCase CodeInsulatedD ± 0.015 (0.4 mm)L ± 0.062 (1.6 mm)D x LEpoxyendseal LMaxBare CanD ± 0.015 (0.4 mm)L ± 0.030 (0.8 mm)D x LLead SpacingType 300 Type 301S1 T S2±0.020(0.5 mm) ±0.020(0.5 mm)Lead Diameterdia. AWGCase Dimensions in InchesEG .512 x 0.846 0.9060.492 x 0.787 0.1970.0980.1970.03220 EK .512 x 1.043 1.1420.492 x 0.984 0.1970.0980.1970.03220 EM .512 x 1.102 1.1610.492 x 1.043 0.1970.0980.1970.03220 EN .512 x 1.378 1.4170.492 x 1.319 0.1970.0980.1970.03220 ER .512 x 1.732 1.7910.492 x 1.673 0.1970.0980.1970.03220 FK .650 x 1.043 1.0980.630 x 0.984 0.2950.1480.2950.03220 FF .650 x 1.319 1.4170.630 x 1.260 0.2950.1480.2950.03220 FQ .650 x 1.476 1.5750.630 x 1.417 0.2950.1480.2950.03220 FV .650 x 1.634 1.6690.630 x 1.575 0.2950.1480.2950.03220 LQ .728 x 1.476 1.5750.709 x 1.417 0.2950.1480.2950.03220 LV .728 x 1.634 1.6930.709 x 1.575 0.2950.1480.2950.03220 GE.765 x 1.150 1.2120.750 x 1.1250.2000.3000.3000.04018 GJ.765 x 1.650 1.7120.750 x 1.6250.2000.3000.3000.04018 GL.765 x 2.150 2.2120.750 x 2.1250.2000.3000.3000.04018 GP.765 x 2.650 2.7120.750 x 2.6250.2000.3000.3000.04018 GS.765 x 3.150 3.2120.750 x 3.1250.2000.3000.3000.04018 GT.765 x 3.650 3.7120.750 x 3.6250.2000.3000.3000.04018 HE.890 x 1.150 1.2120.875 x 1.1250.3000.4000.3000.04018 HJ.890 x 1.650 1.7120.875 x 1.6250.3000.4000.3000.04018 HL.890 x 2.150 2.2120.875 x 2.1250.3000.4000.3000.04018 HP.890 x 2.650 2.7120.875 x 2.6250.3000.4000.3000.04018 HS.890 x 3.150 3.2120.875 x 3.1250.3000.4000.3000.04018 HT.890 x 3.650 3.7120.875 x 3.6250.3000.4000.3000.04018 JE 1.015 x 1.150 1.212 1.000 x 1.1250.3000.4000.4000.04018 JJ 1.015 x 1.650 1.712 1.000 x 1.6250.3000.4000.4000.04018 JL 1.015 x 2.150 2.212 1.000 x 2.1250.3000.4000.4000.04018 JP 1.015 x 2.650 2.712 1.000 x 2.6250.3000.4000.4000.04018 JS 1.015 x 3.150 3.212 1.000 x 3.1250.3000.4000.4000.04018 JT 1.015 x 3.650 3.712 1.000 x 3.6250.3000.4000.4000.04018Case Dimensions in MillimetersEG 13.0 x 21.5 2312.5 x 20.0 5.00 2.50 5.000.8120 EK 13.0 x 26.5 29.012.5 x 25.0 5.00 2.50 5.000.8120 EM 13.0 x 28.0 29.512.5 x 26.5 5.00 2.50 5.000.8120 EN 13.0 x 35.0 36.012.5 x 33.5 5.00 2.50 5.000.8120 ER 13.0 x 44.0 45.512.5 x 42.5 5.00 2.50 5.000.8120 FK 16.5 x 26.5 27.916.0 x 25.0 7.50 3.757.500.8120 FF 16.5 x 33.5 36.016.0 x 32.0 7.50 3.757.500.8120 FQ 16.5 x 37.5 40.016.0 x 36.0 7.50 3.757.500.8120 FV 16.5 x 41.5 42.416.0 x 40.0 7.50 3.757.500.8120 LQ 18.5 x 37.5 40.018.0 x 36.0 7.50 3.757.500.8120 LV 18.5 x 41.5 43.018.0 x 40.0 7.50 3.757.500.8120 GE19.4 x 29.230.819.1 x 28.6 5.087.627.62 1.0218 GJ19.4 x 41.943.519.1 x 41.3 5.087.627.62 1.0218 GL19.4 x 54.656.219.1 x 54.0 5.087.627.62 1.0218 GP19.4 x 67.368.919.1 x 66.7 5.087.627.62 1.0218 GS19.4 x 80.081.619.1 x 79.4 5.087.627.62 1.0218 GT19.4 x 92.794.319.1 x 92.1 5.087.627.62 1.0218 HE22.6 x 29.230.822.2 x 28.67.6210.167.62 1.0218 HJ22.6 x 41.943.522.2 x 41.37.6210.167.62 1.0218 HL22.6 x 54.656.222.2 x 54.07.6210.167.62 1.0218 HP22.6 x 67.368.922.2 x 66.77.6210.167.62 1.0218 HS22.6 x 80.081.622.2 x 79.47.6210.167.62 1.0218 HT22.6 x 92.794.322.2 x 92.17.6210.167.62 1.0218 JE25.8 x 29.230.825.4 x 28.67.6210.1610.16 1.0218 JJ25.8 x 41.943.525.4 x 41.37.6210.1610.16 1.0218 HL25.8 x 54.656.225.4 x 54.07.6210.1610.16 1.0218 JP25.8 x 67.368.925.4 x 66.77.6210.1610.16 1.0218 JS25.8 x 80.081.625.4 x 79.47.6210.1610.16 1.0218 JT25.8 x 92.794.325.4 x 92.17.6210.1610.16 1.0218Typical Performance Curves300 - 3 leads 152 = 1500 µF M = ±20% 6R3 =6.3 V 0 = bare can E = epoxy TypeCapacitance Tolerance Voltage Case Code Insulation Epoxy301R 333U6R3JS 2EPart Numbering System300R - 3 leads, 102 = 1000 µF T = 10% +50% 063 = 63 Vdc 1 = Polyester endseal low ESR U = –10 +75% 100 = 100 Vdc 2 = PVC Blank = noepoxy 301- 2 leads 8 = PVC9 = Polyester w/standoffs* 301R - 2 leads, low ESR w/standoffs*301A- Laydown 3 leads*Not available in .77” diameterCap. (µF)Catalog Part NumberESR MAX @ 25°C 120 Hz 20 kHz(mΏ)Ripple MAX @ 85ºC 120 Hz 20 kHz(mΏ)Nom Size Insulated D x L (in)Cap. (µF)Catalog Part NumberESR MAX @ 25°C 120 Hz 20 kHz (mΏ)Ripple MAX @ 85ºC 120 Hz 20 kHz(mΏ)Nom SizeInsulated D x L (in)6.3 Vdc (9 Vdc Surge)8200301R822U6R3HJ2 44.325.7 3.99 4.93.895 x 1.65 680301681U6R3EM2 231.0150.0 1.16 1.44.51 x 1.10 10000301R103M6R3LV2 54.024.0 3.47 5.21.73 x 1.63 1000301102U6R3FK2 160.090.0 1.54 2.05.65 x 1.04 10000301103U6R3GP2 37.821.5 5.12 6.39.77 x 2.65 1200301122U6R3ER2 134.070.0 1.78 2.46.51 x 1.73 10000301R103U6R3GP2 32.718.7 5.50 6.86.77 x 2.65 1500301R152M6R3EG2 201.071.0 1.09 1.84.51 x .85 12000301123U6R3GS2 31.017.7 6.177.70.77 x 3.15 1500301152U6R3FN2 105.050.0 2.00 2.90.65 x 1.32 12000301R123U6R3GS2 26.815.3 6.628.27.77 x 3.15 2200301R222M6R3EM2 110.060.0 1.20 1.63.51 x 1.10 12000301123U6R3HL2 35.021.3 5.20 6.27.895 x 2.15 2700301272U6R3GE2 143.081.5 1.71 2.13.77 x 1.15 12000301R123U6R3HL2 25.514.8 6.097.54.895 x 2.15 2700301R272U6R3GE2 124.070.6 1.84 2.29.77 x 1.15 12000301123U6R3JJ243.029.2 4.39 5.02 1.02 x 1.65 3300301R332M6R3EN2 93.057.0 1.78 2.28.51 x 1.38 12000301R123U6R3JJ2 37.221.2 4.72 5.89 1.02 x 1.65 3300301332U6R3LV276.045.0 2.61 3.39.73 x 1.63 150********U6R3GT2 26.615.17.108.86.77 x 3.65 3900301R392M6R3FK2 111.041.0 1.84 3.03.65 x 1.04 15000301R153U6R3GT2 23.013.17.629.52.77 x 3.65 3900301392U6R3HE2 100.061.1 2.24 2.71.895 x 1.15 150********U6R3HP2 27.116.5 6.577.93.895 x 2.65 3900301R392U6R3HE2 86.850.3 2.41 2.98.895 x 1.15 15000301R153U6R3HP2 19.511.37.759.60.895 x 2.65 4700301R472M6R3ER2 68.031.0 2.52 3.73.51 x 1.73 18000301183U6R3JL229.620.1 6.08 6.95 1.02 x 2.15 4700301472U6R3GJ272.541.3 2.65 3.30.77 x 1.65 18000301R183U6R3JL2 19.110.97.579.45 1.02 x 2.15 4700301R472U6R3GJ2 62.835.8 2.84 3.55.77 x 1.65 22000301223U6R3HS2 22.413.77.889.51.895 x 3.15 5600301R562M6R3FF2 78.037.0 2.43 3.53.65 x 1.32 22000301R223U6R3HS2 15.99.29.3511.60.895 x 3.15 5600301562U6R3JE283.857.0 2.56 2.92 1.02 x 1.15 22000301223U6R3JP2 23.015.67.668.75 1.02 x 2.65 5600301R562U6R3JE2 72.741.4 2.75 3.43 1.02 x 1.15 22000301R223U6R3JP2 14.78.49.5912.00 1.02 x 2.65 6800301R682M6R3FQ2 71.034.0 2.53 3.65.65 x 1.48 27000301273U6R3HT2 19.411.99.0410.90.895 x 3.65 8200301R822M6R3FV2 59.031.03.034.18.65 x 1.65 27000301R273U6R3HT2 13.67.910.8013.40.895 x 3.65 8200301R822M6R3LQ2 67.029.0 2.97 4.51.73 x 1.48 27000301273U6R3JS2 19.213.09.1110.40 1.02 x 3.15 8200301822U6R3GL2 49.228.1 4.025.02.77 x 2.15 27000301R273U6R3JS2 15.18.610.3012.80 1.02 x 3.15 8200301R822U6R3GL2 42.724.3 4.32 5.40.77 x 2.15 33000301333U6R3JT2 16.711.410.5012.00 1.02 x 3.65 8200301822U6R3HJ251.131.23.714.48.895 x 1.6533000301R333U6R3JT2 10.45.913.3016.601.02 x 3.65Ratings RoHS CompliantCap. (µF)CatalogPart NumberESR MAX@ 25°C120 Hz 20 kHz(mΏ)Ripple MAX@ 85ºC120 Hz 20 kHz(mΏ)Nom SizeInsulatedD x L(in)Cap.(µF)CatalogPart NumberESR MAX@ 25°C120 Hz 20 kHz(mΏ)Ripple MAX@ 85ºC120 Hz 20 kHz(mΏ)Nom SizeInsulatedD x L(in)7.5 Vdc (10 Vdc Surge) 3300301R332U010HE2 106.061.8 2.17 2.69.895 x 1.152200301222U7R5GE2 147.080.8 1.69 2.14.77 x 1.15 3300301332U010HE2 92.350.8 2.33 2.97.895 x 1.15 2200301R222U7R5GE2 127.070.0 1.81 2.30.77 x 1.15 3900301392U010GJ2 77.641.1 2.56 3.31.77 x 1.65 3900301392U7R5HE2 103.061.6 2.21 2.69.895 x 1.15 3900301R392U010GJ2 67.335.7 2.75 3.56.77 x 1.65 3900301R392U7R5HE2 88.948.9 2.38 3.02.895 x 1.15 4700301R472M010FF2 87.038.0 2.29 3.47.65 x 1.32 4700301472U7R5GJ2 74.541.0 2.61 3.32.77 x 1.65 4700301472U010JE2 88.356.5 2.49 2.94 1.02 x 1.15 4700301R472U7R5GJ2 64.535.5 2.80 3.56.77 x 1.65 4700301R472U010JE2 76.542.8 2.68 3.37 1.02 x 1.15 5600301562U7R5JE2 85.556.5 2.53 2.94 1.02 x 1.15 5600301R562M010FQ2 78.033.0 2.35 3.62.65 x 1.48 5600301R562U7R5JE2 74.141.5 2.72 3.42 1.02 x 1.15 5600301562U010GL2 52.727.9 3.89 5.04.77 x 2.15 6800301682U7R5GL2 50.627.8 3.97 5.05.77 x 2.15 5600301R562U010GL2 45.624.2 4.18 5.41.77 x 2.15 6800301R682U7R5GL2 43.824.1 4.26 5.42.77 x 2.15 6800301R682M010LQ2 71.031.0 2.92 4.42.73 x 1.48 6800301682U7R5HJ2 52.431.4 3.67 4.46.895 x 1.65 6800301682U010HJ2 54.331.5 3.60 4.46.895 x 1.65 6800301R682U7R5HJ2 45.425.0 3.94 5.01.895 x 1.65 6800301R682U010HJ2 47.125.9 3.87 4.92.895 x 1.65 8200301822U7R5GP2 38.721.3 5.05 6.42.77 x 2.65 8200301R882M010LV2 60.026.0 3.30 5.01.73 x 1.63 8200301R822U7R5GP2 33.618.5 5.43 6.90.77 x 2.65 8200301822U010GP2 