EML5313中文资料

IM3331三相多功能电能计量模块产品手册V1.3.1● 提供三相全波电压、电流、功率、功率因数、电量及总电量等用电参数 ● 提供全波有功、无功、RMS 或PQS 视在功率 ● 提供有功、无功、视在电能● 提供三相失压、过载、过流、失流、过压、欠压、失压、电压电流逆相序、不平衡度等事件检测 ● 提供三相电压、电流的 41次谐波含量数据● 具有1路TTL 通讯接口，通信规约采用标准 Modbus-RTU 和DLT645-2007协议 ● 具有脉冲指示灯和PF 输出，便于第三方精度检定● 具有报警输出，可自定义输出事件，如过压、过流、失压、失流、相序错误、欠压等。

● 三相三线与三相四线硬件兼容，软件可根据需要配置● 符合欧盟RoHS 指令2011/65EU 附录的修订指令(EU)2015/863要求目前，公司IM 系列交直流计量模块已经在交流充电桩、智能家居、动环监控FSU 、智能安防、照明监控、智能园区、数字机房、能耗管理、电机保护等领域广泛应用，得到各行业标杆企业的采用和认可。

此模块可方便应用于路灯监控、智能家居、智能家电、节能改造、智能用电管理、安防监控、设备能耗监测、电机保护等诸多行业，是迈入物联网时代的重要配套模块。

光电有限公司研制开发的拥有完全自主知识产权的三相电计量产品。

该产品技术性能完全符合62053-21术要求，能直接精确地测量额定频率为60HZ 因数、电量及电能总量等用电相关参数。

该产品内置Modbus-RTU/DLT645-2007AMR 形美观、安装方便等特点。

设备。

检查确认接线无误后，再接通电源测试。

●接通电源后，电源蓝色指示灯常亮，通讯时，此蓝色指示灯在通讯数据传输时同步闪烁。

●产品出厂时，均设置为默认配置：地址 1 号、波特率 9600bps、数据格式“n,8,1”,可通过我们提供的测试软件来更改设置产品参数及产品的一般性测试。

●重要！模块校表通讯接口与对外数据通讯共用一个uart通讯口。

12/27/2002DescriptionThese Precision Optical Performance oval LEDs are specifically designed for Full Color / Video and Passenger Information signs.High efficiency LED materials are used in these lamps:Aluminum Indium Gallium Phosphide (AlInGaP)for red,amber and green, and Indium Gallium Nitride (InGaN) for true green and blue.Designers can select parallel(where the axis of the leads is parallel to the wide axis of the oval radiation pattern) or perpendicular orientation. Designers can also choose between lamps with or without standoffs.Featuresl Smooth, Consistent Spatial Radiation Patterns l High Luminous Output lEmitting Colors :632 nm Ultra Red 625 nm Red 605 nm Orange 590 nm Amber 573 nm Green 525 nm True Green 470 nm Bluel Superior Resistance to Moisture lChoice of Package OptionsBenefitsl Viewing Angle Designed for Wide Field of View Applicationsl Red, True Green, and Blue Radiation Patterns Matched for Full Color Signs lSuperior Outdoor Environmental PerformanceApplicationsl Full Color / Video Sings lVariable Message SignsPassenger Information AdvertisingTime / TemperatureUnity Opto Technology Co., Ltd.OVAL PRECISIONOPTICAL PERFORMANCE LED LAMPs Technical DataPackage DimensionNotes :1. Tolerance is ± 0.25 mm (.010") unless otherwise noted.2. Protruded resin under flange is 1.5 mm (.059") max.3. Lead spacing is measured where the leads emerge from the package.Part Numbering SchemeMVL-6ABCDwhere A = Leadframe Orientation where C = Color Optionand Package Dimension"UROK" = 632 nm Ultra Red "3" = Parallel Leadframe (3.10 X 3.95 mm) "NUOL" = 625 nm Red "5" = Parallel Leadframe ( 4.26 X 5.06 mm ) "UOL" = 625 nm Red "6" = Perpendicular Leadframe (4.70 X 5.70 mm) "TUOL" = 625 nm Red "7" = Parallel Leadframe ( 3.80 X 5.20 mm ) "SO" = 605 nm Orange "8" = Parallel Leadframe ( 4.56 X 5.20 mm ) "UYL" = 590 nm Amber "9" = Perpendicular Leadframe ( 4.60 X 5.60 mm )"TUYL" = 590 nm Amber "UG" = 573 nm Green"HTG / UTG" = 525 mm True Green "HB / UB" = 470 mm Bluewhere B = Package Color where D = Standoff Option "1" = color diffuse "N/A" = Without "2" = diffuse "-S" = With Stopper"3" = Matching Color "4" = Water ClearAbsolute Maximum Ratings at T A =25o C"UROK""UOL""SO""UYL""HTG""UTG""TUOL""HB""UB""TUYL""UG"mA mW mA Vo C oCV3012510050105100-40 to + 100N/A-30 to + 100300 NOTE1-40 to + 100N/A5-20 to + 855-20 to + 805-20 to + 85Storage TempSolder TemperaturePeak Forward Current(1/10 Duty Cycle 100 µs pulse width)Electrostatic Discharge ThresholdDC Forward Current Reverse Voltage (I R =100µA)Operating Temp Range Power Dissipation100030125100260o C for 5 seconds[ 1.5mm ( 0.06 in. ) below seating plane ]Parameter UnitsInGaNInGaN5-20 to + 80-30 to + 100100AlInGaPAlInGaP3070"NUOL"Notes: 1. Product resistance to electrostatic discharge (ESD) is measured by simulating ESD using a rapid avalanche energy test (RAET).The RAET procedures are designed to approximate the maximum ESD ratings shown. Seller gives no other assurances regarding the ability of Products to withstand ESD.MVL-63XXX AlInGaPDevice Selection Guide (Red, Orange, Amber, Green)Leads Lead Package with Frame Package Min.Typ.Color Stand-OffsOrientationDrawing MajorMinorNo A Yes B No A Yes B No A Yes B No A Yes B No A Yes B No A Yes B No A Yes B No A Yes B No A Yes B No A Yes B No A YesBInGaNDevice Selection Guide (True Green,Blue)No A Yes B No A Yes B No A Yes B No A Yes B No A Yes B No A Yes B No A Yes B No A YesBMVL-631TUYL-S MVL-632TUYL MVL-632TUYL-S Amber diffuse diffuse 400450400450MVL-634UG MVL-634UG-SGreen 573100150Water ClearParallel 110RedWater Clear OrangeWater Clear Amber Water Clearλd(nm)Part Number60300diffuse MVL-632UOL MVL-632UOL-S Red 625150MVL-633UOL Viewing TypicalIntensity Angle Color and Luminous 2θ1/2 (Degrees)Wavelength I F =20mA TypDominant Iv(mcd) at MVL-633UOL-S MVL-634UOL 150300MVL-634UOL-S 150300MVL-634NUOL 150300MVL-633SO Orange 605150300MVL-633SO-S MVL-634SO 150300MVL-634SO-S MVL-634UYL 170350MVL-634UYL-S Amber 590MVL-633UYL 170350MVL-633UYL-S MVL-631TUYL 60MVL-633HTG True Green 525350650MVL-633HTG-S MVL-634HTG 350650MVL-634HTG-S Parallel110GreenWater