40.321.4 4.95 6.41.77 x 2.65 10000301103U7R5HL2 35.821.5 5.14 6.25.895 x 2.15 8200301R822U010GP2 34.918.5 5.32 6.89.77 x 2.65 10000301R103U7R5HL2 26.214.4 6.017.64.895 x 2.15 8200301822U010JJ2 45.228.9 4.28 5.05 1.02 x 1.65 10000301103U7R5JJ2 43.828.9 4.35 5.05 1.02 x 1.65 8200301R822U010JJ2 39.221.9 4.60 5.80 1.02 x 1.65 10000301R103U7R5JJ2 38.021.3 4.67 5.89 1.02 x 1.65 10000301103U010GS2 33.017.5 5.977.73.77 x 3.15 12000301123U7R5GS2 31.817.5 6.097.74.77 x 3.15 10000301R103U010GS2 28.615.2 6.418.31.77 x 3.15 12000301R123U7R5GS2 27.515.1 6.548.31.77 x 3.15 10000301103U010HL2 37.121.5 5.05 6.25.895 x 2.15 12000301123U7R5GT2 27.215.07.018.91.77 x 3.65 10000301R103U010HL2 27.315.0 5.887.48.895 x 2.15 12000301R123U7R5GT2 23.613.07.539.57.77 x 3.65 12000301123U010GT2 28.315.0 6.888.91.77 x 3.65 150********U7R5HP2 27.716.6 6.507.91.895 x 2.65 12000301R123U010GT2 24.513.07.399.57.77 x 3.65 15000301R153U7R5HP2 20.011.07.659.73.895 x 2.65 12000301123U010HP2 28.716.6 6.397.91.895 x 2.65 150********U7R5JL2 30.119.9 6.02 6.99 1.02 x 2.15 12000301R123U010HP2 20.811.57.499.53.895 x 2.65 15000301R153U7R5JL2 19.610.97.479.41 1.02 x 2.15 12000301123U010JL2 31.019.9 5.93 6.99 1.02 x 2.15 180********U7R5HS2 22.913.87.799.48.895 x 3.15 12000301R123U010JL2 20.311.47.339.23 1.02 x 2.15 18000301R183U7R5HS2 16.39.09.2311.70.895 x 3.15 150********U010HS2 23.713.77.669.49.895 x 3.15 22000301223U7R5HT2 19.811.98.9510.90.895 x 3.65 15000301R153U010HS2 17.09.39.0511.50.895 x 3.15 22000301R223U7R5HT2 13.97.710.7013.60.895 x 3.65 180********U010HT2 20.511.98.8110.90.895 x 3.65 22000301223U7R5JP2 23.415.57.598.80 1.02 x 2.65 18000301R183U010HT2 14.58.010.5013.30.895 x 3.65 22000301R223U7R5JP2 15.08.49.4711.90 1.02 x 2.65 180********U010JP2 24.115.47.488.81 1.02 x 2.65 27000301273U7R5JS2 19.512.99.0310.50 1.02 x 3.15 18000301R183U010JP2 15.68.79.2911.70 1.02 x 2.65 27000301R273U7R5JS2 15.58.710.1012.80 1.02 x 3.15 22000301223U010JS2 20.112.88.9010.50 1.02 x 3.15 33000301333U7R5JT2 17.011.210.4012.10 1.02 x 3.65 22000301R223U010JS2 16.19.09.9412.50 1.02 x 3.15 33000301R333U7R5JT2 10.6 5.913.1016.60 1.02 x 3.65 27000301273U010JT2 17.511.210.3012.10 1.02 x 3.6510 Vdc (15 Vdc Surge) 27000301R273U010JT2 11.0 6.212.9016.30 1.02 x 3.65 1000301R102M010EG2 216.077.0 1.07 1.80.51 x .85 16 Vdc (25 Vdc Surge)1500301R152M010EK2 200.064.0 1.07 1.90.51 x 1.04 820301R821M016EG2 216.085.0 1.12 1.78.51 x .85 1800301R182M010EM2 122.062.0 1.58 2.21.51 x 1.10 1200301R122M016EM2 130.066.0 1.60 2.24.51 x 1.10 1800301182U010GE2 153.081.2 1.65 2.14.77 x 1.15 1500301152U016GE2 159.080.9 1.62 2.14.77 x 1.15 1800301R182U010GE2 133.070.3 1.77 2.30.77 x 1.15 1500301R152U016GE2 138.070.1 1.74 2.30.77 x 1.15 2700301R272M010EN2 111.059.0 1.66 2.28.51 x 1.38 1800301R182M016EN2 122.055.0 1.85 2.76.51 x 1.38 2700301R272M010FK2 116.042.0 2.04 3.39.65 x 1.04 2200301R222M016FK2 120.042.0 1.79 3.02.65 x 1.04 3300301R332M010ER2 75.032.0 2.41 3.69.51 x 1.73 2700301R272M016ER2 82.032.0 1.66 2.65.51 x 1.73Cap. (µF)CatalogPart NumberESR MAX@ 25°C120 Hz 20 kHz(mΏ)Ripple MAX@ 85ºC120 Hz 20 kHz(mΏ)Nom SizeInsulatedD x L(in)Cap.(µF)CatalogPart NumberESR MAX@ 25°C120 Hz 20 kHz(mΏ)Ripple MAX@ 85ºC120 Hz 20 kHz(mΏ)Nom SizeInsulatedD x L(in)2700301272U016HE2 110.063.7 2.14 2.65.895 x 1.15 1200301R122U020GE2 138.070.1 1.74 2.30.77 x 1.15 2700301R272U016HE2 95.252.4 2.30 2.92.895 x 1.15 1500301R152M020ER2 85.033.0 2.23 3.58.51 x 1.73 3300301R332M016FF2 78.032.0 2.42 3.78.65 x 1.32 1500301152U020LV2 90.050.0 2.42 3.25.73 x 1.63 3300301332U016GJ2 80.441.0 2.51 3.32.77 x 1.65 2200301R222M020FQ2 77.032.0 2.55 3.96.65 x 1.48 3300301R332U016GJ2 69.735.5 2.70 3.56.77 x 1.65 2200301222U020HE2 110.061.5 2.14 2.70.895 x 1.15 3300301332U016JE2 90.756.2 2.46 2.94 1.02 x 1.15 2200301R222U020HE2 95.253.3 2.30 2.90.895 x 1.15 3300301R332U016JE2 78.641.6 2.64 3.42 1.02 x 1.15 2700301272U020GJ2 80.441.0 2.51 3.32.77 x 1.65 3900301R392M016FQ2 75.032.0 2.59 3.97.65 x 1.48 2700301R272U020GJ2 69.735.5 2.70 3.56.77 x 1.65 4700301R472M016LQ2 74.032.0 2.85 4.34.73 x 1.48 2700301272U020JE2 90.757.1 2.46 2.92 1.02 x 1.15 4700301472U016GL2 54.527.8 3.82 5.05.77 x 2.15 2700301R272U020JE2 78.649.5 2.64 3.14 1.02 x 1.15 4700301R472U016GL2 47.224.1 4.11 5.42.77 x 2.15 3300301R332M020LV2 62.026.0 3.19 4.92.73 x 1.63 4700301472U016HJ2 56.032.5 3.55 4.39.895 x 1.65 3900301392U020GL2 54.527.8 3.82 5.05.77 x 2.15 4700301R472U016HJ2 48.526.7 3.81 4.84.895 x 1.65 3900301R392U020GL2 47.224.1 4.11 5.42.77 x 2.15 5600301R562M016LV2 62.026.0 3.22 4.98.73 x 1.63 3900301392U020HJ2 56.031.4 3.55 4.47.895 x 1.65 5600301562U016GP2 41.721.3 4.87 6.43.77 x 2.65 3900301R392U020HJ2 48.527.2 3.81 4.80.895 x 1.65 5600301R562U016GP2 36.118.4 5.23 6.90.77 x 2.65 4700301472U020GP2 41.721.3 4.87 6.43.77 x 2.65 6800301682U016HL2 38.222.2 4.97 6.15.895 x 2.15 4700301R472U020GP2 36.118.4 5.23 6.90.77 x 2.65 6800301R682U016HL2 28.315.6 5.787.35.895 x 2.15 5600301562U020JJ2 46.429.2 4.23 5.02 1.02 x 1.65 6800301682U016JJ2 46.428.8 4.23 5.06 1.02 x 1.65 5600301R562U020JJ2 40.221.3 4.54 5.88 1.02 x 1.65 6800301R682U016JJ2 40.221.3 4.54 5.88 1.02 x 1.65 6800301682U020GS2 34.117.4 5.877.75.77 x 3.15 8200301822U016GS2 34.117.4 5.877.75.77 x 3.15 6800301R682U020GS2 29.615.1 6.318.33.77 x 3.15 8200301R822U016GS2 29.615.1 6.318.33.77 x 3.15 6800301682U020HL2 38.221.4 4.97 6.26.895 x 2.15 10000301103U016GT2 29.214.9 6.778.94.77 x 3.65 6800301R682U020HL2 28.315.8 5.787.28.895 x 2.15 10000301R103U016GT2 25.312.97.279.60.77 x 3.65 8200301822U020GT2 29.214.9 6.778.94.77 x 3.65 10000301103U016HP2 29.517.1 6.307.79.895 x 2.65 8200301R822U020GT2 25.312.97.279.60.77 x 3.65 10000301R103U016HP2 21.611.97.369.36.895 x 2.65 8200301822U020HP2 29.516.5 6.307.93.895 x 2.65 10000301103U016JL2 31.819.7 5.867.01 1.02 x 2.15 8200301R822U020HP2 21.612.17.369.28.895 x 2.65 10000301R103U016JL2 21.011.17.219.33 1.02 x 2.15 8200301822U020JL2 31.820.1 5.86 6.96 1.02 x 2.15 12000301123U016HS2 24.414.17.559.35.895 x 3.15 8200301R822U020JL2 21.011.17.219.33 1.02 x 2.15 12000301R123U016HS2 17.69.78.8911.30.895 x 3.15 10000301103U020HS2 24.413.77.559.52.895 x 3.15 150********U016HT2 21.112.28.6910.80.895 x 3.65 10000301R103U020HS2 17.69.88.8911.20.895 x 3.15 15000301R153U016HT2 15.08.210.3013.10.895 x 3.65 12000301123U020HT2 21.111.88.6910.90.895 x 3.65 150********U016JP2 24.715.37.398.85 1.02 x 2.65 12000301R123U020HT2 15.08.410.3013.00.895 x 3.65 15000301R153U016JP2 16.18.59.1411.80 1.02 x 2.65 12000301123U020JP2 24.715.67.398.77 1.02 x 2.65 180********U016JS2 20.512.78.8010.50 1.02 x 3.15 12000301R123U020JP2 16.18.59.1411.80 1.02 x 2.65 18000301R183U016JS2 16.68.89.7912.70 1.02 x 3.15 150********U020JS2 20.512.98.8010.50 1.02 x 3.15 22000301223U016JT2 17.911.110.1012.10 1.02 x 3.65 15000301R153U020JS2 13.27.011.0014.20 1.02 x 3.15 22000301R223U016JT2 11.4 6.012.7016.50 1.02 x 3.65 180********U020JT2 17.911.210.1012.00 1.02 x 3.6520 Vdc (30 Vdc Surge)18000301R183U020JT2 11.4 6.012.7016.50 1.02 x 3.65 330301331U020EM2 360.0160.00.89 1.34.51 x 1.10 25 Vdc (35 Vdc Surge)470301R471M020EG2 250.077.00.550.99.51 x .85 330301331U025EN2 290.0120.0 1.13 1.75.51 x 1.38 470301471U020FK2 240.090.0 1.22 2.00.65 x 1.04 390301R391M025EG2 267.092.00.89 1.52.51 x .85 560301561U020ER2 220.080.0 1.41 2.34.51 x 1.73 470301471U025ER2 220.080.0 1.42 2.35.51 x 1.73 680301R681M020EM2 140.067.0 1.46 2.11.51 x 1.10 560301R561M025EK2 193.075.0 1.12 1.79.51 x 1.04 680301681U020FF2 170.060.0 1.72 2.90.65 x 1.32 680301R681M025EM2 160.067.0 1.40 2.17.51 x 1.10 1000301R102M020EN2 114.048.0 1.10 1.69.51 x 1.38 680301681U025FQ2 190.075.0 1.53 2.44.65 x 1.48 1200301122U020GE2 159.080.9 1.62 2.14.77 x 1.15 1000301R102M025EN2 152.056.0 1.62 2.67.51 x 1.381000301102U025GE2 170.081.8 1.57 2.13.77 x 1.15 330301R331M040EM2 202.068.0 1.19 2.05.51 x 1.10 1000301R102U025GE2 148.070.9 1.68 2.29.77 x 1.15 330301331U040FN2 330.0120.0 1.35 2.24.65 x 1.32 1200301R122M025ER2 90.034.0 2.20 3.58.51 x 1.73 390301391U040ER2 270.0150.0 1.42 1.90.51 x 1.73 1200301R122M025FK2 132.045.0 1.71 2.93.65 x 1.04 470301R471M040FK2 133.046.0 1.66 2.82.65 x 1.04 1200301122U025LV2 100.050.0 2.26 3.20.73 x 1.63 680301R681M040ER2 95.035.0 2.07 3.41.51 x 1.73 1500301R152M025FF2 95.039.0 2.20 3.44.65 