ClearBlueWater Clear Water ClearWater Clear200MVL-633HB-S MVL-634HB 100200MVL-634HB-S True Green 525250MVL-633HB Blue 470100450MVL-634UB 70140MVL-634UB-SBlue 47070140MVL-634UTG-S MVL-633UTG Water Clear MVL-634NUOL-S BlueMVL-633UB-S MVL-633UB GreenMVL-633UTG-S MVL-634UTG 250450MVL-65XXX AlInGaPDevice Selection Guide (Red, Orange, Amber, Green)LeadsLead Package with Frame Package Min.Typ.Color Stand-OffsOrientationDrawing MajorMinorNo E Yes F No E Yes F No E Yes F No E Yes F No E Yes F No E Yes F No E Yes F No E YesFInGaNDevice Selection Guide (True Green,Blue)No E Yes F No E Yes F No E Yes F No E YesFWater Clear Water Clear MVL-654SO 400MVL-654SO-S MVL-654UOL 400600MVL-654UOL-S 800Water Clear MVL-654UYL 500MVL-654UYL-S Viewing TypicalIntensity Angle Dominant Iv(mcd) at 2θ1/2 (Degrees)Part NumberWavelength I F =20mA Typλd(nm)Color and Luminous 30MVL-653UOL MVL-653UOL-S 400600Red150MVL-654UG 80MVL-654UG-SAmber400MVL-653SO MVL-653SO-S 500700Orange700Water Clear50MVL-653UYL MVL-653UYL-S MVL-653UG-S MVL-653UG 80150Green800MVL-653HTG 7501500MVL-653HTG-S Parallel MVL-653HB 200400BlueMVL-654HTG 750MVL-654HTG-S 1500Water Clear 400Water Clear5030ParallelGreenMVL-654HB 200MVL-654HB-SRed 625Orange 605Amber 590Green 573True Green 525Blue 470MVL-653HB-SMVL-66XXX AlInGaPDevice Selection Guide (Red, Orange, Amber)Leads Lead Package with Frame Package Min.Typ.Color Stand-OffsOrientationDrawing MajorMinorNo G Yes H No G Yes H No G Yes H No G Yes H No G Yes H No G Yes H No G Yes H No G Yes H No G Yes H No G Yes H No G YesHInGaNDevice Selection Guide (True Green,Blue)No G Yes H No G Yes H No G Yes H No G Yes H No G Yes H No G Yes H No G Yes H No G YesHMVL-664UROK 150300Ultra Red MVL-664UROK-S Red 625MVL-663TUOL-S Water Clear Red 200Perpendicular8040BlueWater ClearWater Clear Water ClearBlueGreenGreen200380MVL-663MB-S MVL-664MB 200380MVL-664MB-SMVL-663MB Blue 470MVL-664TUYL MVL-664TUYL-SMVL-664TUOL MVL-664TUOL-S MVL-663SO MVL-663UYL MVL-664SO-S MVL-663HTG 400800200400800MVL-663SO-S MVL-663TUOL 400800Amber Water ClearMVL-663HB-S MVL-663HB 100250Blue 470250MVL-664HB 100MVL-664HB-S MVL-664HTG 6001200MVL-664HTG-S True Green 525MVL-663HTG-S 6001200MVL-663MTG Dominant Iv(mcd) at 2θ1/2 (Degrees)Part NumberColor and Luminous Viewing TypicalIntensity Angle Wavelength I F =20mA Typλd(nm)40MVL-664UYL-S 400500MVL-664UOL MVL-663UOL MVL-663UOL-S MVL-664UOL-S MVL-664SO 250250MVL-664UYL 300Amber 590400MVL-663TUYL MVL-663UYL-S 300Orange 605MVL-663TUYL-S Water ClearAmber Water Clear 600Water Clear80400Water Clear600800Red Perpendicular500OrangeMVL-663MTG-S MVL-664MTG 7001300MVL-664MTG-S True Green 5257001300MVL-67XXX AlInGaPDevice Selection Guide (Red)LeadsLead Package with Frame Package Min.Typ.Color Stand-OffsOrientationDrawing MajorMinorNo C Yes D No C Yes D No C Yes D No C Yes D No C Yes D No C Yes D No C Yes D No C Yes D No C YesDInGaNDevice Selection Guide (True Green,Blue)No C Yes D No C Yes D No C Yes D No C Yes D No C Yes D No C YesDPart NumberParallelGreen GreenGreen diffuseWater ClearBlue diffuseWater ClearParallel Water Clear Red MVL-674HTG-S 1100250500500MVL-672TUOL-S Red 625250MVL-671TUOL 20025012001200250MVL-674HB-S13001300MVL-671HTG True Green 525600700MVL-671HTG-S Blue 470MVL-671UOL MVL-671UOL-S MVL-673UOL-S MVL-674UOL 250MVL-673UOL Viewing TypicalIntensity Angle Color and Luminous Dominant Iv(mcd) at 2θ1/2 (Degrees)Typλd(nm)Wavelength I F =20mA 100MVL-674HB 100MVL-673HB MVL-673HTG-S Blue Water Clear MVL-673HTG MVL-674HTG 700MVL-671HB MVL-671HB-S 100MVL-673HB-S 3070308030707030800800MVL-674UOL-S MVL-672TUOL MVL-673TUOL MVL-673TUOL-S 500MVL-674TUOL MVL-674TUOL-S MVL-671TUOL-S 500Red diffuse diffuse 500900900Red Water Clear Red diffuseMVL-673UG MVL-673UG-S MVL-674UG MVL-674UG-SGreen 5737070150150MVL-68XXX AlInGaPDevice Selection Guide (Red)LeadsLead Package with Frame Package Min.Typ.Color Stand-OffsOrientationDrawingMajorMinorNo I Yes J No I Yes J No I Yes J No I YesJInGaNDevice Selection Guide (True Green,Blue)No I Yes J No I Yes J No I Yes J No I Yes J No I Yes J No I Yes J No I Yes J No I YesJMVL-683HTG MVL-683HTG-S 3001300MVL-684HTG MVL-684HTG-S True Green 5256506501300100200MVL-682HB-S MVL-681HB-S MVL-682HB MVL-684HB 150300MVL-684HB-SMVL-683HB MVL-683HB-S 150601200MVL-681HTG-S MVL-681HB Blue 47010020030diffuseBlue diffuse diffuseBlue Water ClearGreen diffuse ParallelGreen Water Clear MVL-684UOL 400800MVL-682HTG 6001200MVL-682HTG-S MVL-681HTG 600MVL-684UOL-S400800Red MVL-683UOL-S MVL-683UOL Red diffuse Parallel diffuse60Water Clear30MVL-681UOL Red 625300600MVL-681UOL-S MVL-682UOL 300600MVL-682UOL-S Wavelength I F =20mA Typλd(nm)Dominant Iv(mcd) at 2θ1/2 (Degrees)Part NumberColor and Luminous Viewing TypicalIntensity AngleMVL-69XXX AlInGaPDevice Selection Guide (Red)Leads Lead Package with Frame Package Min.Typ.Color Stand-OffsOrientationDrawing MajorMinorNo K Yes L No K Yes L No K Yes L No K YesLMVL-693TUYL-S MVL-694TUYL MVL-694TUYL-SAmber 590MVL-694TUOL MVL-694TUOL-S MVL-693TUOL-S Red200025502510001000100020002000λd(nm)Wavelength I F =20mA 50Dominant Iv(mcd) at 2θ1/2 (Degrees)TypViewing TypicalIntensity Angle Color and Luminous Part NumberAmberWater ClearPerpendicularWater Clear 1000Red 625MVL-693TUOL 2000MVL-693TUYLElectrical/Optical Characteristics at T A =25o CParameterSymbolMin.Typ.Max.UnitsTest ConditionsTypical Viewing Angle Major/Minor MVL-63XXX 110/60 MVL-65XXX 50/30 MVL-66XXX 80/40 MVL-67XXX 70/30 MVL-68XXX 60/30 MVL-69XXX50/25Peak/Dominant Wavelength MVL-6XXUROK(-S)637/632Peak and Dominant of MVL-6XXNUOL(-S)630/625Wavelength of MVL-6XXUOL(-S)630/625Spectral MVL-6XXTUOL(-S)630/625Distribution at MVL-6XXSO(-S)610/605I F = 20 mAMVL-6XXUYL(-S)592/590 MVL-6XXTUYL(-S)592/590 MVL-6XXUG(-S)575/573 MVL-6XXUTG(-S)523/525 MVL-6XXHTG(-S)523/525 MVL-6XXUB(-S)468/470 MVL-6XXHB(-S)468/470Spectral HalfwidthUltra Red (λd = 632 nm)22Wavelength Width at Red (λd = 625 nm)17Spectral Orange (λd = 605 nm)13Distribution Amber (λd = 590 nm)171/2 Power Point Yellow Green (λd = 573 nm)20at I F = 20mATure Green (λd = 525 nm)40 Blue (λd = 470 nm)26Forward Voltage AlInGaP 1.6 2.1 2.6 InGaN 2.83.54.2Reverse Current AlInGaP100 InGaN "HTG" "HB"100 "UTG" "UB"10I F = 20mA2θ1/2DegreesV FVµAV R = 5Vλp / λdnmÄλ1/2nmI F = 20mAI RR E L A T I V E I N T E N S I T YWAVELENGTH(nm)Figure 1.RELATIVE INTENSITY012345020406080100R a d i a n t L u m i n o u s I n t e n s i t yForward Current I F (mA)FIG.4 RELATIVE LUMINOUS INTENSITYVS. FORWARD CURRENTF o r w a r d C u r r e n t I F (m A )F o r w a r d C u r r e n t I F (m A )Ambient Temperature T A (oC )FIG.3 FORWARD CURRENT VS. AMBIENT TEMPERATUREForward VoltageV F (V)FIG.2 FORWARD CURRENT VS. FORWARD VOLTAGE0102030405060020406080100InGa N AlInGaP10203040501.21.62.02.42.83.23.64.04.4InGaNAlInGaPR e l a t i v e L u m i n o u s I n t e n s i t y0.30.1R e l a t i v e L u m i n o u s I n t e n s i t y0.30.1R e l a t i v e L u m i n o u s In t e n s i t y0.30.100.51400425450475500525550575595620645670695AmberRed OrangeTure GreenGreenBlueR e l a t i v e L u m i n o u s I n t e n s i t y0.30.10.30.1R e l a t i v e L u m i n o u s I n t e n s i t yR e l a t i v e L u m i n o u s I n t e n s i t y0.30.1Unity Oval LEDs Bin TableLuminous IntensityBIN RANGEJ MAX 70MIN41100141199I V (mcd) @ I F =20mA5881115K L M N 225331851593563796S T U282130318434616529223981126230326R 163O P QUnity OVAL LED Bin CodesUnity OVAL LED Bin Codes。

Short Form SpecificationFebruary 2002 Revision 2.0PhilipsSemiconductorsCONTENTS1INTRODUCTION (3)1.1Scope (3)1.2Features (3)1.3Applications (3)2BLOCK DIAGRAM (4)3MF RC531 PINNING (5)3.1Pinning Diagram (5)3.2Pin Description (6)3.2.1Antenna Interface (6)3.2.2Analog Supply (6)3.2.3Digital Supply (6)3.2.4Auxillary Pin (6)3.2.5Reset Pin (7)3.2.6Oscillator (7)3.2.7MIFARE® Interface (7)3.2.8Parallel Interface (7)3.2.9SPI Compatible Interface (8)3.3Applications (8)3.3.1Connecting Different µController's (8)3.3.2Application Example (9)4MIFARE® CLASSIC RELATED ITEMS (10)4.1CRYPTO I: Card Authentication (10)4.1.1Initiating Card Authentication (10)4.1.2Second Part of Card Authentication (10)5ELECTRICAL SPECIFICATION (11)5.1DC Characteristics (11)5.2Start up Characteristics (11)MIFARE® is a registered trademark of Philips Electronics N.V1 INTRODUCTION1.1 ScopeThe MF RC531 is member of a new family of highly integrated reader ICs for contactless communication at 13.56 MHz. This reader IC family utilises an outstanding modulation and demodulation concept completely integrated for all kinds of passive contactless communication methods and protocols at 13.56 MHz. The MFRC531 is pin- compatible to the MF RC500, the MF RC530 and the SL RC400.The MF RC531 supports all layers of theISO14443 including the type A and type B communication schemeThe MF RC531 supports contactless communication using MIFARE® Higher Baudrates. The internal transmitter part is able to drive an antenna designed for proximity operating distance (up to 100 mm) directly without additional active circuitry.The receiver part provides a robust and efficient implementation of a demodulation and decoding circuitry for signals from ISO14443 compatible transponders.The digital part handles the complete ISO14443 framing and error detection (Parity & CRC). Additionally it supports the fast MIFARE® Classic security algorithm to authenticate MIFARE®Classic (e.g. MIFARE® Standard, MIFARE® Light) products.A comfortable parallel interface, which can be directly connected to any 8-bit µ-Processor gives high flexibility for the reader/terminal design. Additionally a SPI compatible interface is supported.1.2 Features•Highly integrated analog circuitry todemodulate and decode card response•Buffered output drivers to connect an antenna with minimum number of external components •Proximity operating distance (up to 100 mm)•Supports ISO 14443•Supports MIFARE® Dual Interface Card ICs and supports MIFARE® Classic protocol•Supports contactless communication with higher baudrates