x 1.32 820301821U040LV2 160.075.0 1.78 2.60.73 x 1.63 1800301R182M025FQ2 75.032.0 2.59 3.97.65 x 1.48 1000301R102M040FQ2 80.033.0 2.49 3.87.65 x 1.48 1800301182U025HE2 117.062.1 2.07 2.68.895 x 1.15 1200301122U040HE2 137.065.6 1.92 2.61.895 x 1.15 1800301R182U025HE2 102.047.7 2.23 3.06.895 x 1.15 1200301R122U040HE2 118.052.1 2.06 2.93.895 x 1.15 2200301R222M025FV2 73.031.0 2.69 4.13.65 x 1.65 1500301R152M040LV2 63.027.0 3.16 4.82.73 x 1.63 2200301R222M025LQ2 70.030.0 2.84 4.34.73 x 1.48 1500301152U040JE2 109.060.2 2.24 2.84 1.02 x 1.15 2200301222U025GJ2 86.341.4 2.42 3.30.77 x 1.65 1500301R152U040JE2 94.843.6 2.40 3.34 1.02 x 1.15 2200301R222U025GJ2 74.835.9 2.60 3.54.77 x 1.65 2200301222U040HJ2 69.433.3 3.18 4.33.895 x 1.65 2700301R272M025LV2 62.026.0 3.22 4.97.73 x 1.63 2200301R222U040HJ2 60.226.5 3.42 4.86.895 x 1.65 2700301272U025JE2 95.857.5 2.39 2.91 1.02 x 1.15 3300301332U040HL2 47.222.6 4.48 6.09.895 x 2.15 2700301R272U025JE2 83.041.5 2.57 3.42 1.02 x 1.15 3300301R332U040HL2 36.015.8 5.127.28.895 x 2.15 3300301332U025GL2 58.428.1 3.69 5.02.77 x 2.15 3300301332U040JJ2 55.830.7 3.86 4.90 1.02 x 1.65 3300301R332U025GL2 50.624.3 3.97 5.40.77 x 2.15 3300301R332U040JJ2 48.322.2 4.14 5.76 1.02 x 1.65 3300301332U025HJ2 59.731.6 3.44 4.45.895 x 1.65 3900301R392U040GS2 37.116.7 5.637.92.77 x 3.15 3300301R332U025HJ2 51.724.3 3.69 5.07.895 x 1.65 4700301472U040GT2 36.416.4 6.068.52.77 x 3.65 4700301472U025GP2 44.721.4 4.71 6.40.77 x 2.65 4700301R472U040GT2 31.614.2 6.519.15.77 x 3.65 4700301R472U025GP2 38.718.6 5.05 6.88.77 x 2.65 4700301472U040HP2 36.217.4 5.687.73.895 x 2.65 4700301472U025JJ2 48.929.4 4.12 5.01 1.02 x 1.65 4700301R472U040HP2 27.412.0 6.549.29.895 x 2.65 4700301R472U025JJ2 42.421.2 4.42 5.90 1.02 x 1.65 4700301472U040JL2 38.120.9 5.35 6.81 1.02 x 2.15 5600301562U025GS2 36.517.5 5.687.73.77 x 3.15 4700301R472U040JL2 26.512.2 6.428.93 1.02 x 2.15 5600301R562U025GS2 31.615.2 6.108.30.77 x 3.15 5600301562U040HS2 29.714.3 6.849.31.895 x 3.15 5600301562U025HL2 42.022.3 4.74 6.14.895 x 2.15 5600301R562U040HS2 22.29.87.9111.20.895 x 3.15 5600301R562U025HL2 30.414.3 5.587.67.895 x 2.15 6800301682U040HT2 25.512.37.8910.70.895 x 3.65 6800301682U025GT2 31.215.0 6.558.91.77 x 3.65 6800301R682U040HT2 18.98.39.1813.10.895 x 3.65 6800301R682U025GT2 27.013.07.049.58.77 x 3.65 6800301682U040JP2 29.416.2 6.778.61 1.02 x 2.65 6800301682U025HP2 31.316.6 6.117.91.895 x 2.65 6800301R682U040JP2 20.29.38.1711.40 1.02 x 2.65 6800301R682U025HP2 23.110.97.119.77.895 x 2.65 8200301822U040JS2 24.313.48.0910.30 1.02 x 3.15 6800301682U025JL2 33.520.1 5.71 6.94 1.02 x 2.15 8200301R822U040JS2 16.57.69.8213.60 1.02 x 3.15 6800301R682U025JL2 22.511.3 6.969.29 1.02 x 2.15 10000301103U040JT2 21.011.59.3511.90 1.02 x 3.65 8200301822U025HS2 25.813.77.349.50.895 x 3.15 10000301R103U040JT2 14.1 6.511.4015.90 1.02 x 3.65 8200301R822U025HS2 18.98.98.5911.81.895 x 3.15 50 Vdc (75 Vdc Surge)10000301103U025HT2 22.311.88.4510.94.895 x 3.65 100301101U050EN2 810.0260.00.65 1.14.51 x 1.38 10000301R103U025HT2 16.07.59.9613.69.895 x 3.65 120301R121M050EG2 391.0139.00.79 1.33.51 x .85 10000301103U025JP2 26.015.67.208.77 1.02 x 2.65 150301151U050FK2 550.0220.00.82 1.30.65 x 1.04 10000301R103U025JP2 17.28.68.8411.80 1.02 x 2.65 180301R181M050EK2 261.090.00.95 1.61.51 x 1.04 12000301123U025JS2 21.612.98.5910.50 1.02 x 3.15 180301181U050ER2 500.0180.00.93 1.55.51 x 1.73 12000301R123U025JS2 14.17.110.6014.10 1.02 x 3.15 220301R221M050EM2 240.069.0 1.12 2.08.51 x 1.04 150********U025JT2 18.711.29.9012.10 1.02 x 3.65 220301221U050FN2 420.0150.0 1.09 1.83.65 x 1.32 15000301R153U025JT2 12.1 6.012.3016.40 1.02 x 3.65 330301R331M050EN2 221.063.0 1.19 2.22.51 x 1.3840 Vdc (60 Vdc Surge) 390301R391M050FK2 150.048.0 1.60 2.82.65 x 1.04 220301221U040FK2 480.0140.00.89 1.65.65 x 1.04 470301R47lM050ER2 111.036.0 1.97 3.46.51 x 1.73470301471U050LV2 250.090.0 1.44 2.40.73 x 1.63 390301391U063GE2 281.092.7 1.22 2.00.77 x 1.15 56030lR561M050FF2 118.041.0 1.98 3.36.65 x 1.32 390301R391U063GE2 243.080.3 1.31 2.15.77 x 1.15 560301R561U050GE2 216.088.6 1.39 2.05.77 x 1.15 470301R471M063FF2 142.043.0 1.80 3.27.65 x 1.32 560301561U050GE2 249.0102.0 1.29 1.91.77 x 1.15 560301R561M063FQ2 120.035.0 2.05 3.80.65 x 1.48 680301R681M050FQ2 102.040.0 2.31 3.69.65 x 1.48 680301R681M063FV2 113.032.0 2.06 3.87.65 x 1.65 820301R821M050FV2 95.038.0 2.40 3.79.65 x 1.63 680301R681M063LQ2 103.029.0 2.21 4.17.73 x 1.48 820301R821M050LQ2 89.036.0 2.59 4.07.73 x 1.48 680301681U063HE2 185.070.5 1.65 2.52.895 x 1.15 1000301R102M050LV2 77.028.0 2.90 4.81.73 x 1.63 680301R681U063HE2 161.053.0 1.77 2.90.895 x 1.15 1200301R122U050GJ2 109.044.7 2.16 3.18.77 x 1.65 820301R821M063LV2 90.029.0 2.69 4.74.73 x 1.63 1200301122U050GJ2 126.051.6 2.01 2.96.77 x 1.65 820301821U063GJ2 142.046.7 1.89 3.11.77 x 1.65 1200301122U050JE2 130.062.4 2.05 2.79 1.02 x 1.15 820301R821U063GJ2 123.040.5 2.03 3.34.77 x 1.65 1200301R122U050JE2 113.043.9 2.21 3.33 1.02 x 1.15 1000301102U063JE2 144.063.2 1.95 2.78 1.02 x 1.15 1500301R152U050GL2 73.430.1 3.29 4.85.77 x 2.15 1000301R102U063JE2 124.043.5 2.10 3.34 1.02 x 1.15 1500301152U050GL2 84.734.7 3.07 4.52.77 x 2.15 1200301122U063GL2 95.231.4 2.89 4.75.77 x 2.15 1800301182U050HJ2 84.034.5 2.89 4.26.895 x 1.65 1200301R122U063GL2 82.527.2 3.11 5.10.77 x 2.15 1800301R182U050HJ2 72.826.2 3.11 4.89.895 x 1.65 1200301122U063HJ2 93.835.6 2.74 4.19.895 x 1.65 2200301R222U050GP2 55.822.9 4.21 6.20.77 x 2.65 1200301R122U063HJ2 81.326.8 2.94 4.83.895 x 1.65 2200301222U050GP2 64.426.4 3.92 5.77.77 x 2.65 1500301152U063GP2 72.323.8 3.70 6.07.77 x 2.65 2700301R272U050GS2 45.318.6 5.107.51.77 x 3.15 1500301R152U063GP2 62.620.7 3.97 6.52.77 x 2.65 2700301272U050GS2 52.321.4 4.75 6.99.77 x 3.15 1800301182U063HL2 63.424.1 3.86 5.90.895 x 2.15 2700301272U050HL2 56.923.3 4.07 6.00.895 x 2.15 1800301R182U063HL2 50.116.5 4.347.13.895 x 2.15 2700301R272U050HL2 44.516.0 4.617.24.895 x 2.15 1800301182U063JJ2 72.832.0 3.37 4.80 1.02 x 1.65 2700301272U050JJ2 66.031.7 3.54 4.82 1.02 x 1.65 1800301R182U063JJ2 63.122.1 3.62 5.78 1.02 x 1.65 2700301R272U050JJ2 57.222.3 3.81 5.75 1.02 x 1.65 2200301222U063GS2 58.619.3 4.487.36.77 x 3.15 3300301R332U050GT2 38.415.7 5.908.69.77 x 3.65 2200301R222U063GS2 50.816.8 4.827.90.77 x 3.15 3300301332U050GT2 44.318.2 5.498.09.77 x 3.65 2200301222U063GT2 49.616.4 5.198.53.77 x 3.65 3300301332U050HP2 43.517.8 5.187.63.895 x 2.65 2200301R222U063GT2 43.014.2 5.589.16.77 x 3.65 3300301R332U050HP2 33.712.1 5.899.26.895 x 2.65 2700301272U063HP2 48.418.4 4.927.52.895 x 2.65 3900301392U050JL2 44.921.6 4.93 6.71 1.02 x 2.15 2700301R272U063HP2 37.912.5 5.559.11.895 x 2.65 3900301R392U050JL2 32.412.6 5.818.77 1.02 x 2.15 2700301272U063JL2 49.521.8 4.70 6.68 1.02 x 2.15 4700301472U050HS2 35.614.6 6.259.21.895 x 3.15 2700301R272U063JL2 36.312.7 5.488.74 1.02 x 2.15 4700301R472U050HS2 27.39.87.1411.20.895 x 3.15 3300301332U063HS2 39.515.0 5.949.08.895 x 3.15 5600301562U050HT2 30.412.57.2310.60.895 x 3.65 3300301R332U063HS2 30.710.1 6.7311.10.895 x 3.15 5600301R562U050HT2 23.18.38.3013.00.895 x 3.65 3900301392U063HT2 33.712.8 6.8710.50.895 x 3.65 5600301562U050JP2 34.516.6 6.258.50 1.02 x 2.65 3900301R392U063HT2 25.98.57.8412.90.895 x 3.65 5600301R562U050JP2 24.69.67.4011.20 1.02 x 2.65 3900301392U063JP2 37.916.7 5.968.47 1.02 x 2.65 6800301682U050JS2 28.413.67.4810.20 1.02 x 3.15 3900301R392U063JP2 27.69.7 6.9911.10 1.02 x 2.65 6800301R682U050JS2 20.07.88.9113.40 1.02 x 3.15 4700301472U063JS2 31.113.77.1510.20 1.02 x 3.15 8200301822U050JT2 24.411.78.6711.80 1.02 x 3.65 4700301R472U063JS2 22.47.88.4213.40 1.02 x 3.15 8200301R822U050JT2 17.0 6.610.4015.70 1.02 x 3.65 5600301562U063JT2 26.711.78.3011.80 1.02 x 3.6563 Vdc (90 Vdc Surge) 5600301R562U063JT2 19.0 6.69.8315.70 1.02 x 3.65 120301R121M063EG2 451.093.00.73 1.60.51 x .85 75 Vdc (100 Vdc Surge)180301R18lM063EK2 298.090.0 1.01 1.83.51 x 1.04 330301331U075GE2 360.0155.0 1.08 1.55.77 x 1.15 270301R271M063EN2 160.055.0 1.44 2.46.51 x 1.38 330301R331U075GE2 312.0134.0 1.16 1.66.77 x 1.15 330301R331M063FK2 171.050.0 1.48 2.74.65 x 1.04 470301471U075HE2 234.0108.0 1.47 2.04.895 x 1.15 390301R391M063ER2 130.038.0 1.83 3.38.51 x 1.73 470301R471U075HE2 203.087.3 1.57 2.26.895 x 1.15。