up to 424kHz •Crypto1 and secure non-volatile internal key memory•Pin-compatible to the MF RC500, MF RC530 and the SL RC400•Parallel µ-Processor interface with internal address latch and IRQ line•SPI compatible interface•Flexible interrupt handling•Automatic detection of the used µ-Processor interface type•Comfortable 64 byte send and receive FIFO-buffer•Hard reset with low power function•Power down mode per software •Programmable timer•Unique serial number•Bit- and byte-oriented framing•Internal oscillator buffer to connect 13.56 MHz quartz, optimised for low phase jitter• 3.3 V to 5 V operation for transmitter (antenna driver) in short range and proximityapplications• 3.3 V or 5V operation for the digital part1.3 ApplicationsThe MF RC531 is tailored to fit the requirements of various applications using contactless communication based on ISO/IEC 14443 standard where cost-effectiveness, small size, high performance with a single voltage supply are important.•Public transport terminals•Handheld terminals•On board units•Contactless PC terminals•Metering•Contactless public phones2 BLOCK DIAGRAMThe block diagram shows the main internal parts of the MF RC531.The parallel µController interface automatically detects the kind of 8 bit parallel interface connected to it. It includes a comfortable bi-directional FIFO buffer and a configurable interrupt output. This gives the flexibility to connect a variety of µC, even low cost devices, still meeting the requirements of high speed contactless transactions.Additionally a SPI compatible interface will be supported. The MF RC531 acts as a slave during the SPI communication. The SPI clock SCK has to be generated by the master. The SPI interface includes a comfortable bi-directional FIFO buffer. The Data processing part performs parallel serial conversion of the data. It supports framing including CRC and parity generation / checking. It operates in full transparent mode thus supporting all layers of ISO 14443 A& B.The status and control part allows configuration of the device to adapt to environmental influences and to adjust to operate with best performance. For communication with MIFARE® Classic products like MIFARE® Standard or MIFARE®Light a high speed CRYPTO 1 stream cipher unit and a secure non-volatile key memory is implemented.The analog circuit includes a transmitting part with a very low impedance bridge driver output. This allows an operating distance up to 100mm. The receiver is able to detect and decode even very weak responses. Due to a highly sophisticated implementation the receiver is no longer a limiting factor for the operating distance.3 MF RC531 PINNING3.1 Pinning DiagramThe device is packaged in a 32 pin SO-package.The device operates with 3 individual power supplies for best performance in terms of EMC behaviour and signal de-coupling. This gives outstanding RF performance and also maximum flexibility to adapt to different operating voltages of digital and analog part.3.2 Pin Description3.2.1 ANTENNA INTERFACEThe contactless antenna interface basically uses four pins:Name Type FunctionTX1, TX2O Buffered Antenna DriversVMID Analog Reference VoltageRX I Analog Antenna Input SignalTo drive the antenna the MF RC531 provides the energy carrier of 13.56 MHz through TX1 and TX2. This signal is modulated by the transmitting data according the register settings.The card responds with load modulation of the RF field. The resulting signal picked up by the antenna is coupled out from the antenna matching circuit and forwarded to the RX-pin. Inside the MF RC531 the receiver senses and demodulates the signal and processes it according to the register settings. Data is passed further on to the parallel interface where it is accessible by the µ-Controller.The MF RC531 uses a separate power supply for the driver stage.Name Type FunctionTVDD Power Transmitter Supply Voltage TGND Power Transmitter Supply Ground3.2.2 ANALOG SUPPLYFor best performance the MF RC531 analog part has a separate supply. It powers the oscillator, the analog demodulator and decoder circuitry.Name Type FunctionAVDD Power Analog Positive Supply Voltage AGND Power Analog Supply Ground3.2.3 DIGITAL SUPPLYThe MF RC531 uses a separate digital supply.Name Type FunctionDVDD Power Digital Positive Supply Voltage DGND Power Digital Supply Ground3.2.4 AUXILLARY PINInternal signals may be selected to drive this pin. It is used for design-in support and test purpose.3.2.5 RESET PINThe reset pin disables internal current sources and clocks and detaches the MF RC531 virtually from the µC bus. If RST is released, the MF RC531 executes the power up sequence.3.2.6 OSCILLATORName Type FunctionXIN I Oscillator Buffer InputXOUT O Oscillator Buffer OutputThe very fast on-chip oscillator buffer operates with a 13.56 MHz crystal connected to XIN and XOUT. If the device shall operate with an external clock it may be applied to pin XIN.3.2.7 MIFARE® INTERFACEThe MF RC531 supports the active antenna concept of MIFARE®. It may handles the base-band signals NPAUSE and KOMP of MIFARE® Core Modules (MF CMxxx) at the pins MFIN and MFOUT.Name Type FunctionMFIN I with Schmitt Trigger MIFARE® Interface InputMFOUT O MIFARE® Interface OutputThe MIFARE® interface may be used to communicate with either the analog or the digital part of the MFRC531 separately in the following ways:•The analog circuit may be used stand-alone via the MIFARE® interface. In that case MFIN will be connected to the externally generated NPAUSE signal. The MFOUT pin provides the KOMP signal.