NG012200 Under Counter RefrigeratorOwner’s ManualFOR YOUR SAFTEYDO NOT STORE OR USE GASOLINE OR OTHER FLAMMABLE VAPORS OR LIQUIDS IN THE VICINITY OF THIS OR ANY OTHERAPPLIANCE.WARNING: IMPROPER INSTALLATION,ADJUSTMENT, ALTERATION, OR MAINTENANCE CAN CAUSE INJURY ORDEATH. READ THE INSTALLATION,OPERATION AND MAINTENANCE INSTRUCTIONS THOROUGHLY BEFOREINSTALLING OR SERVICING THISEQUIPMENT.KEEP THIS MANUAL IN A SAFE PLACE AND RETAIN FOR FUTUREUSESupplier Name: Address:Serial #:Date Received: Date Installed: Telephone #:Fax#:Service Warranty NSC #: Sertek LLC6399 Shier Rings Rd Dublin, OH 43016______________________ ______________________ ______________________ 614-504-5828614-504-5728877-277-7221Owner’s ManualSertek Under Counter RefrigeratorProduct DescriptionThe NGK Under Counter Refrigerator MG3 Model NG012200 has been built to fit into Wendy’s NGK front counter assemblies. It features two drawers for holding packaged product.Table of ContentsReplacement Parts List 5-7 Daily Maintenance 8 Monthly Maintenance 9 Servicing the Condensing Unit 10 Servicing the Evaporator 11-12 Troubleshooting Guide 13 MR4PMUHV Temperature/Defrost Control Quick Reference Guide 14-15 MR4PMUHV Display Code Chart 16 Electrical Schematics 17 Service Chart 18-1912 34 5 6Replacement Parts List789Refrigeration Unit1011 1213 14 1516List of Replacement Parts1. Remove the two pans to be cleaned at the store’s dish tank.2. Inspect the unit’s drawer gaskets and slides. Ensure that there is no food build up and that both thedrawer slide and gasket are functioning properly.Daily MaintenanceMonthly Maintenance1. Perform Daily Maintenance.2. Remove the unit’s drawer slides and clean the storage bay.I. Follow the steps below to remove the drawer slides from the unit.II. With the drawer slides removed there is clear access to the storage bay. Use a damp cloth and Wendy’s approved cleaner to thoroughly wipe down the interior of the unit.III. Once the bay is cleaned replace the drawer slides following the steps shown below.Servicing the Condensing Unit1. Remove the unit from it’s housing in the Front Counter.2. The condensing unit, temperature control, high pressure switch, axial fans, and condensate evaporator pan can be accessed from the back of the unit.1. In order to reach the evaporators and expansion valve complete access to the cooler bay will be needed. To accomplish this you will need to remove the drawer assembly insert. First remove all the pans from the drawer slides. Next remove the four 7/16” bolts securing the inserts to the cooler bay. The locations of these bolts are shown below2. Remove the two 7/16th bolts from the bottom and the drawer carriage can be pulled from the front of the unit.3. Once the drawer carriage is removed there is clear access to the evaporator. To open the evaporator casing and access the coil and expansion valve, remove the four 1/4” hex head screws holding the cover in place.Troubleshooting GuideUsing the control moduleDuring normal operation, the display shows the main sensor temperature.Press up or down to scroll through the main sensor temperature, evaporatorsensor temperature, and the binary input status.Press and hold enter for approximately three seconds to view the set point. Note: After 15 seconds of inactivity, the display shows the main temperature. Initiating a manual deep freeze1. In sequence, press and hold enter then up.2. Hold both buttons for five seconds.3. The compressor output status LED lights and compressor contactsclose.Unlocking or locking access to programming1. In sequence, press and hold enter, up, and then down.2. Hold all three buttons until ——— is displayed.3. Continue holding until the sensed temperature is displayed(approximately ten seconds).Changing the set point1. Press and hold enter for approximately three seconds.2. Release enter when the set point value is displayed.3. Press up or down to display the new set point value.4. Press enter to save the new set point value.Note: if enter is not pressed, the new set point value is not saved, and control reverts to the previous set point value.Changing other function settings1. Press and hold enter for approximately 10 seconds.2. The display code for differential is displayed (HY).3. Press up or down until the display code for the desired function isdisplayed (see freezer settings list).4. Press enter. The functions existing value is displayed.5. Press up or down until the desired setting value is displayed.6. Press enter to save the new value. After 10 seconds of inactivity the,display returns to normal operation.Note: If enter is not pressed, the new value is not saved and reverts to the previousMR4PMUHV Display Code ChartElectrical SchematicsNGK UNDER COUNTER REFRIGERATORMODEL NG012200OWNER’S MANUAL7NG012200-MNL1.10153/9/16 RS。