•The digital circuit may be used to drive an external analog circuit via the MIFARE® interface. In that case the MFOUT pin provides the internally generated NPAUSE signal and MFIN will be connected to the KOMP signal from the outside.3.2.8 PARALLEL INTERFACE16 pins control the parallel interface:Name Type FunctionD0 … D7I/O with Schmitt Trigger Bi-directional Data BusA0 … A2I/O with Schmitt Trigger Address LinesNWR / RNW I/O with Schmitt Trigger Not Write / Read Not WriteNRD / NDS I/O with Schmitt Trigger Not Read / Not Data StrobeNCS I/O with Schmitt Trigger Not Chip SelectALE I/O with Schmitt Trigger Address Latch EnableIRQ O Interrupt Request3.2.9 SPI COMPATIBLE INTERFACE4 pins control the SPI compatible interface.Name Type FunctionA0I/O with Schmitt Trigger MOSI, master to slavecommunicationA2I/O with Schmitt Trigger SCK, clock to be generated by themasterD0I/O with Schmitt Trigger MISO, slave to mastercommunicationALE I/O with Schmitt Trigger NSS, enables the SPIcommunication3.3 Applications3.3.1 CONNECTING DIFFERENT µCONTROLLER'SThe MF RC531 supports different parallel µC interfaces and a SPI compatible interface. An intelligent auto-detection logic automatically adapts the parallel interface to the respective bus system. Selection of the device is performed with signal NCS.To connect µ-Controllers using separated address and data bus pin ALE has to be connected to DVDD.To connect µ-Controllers using multiplexed address and data bus pin ALE has to be connected to the signal ALE of the µ-ControllerTo connect µ-Controllers using RNW and NDS (instead of NWR and NRD) the µ-Controller’s RNW has to be connected to pin NWR and NDS to pin NRD.3.3.2 APPLICATION EXAMPLE4 MIFARE® CLASSIC RELATED ITEMS4.1 CRYPTO I: Card AuthenticationFor correct authentication of MIFARE® Classic products the fast CRYPTO 1 stream cipher is available. The corresponding keys have to be programmed into the secure non-volatile key memory of the MF RC531.Only two commands need to be sent by application software to turn on CRYPTO 1 secured communication.4.1.1 INITIATING CARD AUTHENTICATION The correct key for the authentication has to be selected from the secure internal non-volatile key memory and loaded into the internal CRYPTO1 register. Next the authentication command is transmitted to the card.After receiving the first message token from the card, the µ-Controller has to check the communication status flags. If communication so far has been successful the second part of the authentication procedure can be started.4.1.2 SECOND PART OF CARD AUTHENTICATIONData to be transmitted to the card in this phase are generated automatically by the internal CRYPTO 1 unit inside the MF RC531. To request this action the according command has to be triggered.The card will respond with the second message token. Then the communication status flags have to be checked by the µ-Controller. If authentication has been successful further communication with a MIFARE® Classic card continues CRYPTO 1 enciphered.Philips Semiconductors Short From Specification Rev. 2.0 February 2002ISO 14443 Reader IC MF RC53111PUBLIC5 ELECTRICAL SPECIFICATION 5.1 DC Characteristics SYMBOL PARAMETERCONDITIONSMINTYPMAXUNITVoltage Supply 4.5 5.0 5.5VDVDD Digital Supply Voltage 3.0 3.3 3.6AVDD Analog Supply Voltage 4.5 5.0 5.5V TVDDTransmitter Supply Voltage3.35.05.5V Current Consumption I DVDD Operating Digital Supply Current Idle Command6mA I AVDD Operating Analog Supply Current Idle Command,Receiver On 25mA I TVDDOperating Buffered Antenna Driver Supply Currentcontinuous wave50mA5.2 Start up Characteristics ModeCONDITIONSCurrent UNITTimeUNITStartup times and current consumption Power on--< 1000µs Hard Reset via Reset Pin 1µA < 1000µs Soft Reset via Register Setting1µA < 1000µsDefinitionsData sheet statusObjective specification This data sheet contains target or goal specifications for product development. Preliminary specification This data sheet contains preliminary data; supplementary data may bepublished later.Product specification This data sheet contains final product specifications.Limiting valuesLimiting values given are in accordance with the Absolute Maximum Rating System (IEC 134). Stress above one or more of the limiting values may cause permanent damage to the device. These are stress ratings only and operation of the device at these or at any other conditions above those given in the Characteristics section of the specification is not implied. Exposure to limiting values for extended periods may affect device reliability.Application informationWhere application information is given, it is advisory and does not form part of the specification.Life support applicationsThese products are not designed for use in life support appliances, devices, or systems where malfunction of these products can reasonably be expected to result in personal injury. 