Per-DRAM AddressabilityDDR4 allows programmability of a single, specific DRAM on a rank. As an example, thisfeature can be used to program different ODT or V REF values on each DRAM on a givenrank. Because per-DRAM addressability (PDA) mode may be used to program optimalV REF for the DRAM, the data set up for first DQ0 transfer or the hold time for the lastDQ0 transfer cannot be guaranteed. The DRAM may sample DQ0 on either the first fall-ing or second rising DQS transfer edge. This supports a common implementation be-tween BC4 and BL8 modes on the DRAM. The DRAM controller is required to drive DQ0to a stable LOW or HIGH state during the length of the data transfer for BC4 and BL8cases. Note, both fixed and on-the-fly (OTF) modes are supported for BC4 and BL8 dur-ing PDA mode.1.Before entering PDA mode, write leveling is required.•BL8 or BC4 may be used.2.Before entering PDA mode, the following MR settings are possible:•R TT(Park) MR5 A[8:6] = Enable•R TT(NOM) MR1 A[10:8] = Enable3.Enable PDA mode using MR3 [4] = 1. (The default programed value of MR3[4] = 0.)4.In PDA mode, all MRS commands are qualified with DQ0. The device capturesDQ0 by using DQS signals. If the value on DQ0 is LOW, the DRAM executes theMRS command. If the value on DQ0 is HIGH, the DRAM ignores the MRS com-mand. The controller can choose to drive all the DQ bits.5.Program the desired DRAM and mode registers using the MRS command andDQ0.6.In PDA mode, only MRS commands are allowed.7.The MODE REGISTER SET command cycle time in PDA mode, AL + CWL + BL/2 -0.5t CK + t MRD_PDA + PL, is required to complete the WRITE operation to themode register and is the minimum time required between two MRS commands.8.Remove the device from PDA mode by setting MR3[4] = 0. (This command re-quires DQ0 = 0.)Note: Removing the device from PDA mode will require programming the entire MR3when the MRS command is issued. This may impact some PDA values programmedwithin a rank as the EXIT command is sent to the rank. To avoid such a case, the PDAenable/disable control bit is located in a mode register that does not have any PDAmode controls.In PDA mode, the device captures DQ0 using DQS signals the same as in a normalWRITE operation; however, dynamic ODT is not supported. Extra care is required forthe ODT setting. If R TT(NOM) MR1 [10:8] = enable, device data termination needs to becontrolled by the ODT pin, and applies the same timing parameters (defined below).mand execution is unknown; the corresponding DRAM internal state change may or may not occur. The DRAM controller should consider both cases and make sure that the command sequence meets the specifications.5.Only a DESELECT command is allowed; CKE may go HIGH prior to Td2 as long as DES commands are issued.Figure 55: Parity Entry Timing Example – t MRD_PARTa0Ta1Ta2Tb0Tb1Tb2Command Parity latency CK_tCK_cEnableparityDon’t CareNote: 1.t MRD_PAR = t MOD + N; where N is the programmed parity latency.Figure 56: Parity Entry Timing Example – t MOD_PARTa0Ta1Ta2Tb0Tb1Tb2Command Parity latency CK_tCK_cEnableparityDon’t CareTime Break Note: 1.t MOD_PAR = t MOD + N; where N is the programmed parity latency.Figure 57: Parity Exit Timing Example – t MRD_PARTa0Ta1Ta2Tb0Tb1Tb2Command Parity latency CK_tCK_cDisableparityDon’t CareNote: 1.t MRD_PAR = t MOD + N; where N is the programmed parity latency.4Gb: x8, x16 Automotive DDR4 SDRAM Command/Address Parity。

1、技术参数1.1 产品型号意义注：※前的项目选型时必须标注，※后的项目为选择项目，不要时可省略，但顺序不可颠倒。

-1-- 2 -1.2 结构1.2.1 361普通型结构图1.2.1 361普通型结构图（1。

1）图1.11.2.2 361防爆型结构图图1.2-3-1.3 主要技术参数表-4-- 5 -1．4 安装尺寸1．4．1 安装尺寸图图1.3表1.3注：表中H 2是拆卸护罩所必须的尺寸，R 是手动操作所必须的尺寸，在设计安装时应予以考虑。

1．4．2 RSA 、RSB 、RXB 型带底座、曲柄安装方式尺寸图图1.4- 6 -表1.4注：表中H 2是拆卸护罩所必须的尺寸，R 是手动操作所必须的尺寸，在设计安装时应予以考虑。

1．4．3 RSC 、RXC 型带底座、曲柄安装方式尺寸图图1.5表1.5注：L 3、L 6、L 8符合DKJ-310安装尺寸。

L 4、L 7、L 9符合DKJ-410安装尺寸。

H 2是拆卸护罩所必须的尺寸，R 是手动操作所必须的尺寸，在设计安装时应予以考虑。

1．4．4 RSD 、RXD 型带底座、曲柄安装方式尺寸图图1.6- 7 -表1.6注：表中H 2是拆卸护罩所必须的尺寸，R 是手动操作所必须的尺寸，在设计安装时应予以考虑。

2、工作原理3610系列电子式执行器是以220V 单相交流电源作为驱动电源，接受来自计算机、调节器或操作器4～2 OmAd ·c 、或1～5 Vd ·c 输入信号来工作的电子式执行机构。