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Pasica 5/v, 11000 BEOGRAD,Tel. +38111 625 344, Fax. +38111 635 777Published by:Philips Semiconductors Gratkorn GmbH, Mikron-Weg 1, A-8101 Gratkorn, Austria Fax: +43 3124 299 - 270 For all other countries apply to: Philips Semiconductors, Marketing & Sales Communications, Internet: Building BE-p, P.O.Box 218, 5600 MD EINDHOVEN, The Netherlands, Fax: +3140 27 24825© Philips Electronics N.V. 1997 SCB52 All rights are reserved. Reproduction in whole or in part is prohibited without the prior written consent of the copyright owner.The information presented in this document does not form part of any quotation or contract, is believed to be accurate and reliable and may be changed without any notice. No liability will be accepted by the publisher for any consequence of its use. Publication thereof does not convey nor imply any license under patent- or other industrial or intellectual property rights.PhilipsSemiconductors。

TS8 E MBER®EM3X M ODULE T ECHNICAL S PECIFICATIONSilicon Labs’ EM3x development kits contain various modules designed around the EM3x family of ICs. All of these modules are designed and sold by Silicon Labs’ module partners Telegesis (UK) Limited and California Eastern Laboratories (CEL). The module designs allow them to be integrated into any product without the need for RF experience and expertise. Utilizing stacks such as Silicon Labs’ certified ZigBee network stack EmberZNet, these modules enable a developer to add powerful wireless networking capability to products and quickly bring them to market.This document provides the technical specification of the EM3x modules on its Silicon Labs-specific carrier board. For more information on the other Telegesis modules, contact Telegesis, Ltd directly at . For more information on other CEL modules, contact CEL directly at .New in This RevisionAdded CEL CE compliance information.Contents1EM3x Module Definitions (2)2EM3x Module Features (3)3Performance Characteristics (3)4EM3x Configurations (5)5Mechanical Details (7)5.1EM3x Module Interface Connector (8)TS81 EM3x Module DefinitionsTo accommodate the requirements of the different markets, Telegesis and CEL have developed a series of pin-compatible modules based on the Ember EM341, EM346, EM357, and EM3588 chipsets. Table 1 defines the Telegesis, CEL, and Silicon Labs part numbers for each module as well as describes the differences (Power Amplifier (PA), Low Noise Amplifier (LNA), and RF connection) between each module.Table 1. Silicon Labs and Module Partner Part NumbersSilicon Labs P/N Silicon Labs OrderablePart Number (OPN)EM3xICModulePartnerModule Partner P/N(Module only)RF ConnectionPA /LNA?(LongRange)110-0740-000 EM341-MOD-ANT-C EM341 CEL ZICM341SP0-1 Antenna No 110-0741-000 EM341-MOD-RF-C EM341 CEL ZICM341SP0-1C Connector No 110-0742-000 EM346-MOD-ANT-C EM346 CEL ZICM346SP0-1 Antenna No 110-0743-000 EM346-MOD-RF-C EM346 CEL ZICM346SP0-1C Connector No 110-0720-000 EM357-MOD-ANT-T EM357 Telegesis ETRX357 SMT Antenna No 110-0721-000 EM357-MOD-RF-T EM357 Telegesis ETRX357HR Mini-RF Connector No 110-0722-000 EM357-MOD-LR-RF-T EM357 Telegesis ETRX357HR-LRS Mini-RF Connector Yes 110-0723-000 EM357-MOD-LR-ANT-T EM357 Telegesis ETRX357-LRS SMT Antenna Yes 110-0730-000 EM357-MOD-ANT-C EM357 CEL ZICM357SP0-1 SMT Antenna No 110-0731-000 EM357-MOD-RF-C EM357 CEL ZICM357SP0-1C Mini-RF Connector No 110-0732-000 EM357-MOD-LR-RF-C EM357 CEL ZICM357SP2-1C Mini-RF Connector Yes 110-0733-000 EM357-MOD-LR-ANT-C EM357 CEL ZICM357SP2-1 SMT Antenna Yes 110-0734-000 EM3588-M-AN-C EM3588 CEL ZICM3588SP0-1 SMT Antenna No 110-0735-000 EM3588-MOD-RF-C EM3588 CEL ZICM3588SP0-1C Mini-RF Connector No 110-0736-000 EM3588-MLR-RF-C EM3588 CEL ZICM3588SP2-1C Mini-RF Connector Yes 110-0737-000 EM3588-MLR-AN-C EM3588 CEL ZICM3588SP2-1 SMT Antenna YesAll of these modules are available from Telegesis and CEL. Silicon Labs provides the CEL EM357 and EM3588 module types with the EM35x Development Kit (part number EM35X-DEV) and the EM341 and EM346 modules with the EM34x Development Kit (part number EM34X-DEV).For modules whose RF connection is a mini-RF connector, an RF adapter cable (Tyco/Amp part number 2032440-1) can be used to interface the module to external test equipment. One of these RF adapter cables is included with the development kits.To connect to the EM35x breakout board (Silicon Labs P/N: 130-0680-000), each module shown in Table 1 is soldered to a small carrier board. The carrier board connector is discussed in section 5.1, EM3x Module Interface Connector.TS82 EM3x Module FeaturesModule features:•Small form factor, SMT module (25 mm x 19 mm)•Side castellation for easy soldering and inspection•Industry standard JTAG Programming and real-time network level debugging via the Packet Trace Port.