电子控制单元采用集成电路制做，被设计成匣子形式，并用树脂浇铸固化，称为控制模块，本身具有伺服功能。

控制模块接收到变化的输入信号4～2OmAd ·c （或1～5 Vd ·c)和来自反馈机构的开度信号进行比较、放大后，向消除其差值的方向驱动和控制电机。

电机的旋转通过减速机构把动力传递到蜗轮轴上，使其顺、逆时针转动，同时通过反馈机构带动电位器转动，电位器的动作变换成电气信号后，作为开度信号反馈给控制器。

L DESIGN FEATURESIntroductionThe LTC3612 monolithic synchronous buck regulator can source 3A and sink 1.5A from a tiny 3mm × 4mm QFN or 20-lead TSSOP package with exposed pads for improved thermal performance. This device saves space, minimizes external components and is highly efficient. It employs a constant frequency, current mode architecture that operates from an input range of 2.25V to 5.5V—suitable for a single Li-Ion battery or low voltage input applications. The LTC3612 provides an adjustable regulated output down to 0.6V.The LTC3612 uses Burst Mode ® operation to increase efficiency at light loads, consuming less than 100µA of supply current at no load. Adjustable compensation allows the transient response to be optimized over a wide range of loads and output capacitors. The internal synchronous switch increases efficiency and eliminates the need for an external catch diode, saving external components and board space.Design Versatility Depending on the application require-ments, a designer can either prioritize light load efficiency or minimize sup-ply noise by choosing from three light load operating modes: Burst Modeoperation, pulse-skipping, or forcedcontinuous modes. Burst Mode op-eration provides high efficiency overthe entire load range by reducing gatecharge losses at light loads. BurstMode operation is an efficient solution for low current applications, but insome applications noise suppression is a higher priority. Forced continuous operation, though not as efficient as Burst Mode operation at light loads,maintains a constant switching fre-quency, making it easier to reduce noise and RF interference. In forced continuous operation, the LTC3612 can source and sink current. Pulse-skipping mode is similar to Burst Mode operation. It reduces output voltage ripple, but incurs more gate charge losses, compromising light load ef-ficiency. Although not as efficient as Burst Mode operation at low currents, pulse-skipping mode still provides high efficiency for moderate loads.The default frequency of 2.25MHz ischosen by tying the RT/SYNC pin to V IN . This high frequency allows the use of tiny inductors and ceramic output capacitors without compromising ef-ficiency. The switching frequency can be set from 300kHz to 4MHz with an external resistor or synchronized to an external clock, where each switch-ing cycle begins at the falling edge of the external clock signal. All operat-ing modes (Burst Mode operation, pulse-skipping and forced continuous mode) can be selected in combination with the default 2.25MHz frequency, a frequency defined by an external resistor or synchronization with ex-ternal clock.The LTC3612 offers a power good indicator (PGOOD pin), which moni-tors the output voltage. The PGOOD pin is an open-drain output which is pulled down to ground during shut down, start-up and while the output voltage is outside the power good voltage window (±7.5% of the final programmed output voltage). If the output voltage stays inside the power good window for more than 100µs, the PGOOD pin is released. If the output voltage remains outside the power good window for more than 100µs, the PGOOD pin is pulled down.The 100% duty cycle capability for low dropout conditions allows maxi-Monolithic Synchronous Step-Down Regulator Sources 3A or Sinks 1.5A in TSSOP or 3mm × 4mm QFNby Genesia BertelleLOAD CURRENT (mA)E F F I C I E N C Y (%)102030405060708090100Figure 2. Efficiency vs load current, 2.25MHzswitching frequency, in various operating modesTT =V DD /2V IN V Figure 1. High efficiency and very compact 1.5A LTC3612 V TT power supply with 3.3V inputquirements, where capacitor ESR and ESL primarily determine the amount of droop or overshoot in the output voltage. If a load step with very fast slew rate occurs, an output voltage excursion is seen for transients in both directions: that is for full load to minimum load and for the minimum load to full load.If the ITH pin is tied to SVIN, the ac-tive voltage positioning (AVP) mode and internal compensation are selected. AVP mode intentionally compromises output voltage regulation by reducing the gain of the feedback circuit, result-ing in an output voltage that varies with load current.When the load current suddenly increases, the output voltage starts from a level slightly higher than nomi-nal so the output voltage can droop and stay within the specified voltage range. When the load current suddenly decreases the output voltage starts at a level lower than nominal so the output voltage can overshoot and stay within the specified voltage range. In AVP mode the external compensation at ITH pin is not needed, reducing external components.Short-Circuit ProtectionThe LTC3612 is protected against an output short to ground. When the output is shorted to ground, the inductor current decays very slowly during a single switching cycle. The LTC3612 uses two techniques to pre-vent inductor current runaway from occurring.First, if the output voltage drops be-low 50% of its nominal value, the peak current clamp is decreased, reducing the maximum inductor current. When the output voltage reaches 0V, theclamp voltage at the ITH pin drops to 40% of the clamp voltage during nor-mal operation. The short-circuit peak inductor current is determined by theminimum on-time of the LTC3612, the input voltage and the inductor value. This foldback behavior helps in limit-ing the peak inductor current when theoutput is shorted to ground.Secondly, a limit is also imposed on the valley inductor current. If the mum energy to be extracted from a Li-Ion battery. In dropout, the output voltage is determined by the input voltage minus the voltage drop across the internal P-channel MOSFET (only 70m Ω) and the inductor resistance.Power Supply Tracking and DDR ApplicationsThe LTC3612 supports coincidental or ratiometric ramp-up and ramp-down tracking of another supply via the TRACK/SS pin. For TRACK/SS volt-ages lower than 0.2V, the switching frequency is reduced to ensure that the minimum duty cycle limit does not prevent the output voltage from following the TRACK/SS pin.Start-up behavior can be pro-grammed in one of three ways via the TRACK/SS pin. Tying TRACK/SS to SVIN selects the internal soft-start circuit (1ms ramp time). Alternately, external soft-start timing can be pro-grammed with a TRACK/SS capacitor to ground and a resistor to SVIN. Fi-nally, the TRACK/SS pin can be used to force the LTC3612 to track the start-up behavior of another supply.When running in DDR mode, the TRACK/SS pin can be used as an external reference input, allowing theLTC3612 to power DDR memory. In this mode, the power good window moves in relation to the actual TRACK/SS pin voltage.Typically DDR memory needs at least two main power supplies: V DD and V TT , where V TT must always track the V DD supply with V TT = V DD /2. Since the termination resistors can carry current in either direction, the V TT power supply must be able to both source and sink current while tracking the V DD supply.Two LTC3612 converters can be used to generate both V DD and V TT , as shown in the circuit in Figure 1. V TT voltages range from 1.25V down to 0.75V for different DDR standards. LTC3612 can be used for all DDR standards because the TRACK/SS voltage can accept a reference voltage from 0.6V down to 0.3V (although TRACK/SS voltage values from 0.4V to 0.5V are the most accurate).Optional AVP Mode with Internal Compensation Fast load current transient response is an important feature in microproces-sor power supplies. Normally, several capacitors in parallel are required to meet microprocessor transientre-V DD100mV/DIV V TT100mV/DIV 1ms/DIVFigure 5. V TT responding to a change in V DDfor the circuit shown in Figure 1V OUT 200mV/DIVI LOAD 1A/DIV0A50µs/DIV–1.5V1.5VFigure 4. Load transient response for ±1.5Aload applied to the circuit shown in Figure 1V OUT 200mV/DIVI L 1A/DIV 50µs/DIVV OUT = 1.8VI LOAD = 100mA TO 3A V MODE= 1.5VV OUT 100mV/DIVI L 1A/DIV50µs/DIVV OUT = 1.8VI LOAD = 100mA TO 3A V MODE = 1.5V V ITH = V INFigure 3. Load step transient in forced continuous modecontinued on page 15mode and maximum charge current is determined as follows:V BAT(MIN) = 5.7VV BAT(PRE) < 5.7V V CHRG(PRE) = 0.15 • I CHRG V CHRG(PRE) = 0.3AUsing and efficiency of 0.85, plot P IN over the range of V IN that is current controlled. This is the regulated V IN , or V REG , power line. The intersection of the V REG power line with the solar panel power curve is the operating point. As the battery charges, the slope of the V REG power line increases, indicating the increase in input power required to support the increasing output power. The intersection of the V REG power line continues to follow up the solar panel’s power curves until the charger exits constant cur-rent mode.The resulting plots are shown in Figure 4.The Circuit in Action Figure 4 shows the power output of the solar panel plotted at light intensity levels from 100W/m 2 to 1000W/m 2 in 100W/m 2 steps. At maximum light intensity (top curve in Figure 4) and the battery voltage just above the pre-conditioning level (V BAT(MIN) at 2A), the solar panel is producing more power than the charger needs. The solar panel voltage rises above the V REG control voltage and travels across the constant power line until it intersects the light-power-intensity curve for that intensity level (point A in Figure 4). As the battery charges, the input power increases and the solar panel operating point moves up the light-power-intensity curve until the battery V V V VVBAT PRE BAT MIN BAT FLOAT ()()()•..<=2333approaches full charge (point B). The LT3652 transitions from constant cur-rent mode to constant voltage mode and the charging current is reduced. The solar panel operating point moves back down the light-power-intensity curve to the open circuit voltage (point C) when the battery reaches its final float voltage. During the charging of the battery, if the light intensity diminishes, the op-eration point moves across a constant power line for the battery voltage until it reaches the new power-intensity curve. If the light intensity level con-tinues to diminish, the operating point travels along this constant power line until it reaches the V REG power line. At this point the charging current is reduced until the operating point is at the intersection of the light-power-in-tensity curve and the V REG power line (point D for constant current charging at V BAT(FLOAT) with 800W/m 2 illumi-nation). As the battery continues to charge at this light intensity level, the operating point moves along the new light-power-intensity curve until the battery approaches full charge.As darkness approaches, the op-erating point moves down the V REG power line until charging current ceases (point E) and the solar panel output voltage drops below the SHDN falling threshold at which point the LT3652 turns off.The remaining elements of the design, selection of output inductor, catch rectifier and timer capacitor, are outlined in the design procedurein the LT3652 datasheet along with PCB layout considerations.The maximum power voltage, for a monocrystalline solar cell, has atemperature coefficient of –0.37%/K while the maximum power level is –0.47%/K. This may be compensated for by letting R IN1 be a combination of a series resistor and a series NTC thermistor. The ratio of the two ele-ments that comprise R IN1 and the value of R IN2 need to be adjusted to achievethe correct negative temperature of V IN while still maintaining the control range of V IN .∆••∆•()V V R R R R R IN NTC REG IN NTC NTCIN NTC=21Conclusion The input voltage regulation loop ofthe LT3652 has the ability to seek outthe maximum power operating point of a solar panel’s power characteristic, thus utilizing the full capacity of the solar panel. The float voltage regula-tion loop and its adjustable charging current enable the LT3652 to be used with many battery chemistries, making it a versatile battery charger. The added features of a wide input voltage range, an auto-recharge cycle to maintain a fully charged battery, a battery pre-conditioning mode, NTC temperature sensing, selectable C/10 or timed charging termination, a FAULT and a charging status pins fills out the full feature set of the LT3652. The LT3652 is available in a 3mm × 3mm 12-lead plastic DFN, package with an exposed pad. LThe input voltage regulation loop of the LT3652 has the ability to seek out the maximum power operating point of a solar panel’s power characteristic, thus utilizing the full capacity of the solar panel.inductor current measured through the bottom MOSFET increases beyond 6A, the top power MOSFET is held off and switching cycles are skipped until the inductor current is reduced.LTC3612, continued from page 11ConclusionThe LTC3612 is well suited for a wide range of low voltage step-down con-verter applications, including DDR memory termination applications requiring ±1.5A of output current. Itshigh switching frequency and internal low R DS(ON) power switches allow the LTC3612 to offer a compact, high ef-ficiency design solution supplying up to 3A output current. L。

3616中文资料Token Ring Product Set for Compaq NonStop?Himalaya K-Series Servers Networking Services Product Description High-speed token ring connectivity and token ring support for multiple protocolsThe token ring product set for Compaq NonStop? Himalaya K-series servers includes the Compaq Token Ring LAN Controller product(product3616) and enhanced versions of Compaq SNAX/XF,Compaq SNAX/APN,TCP/IP for Compaq NonStop? Himalaya K-series servers,and Compaq Expand networking software that provide token ring support.The Token Ring LAN Controller product enables you to connect Compaq NonStop?Himalaya K-series servers to IEEE 802.5 token ring local area networks (LAN s).A higher-speed,lower-cost alternative to multiple communications lines or Compaq SNAXL ink controllers,token ring networks provide straightforward connection to IBM hosts and Systems Network Architecture (SNA)devices such as workstations and personal computers (PCs).Features at a glanceHigh-speed connectionto token ring LAN sSimplified cabling andnetwork maintenanceDiverse connectivityoptionsCompaq SNAX/XF andCompaq SNAX/APNTCP/IPCompaq ExpandSupport for peer-oriented and client/server computing Compatibility with existing applicationsToken ring support for popular protocols enables Compaq NonStop? Himalaya K-series servers to participate in a variety of token ring computing environments:SNAX/XF and SNAX/APN support facilitating both traditional and peer-oriented SNAnetworkingTCP/IP support facilitating client/server computingExpand networking software support pro-viding high-speed communicationsbetween Compaq NonStop? HimalayaK-series servers on the token ring network. Any SNAX/XF or SNAX/APN applications that run over leased lines,X.25 packet networks,or SNAXL ink controllers can now run over token ring networks as well.Therefore,you can con-tinue to use applications and protocols without change,leveraging your existing investments.High-speed connection totoken ring LAN sThe Token Ring LAN Controller product lets Compaq NonStop? Himalaya K-series servers participate in either 4- or 16-megabit-per-second token ring networks,which provide throughput exceeding that of wide-area networks.In addition,the Token Ring LAN Controller product supports early token release, a feature of 16-megabit-per-second token ring networks that improves performance by allow-ing the token to be released while multiple frames are being transmitted on the network. Actual throughput depends on the capacity of the target device,the type of Compaq NonStop? Himalaya K-seriesserver,data block sizes,and tuning parameters.The Token Ring LAN Controller subsystem is compliant with IEEE802.2.Token ring support for SNAX/XF and SNAX/APN software has the potential to improve the performance of online transaction processing and decision-support applications involving Compaq NonStop? Himalaya K-series server and IBM hosts by increasing transaction rates and speed of file transfer.Simplified cabling and network maintenance Because token ring networks offer higher band-width than telecommunications lines,the Token Ring LAN Controller product can greatly reduce the number of cables needed to connect Compaq NonStop? Himalaya K-series servers to IBM systems,simplifying wiring,maintenance, and troubleshooting.A variety of network management functions are supported by the Compaq token ring soft-ware product set,including Distributed Systems Management(DSM),Subsystem Control Facility (SCF),Event Management Service (EMS),and Dynamic System Configuration (DSC).Diverse connectivity optionsThe Token Ring LAN Controller product pro-vides diverse connectivity options in conjunc-tion with token ring support for SNAX/XF, SNAX/APN,TCP/IP,and Expand software.SNAX/XF and SNAX/APNSNAX/XF and SNAX/APN token ring support provide a high-speed 802.5 LAN alternative to synchronous data link control (SDLC)and X.25 connections.SNAX/XF software simultaneously supports token ring,SNAXL ink,X.25,and SDLC connec-tions.This facilitates migration to token ring networks because the Token Ring LAN Controller product can be installed and tested while the existingconfiguration is running.TCP/IPCompaq NonStop? Himalaya K-series servers can connect to TCP/IP systems and clients over Ethernet or token ring networks.Through TCP/IP token ring support,you can migrate to TCP/IP in a token ring environment without the expense of adding Ethernet LAN s.Expand networking software Expand networking software is a Compaq pro-tocol for high-speed communications between Compaq NonStop? Himalaya K-series servers.It provides connectivity in both token ring and Ethernet networks.This enables you to include two or more Compaq NonStop? Himalaya K-series servers in your token ring network without adding Ethernet LAN s.Support for peer-oriented and client/server computingToken ring support for popular network protocols simplifies the inclusion of Compaq NonStop? Himalaya K-series servers in both peer-oriented and client/server networks (see figure).Peer-oriented networking reduces costs by opti-mizing network and system resources and by eliminating the need for devices that manage the traffic to and from the master device in hierarchical networking.Compaq supports peer-oriented networking withSNAX/APN for APPN NT2.1 connection,provid-ing network-level peer-oriented connection. SNAX/APC for LU 6.2 connection,providing program-to-program,peer-oriented connec-tion.The SNAX/APC product is an optionalproduct that is one layer above the SNAX/XF and SNAX/APN products.With the Token Ring LAN Controller product,you can useCompaq NonStop? Himalaya K-series servers in client/server environments in two ways:with the SNAX/XF or SNAX/APN products or with Compaq Remote Server Call (RSC)soft-ware over TCP/IP.SNAX/XF and SNAX/APN support for token ring networking enables you to transfer large quan-tities of data at high speeds between Compaq NonStop? Himalaya K-series servers and main-frame,midrange,PC,and other devices in dis-tributed SNA ing RSC software over TCP/IP on token ring networks,Compaq NonStop? Himalaya K-series servers can execute the server portion of appli-cations while workstations and PCs on the token ring execute the client portion. Compatibility with existing applicationsExisting applications written for SNAX/HLS, SNAX/APC,and Compaq SNAX application pro-gram interfaces (APIs) can operate without modification over the token ring versions of SNAX/XF and SNAX/APN protocols.In fact,any SNAX/XF or SNAX/APN applications that run over leased lines,X.25 packet networks,or SNAXL ink controllers now can run over token ring networks as well.This means you can lever-age existing applications while taking advan-tage of the greater speed and simpler manageability of token ring networks.For More Information WEBSITE:2000 Compaq Computer Corporation. All rights reserved. February 2000. Compaq, Expand, Himalaya, and NonStop, registered U.S. Patent and Trademark Office. Remote Server Call (RSC) is based on the Transaction Delivery System (TDS), which is a registered trademark of Cornerstone Software, Inc. Otherproduct names mentioned herein may be trademarks and/or regis-tered trademarks of their respective companies. Technical specifications and availability are subject to change without notice.99-1004。

纽扣电池型号对照表扣式电池button battery总高度小于直径的圆柱形电池，形似纽扣或硬币纽扣电池的型号通常是在纽扣电池的背面由字母和阿拉伯数字组成。

下面例举两种材料的纽扣电池的型号对照表。

纽扣电池新旧型号对照表LR---水银--1.5V，SR---氧化银--1.55V，CR---锂电--3V，ZA---锌空--1.4V氧化银纽扣电池是最常用的手表电池，绝大部分的手表使用的是氧化银纽扣电池。

新电池的电压一般在1.55V到1.58V之间，电池的保质期是3年。

在一块运行良好的手表上使用其运行时间一般不低于两年。

纽扣锂电池，3V锂纽扣电池多使用于防盗器，门禁，电脑等处，有的手表也配备锂电池。

锂电池的保质期为7年，在一般情况下用户一般不用担心电池过期。

瑞士的氧化银纽扣电池型号为3##，日本的型号通常是SR###SW，或SR###W（#代表一个阿拉伯数字）。

纽扣锂电池的型号通常为CR####。

不同材料的纽扣电池，其型号规格也就不同。

大小尺寸mm 瑞士型号 = 日本型号4.8 x 1.6 mm 337＝SR416SW5.8 x 1.2 mm 335＝SR512SW5.8 x 1.6 mm 317＝SR516SW5.8 x 2.1 mm 379＝SR521SW5.8 x 2.6 mm 319＝SR527SW6.8 x 1.4 mm 339＝SR614SW6.8 x 2.1 mm 364＝SR621SW6.8 x 2.6 mm 377＝SR626SW7.9 x 1.2 mm 346＝SR712SW7.9 x 1.4 mm 341＝SR714SW7.9 x 1.6 mm 315＝SR716SW7.9 x 2.1 mm 362＝SR721SW7.9 x 2.6 mm 397＝SR726SW7.9 x 3.1 mm 329＝SR731SW7.9 x 3.6 mm 384＝SR741SW7.9 x 5.4 mm 309＝SR754SW9.5 x 1.6 mm 373＝SR916SW9.5 x 2.1 mm 371＝SR920SW9.5 x 2.6 mm 395＝SR927SW9.5 x 3.6 mm 394＝SR936SW11.6 x 1.6 mm 366＝SR1116SW11.6 x 2.1 mm 381＝SR1120SW11.6 x 3.1 mm 390＝SR1130SW11.6 x 3.6 mm 344＝SR1136SW11.6 x 4.2 mm 301＝SR1143SW11.6 x 5.4 mm 303＝SR1144SW锂-二氧化锰纽扣电池型号对照表——CR系列其型号AG为日本标准，SR为国际标准型号纽扣电池也叫扣式电池是指外形尺寸象一颗小纽扣的电池一般来说直径较大厚度较薄(相对于柱状电池如市场上的5号AA等电池);纽扣电池是从外形上来对电池来分同等对应的电池分类有柱状电池方形电池异形电池;纽扣电池一般来说常见的有充电的和不充电的两种充电的包括3.6V可充锂离子扣式电池(LIR系列)3V可充锂离子扣式电池(ML或VL系列);不充电的包括3V锂锰扣式电池(CR系列)及1.5V碱性锌锰扣式电池(LR及SR系列);纽扣电池的型号名称前面的英文字母表示电池的种类数字表示尺寸前两位数字表示直径后两位表示厚度; 纽扣电池因体形较小直径从4.8mm至30mm厚度从1.0mm至7.7mm不等；一般用于各类电子产品的后备电源，如电脑主板，电子表，电子词典，电子秤，记忆卡，遥控器，电动玩具等；以下每一行均代表同一电池(仅供参考)：AG0 LR69 379 SR521AG1 LR621 364 SR621 164AG2 LR726 396 SR726 196AG3 LR41 392 SR41 192AG4 LR626 377 SR626 177AG5 LR754 393 SR754 193AG6 LR920 371 SR927 171AG7 LR927 395 SR927 195AG8 LR55 391 SR1120 191 LR1120AG9 LR936 394 SR936 194AG10 LR54 389 SR1130 189 LR1130AG11 LR721 362 SR721 162AG12 LR43 386 SR43 186 LR1142AG13 LR44 357 SR44 A76 LR1154337 SR416321 SR616315 SR716362 SR721373 SR916371 SR920特性：1，氧化银电池有“SR××”及“SR××SW”两个系列。