•Wide supply voltage range (2.1 to 3.6 V)•Low sleep current (< 1 µA for EM35x and EM34x, < 2 µA for EM3588)•Access to all EM3x GPIO from the System-on-Chip (SoC)•Access to either a U.FL RF Connector or a SMT antenna allows flexibility in antenna selection process •FCC complianceTelegesis:FCC ID: S4GEM35XACEL:FCC ID: W7Z-ZICM357SPOFCC ID: W7Z-ZICM357SP2•CE complianceTelegesis:Radio: EN300 328 v1.7.1EMC: EN301 489-17 v2.1.1Safety: EN60950-1CELRadio: EN 300 328 V1.8.1 (2006 ‐ 2012)EMC: EN 301 489‐1 V1.8.1, V1.9.1EN 301 489‐17 V2.2.1•Long Range versions with a link budget of up to 124 dBModule with carrier board features:•Access to the Packet Trace Port connector (allows for direct connection to the Ember Debug Adapter (ISA3) for programming and debugging)•Two debug LEDs•Access to all EM3x GPIO through a robust 0.05” pitch connector3 Performance CharacteristicsThis section describes the characteristics of the module with carrier board. For more information on the EM35x and EM34x SoC performance, refer to the EM35x, EM358x, EM341 and EM346 data sheets.Unless specified, the data within each of the tables was gathered at room temperature (25 °C) and 3.0 V source potential. Table 2 summarizes the recommended operating conditions for the modules.Table 2. Recommended Operating Conditions for the EM3x ModuleParameter Min Typ Max Unit VDD supply 2.1 — 3.6 VRF Input Frequency 2405 — 2480 MHzRF Input Power (at RF Port) — — 0 dBm Operating Temperature Range -40 — 85 °CTS8Table 3 summarizes the DC characteristics at 25 °C and VDD of 3 V of the EM3x Module.Table 3. DC Characteristics of the EM3x ModuleParameter Min Typ Max Unit VDD supply 2.1 — 3.6 V Sleep Current (RC oscillator) — 0.4 — µA Active Current (TX)TX, Normal Mode, +3 dBm — 31 — mA TX, Boost Mode, +8 dBm — 39 — mA TX, Normal Mode, 0 dBm — 28.5 —Active Current (RX)RX, Normal Mode — 26 — mA RX, Boost Mode — 27 — mA Wake Time from Deep Sleep — 100 — us Shutdown Time — 5 — usTable 4 summarizes the digital I/Os at VCC = 3 V and 25 °C of the EM3x Module.Table 4. Digital I/O Characteristics of the EM3x ModuleParameter Min Typ Max Unit Input Logic ThresholdSchmitt threshold (high to low) 0.42 x VDD — 0.5 x VDD V Schmitt threshold (low to high) 0.62 x VDD — 0.8 x VDD V Input CurrentLogic Low — — -0.5 µA Logic High — — 0.5 µA Output Voltage — — — Logic Low 0 — 0.18 x VDD V Logic High 0.82 x VDD — VDD V Output CurrentSource, Standard Pad — — 4 mA Sink, Standard Pad — — 4 mA Source, High Current Pad — — 8 mA Sink, High Current Pad — — 8 mA Total Output Current — — 40 mATS8 Table 5 summarizes the RF parameters of the EM3x Module.Table 5. RF Characteristics of the EM3x ModuleParameter Min Typ Max Unit Frequency Range 2405 — 2480 MHz Channel Spacing — 5 — MHzRX Sensitivity (1% PER, 20-byte packet)Normal Mode — -100 -94 dBm Boost Mode — -101 -95 dBm Adjacent Channel RejectionHigh Side — 35 — dB Low Side — 35 — dB 2nd High Side — 43 — dB 2nd Low Side — 43 — dB All other channels — 40 — dBTX Power (Maximum)Boost Mode — 8 — dBm Normal Mode — 3 — dBm Error Vector Magnitude (Offset EVM) (per IEEE 802.15.4-2003) — 5 15 %PSD (3.5 MHz from carrier)Relative -20 — — dB Absolute -30 — — dBm4 EM3x ConfigurationsThe IC on the EM3x Module can be set to different RF frequency channels as well as different power levels. When using the nodetest application on the module, the frequency channels and output power levels can be configured through a command line interface (CLI).In order to configure the output power, the setTXPower command can be used. Table 6 demonstrates the setTXPower command and the expected power output. Note that these are the typical expected power output levels based on the performance of the EM3x IC and actual results are dependent on the module provider design implementation.Note: Table 6 refers to the non-PA versions of the modules. For the version with a PA, the output power should be set to -5 dBm in order to achieve +20 dBm output power.Table 6: List of TX output powers when using SetTxPowerSetTxPower [signed hexadecimal] Output Power(dBm)SetTxPower 9 +3 SetTxPower 8 +8 SetTxPower 7 +7 SetTxPower 6 +6 SetTxPower 5 +5TS8SetTxPower [signed hexadecimal] Output Power(dBm)SetTxPower 4 +4 SetTxPower 3 +3 SetTxPower 2 +2 SetTxPower 1 +1 SetTxPower 0 0 SetTxPower -1 -1 SetTxPower -2 -2 SetTxPower -3 -3 SetTxPower -4 -4 SetTxPower -5 -5 SetTxPower -6 -6 SetTxPower -7 -7 SetTxPower -8 -8 SetTxPower -9 -9 SetTxPower –a -9 SetTxPower –b -11 SetTxPower –c -12 SetTxPower –d -12 SetTxPower –e -14 SetTxPower –f -14 SetTxPower -10 -14 SetTxPower -11 -17 SetTxPower -12 -17 SetTxPower -13 -17 SetTxPower -14 -20 SetTxPower -15 -20 SetTxPower -16 -20 SetTxPower -17 -20TS8 To change the channel, the setChannel command can be used (assuming nodetest application is on the device). Table 7 lists the valid parameters to be used with setChannel command.Table 7: List of setChannel values for EM3xsetChannel (decimal)CenterFrequency (GHz)radioChannel(decimal)CenterFrequency (GHz)11 2.405 19 2.44512 2.410 20 2.45013 2.415 21 2.45514 2.420 22 2.46015 2.425 23 2.46516 2.430 24 2.47017 2.435 25 2.47518 2.440 26 2.4805 Mechanical DetailsFigure 1 illustrates the ZICM35x Module carrier board from CEL, while Figure 2 illustrates the ETRX35x Module from Telegesis on a carrier board.Figure 1. CEL ZICM35x Module Carrier BoardTS8Figure 2. Telegesis ETRX35x Module with Carrier Board5.1 EM3x Module Interface ConnectorTwo single-row, 0.05” pitch, connectors make up the EM3x module interface to the EM35x breakout board. In addition, two single-row, guide connectors on the EM35x breakout board assist with connecting the EM3x module to the breakout board. The board-to-board connector scheme allows access to all EM3x GPIO as well as nRESET and the JCLK signals. The connector is illustrated in Figure 3, while the connector dimensions are listed in Figure 4.Figure 3. Board-to-board connector for the EM3x module (top view)22 mm37.5 mm123456789101112131415161718193332313029282726252423222120E M 35x _P C 5E M 35x _P C 6E M 35x _P C 7E M 35x _P A 7E M 35x _P B 3n R E S E TE M 35x _P B 4E M 35x _P A 0E M 35x _P A 1E M 35x _P A 2E M 35x _P A 3G N DE M 35x _P A 4E M 35x _P A 5E M 35x _P A 6E M 35x _P B 1E M 35x _P B 2G N D G N DG N DV D D _3V _M O DG N DE M 35x _P B 5E M 35x _P B 6E M 35x _P B 7E M 35x _P C 0E M 35x _P C 1E M 35x _P B 0E M 35x _P C 4E M 35x _P C 3E M 35x _P C 2J C L K G N DTS8Figure 4. Board-to-Board Connector Dimensions for the EM3x Module (top view)Table 8 describes the pinout and signal names on the connector.For more information on the alternate functions of the GPIO connector, refer to the EM35x Data Sheet.Table 8. Pinout and Signal Names of the Interface Connector Pin # Signal name Direction1Description1 GND Power Ground Connection2 PC5 I/O EM3x GPIO3 PC6 I/O EM3x GPIO4 PC7 I/O EM3x GPIO5 PA7 I/O EM3x GPIO6 PB3 I/O EM3x GPIO7 nRESET I/O Active low chip reset (internal pull-up on EM3x)8 PB4 I/O EM3x GPIO9 PA0 I/O EM3x GPIO10 PA1 I/O EM3x GPIO11 PA2 I/O EM3x GPIO12 PA3 I/O EM3x GPIO13 GND Power Ground Connection14 PA4 I/O EM3x GPIO15 PA5 I/O EM3x GPIO16 PA6 I/O EM3x GPIO (NC on EM346 module)17 PB1 I/O EM3x GPIO18 PB2 I/O EM3x GPIO19 GND Power Ground connection20 GND Power Ground connection21 JCLK Input JTAG interface, serial clock22 PC2 I/O EM3x GPIO23 PC3 I/O EM3x GPIOTS8Pin # Signal name Direction1Description24 PC4 I/O EM3x GPIO25 PB0 I/O EM3x GPIO26 PC1 I/O EM3x GPIO27 PC0 I/O EM3x GPIO28 PB7 I/O EM3x GPIO (NC on EM346 module)29 PB6 I/O EM3x GPIO (NC on EM346 module)30 PB5 I/O EM3x GPIO (NC on EM346 module)31 GND Power Ground connection32 VDD Power 2.1 to 3.6 V Module Power Domain33 GND Power Ground connection1with respect to the EM3x ModuleTS8Rev. 1.411 C ONTACT I NFORMATIONSilicon Laboratories Inc.400 West Cesar ChavezAustin, TX 78701Tel: 1+(512) 416-8500Fax: 1+(512) 416-9669Toll Free: 1+(877) 444-3032 For additional information please visit the Silicon Labs Technical Support page:/support/Pages/default.aspxPatent NoticeSilicon Labs invests in research and development to help our customers differentiate in the market with innovative low-power, small size, analog-intensive mixed-signal solutions. Silicon Labs' extensive patent portfolio is a testament to our unique approach and world-class engineering team. The information in this document is believed to be accurate in all respects at the time of publication but is subject to change without notice. Silicon Laboratories assumes no responsibility for errors and omissions, and disclaims responsibility for any consequences resulting from the use of information included herein. Additionally, Silicon Laboratories assumes no responsibility for the functioning of undescribed features or parameters. Silicon Laboratories reserves the right to make changes without further notice. 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FSM FUNCTIONAL SAFETY MANAGEMENTThese products are for use as sub-systems within a Safety System conforming to the requirements ofIEC61508:2010 and enable a Safety Integrity Level of SIL 1 (MTL x582B modules) or SIL 2 (MTLx531 modules)to be achieved for the instrument loop.Eaton Electric Ltd, Luton is a certified Functional Safety Management company meeting the requirements ofIEC61508 Part1:clause 6* Refer to content of this manual for details2SMx 531-82 Rev4This manual supports the application of the products in functional safety related loops. It must be used in conjunction with other supporting documents to achieve correct installation, commissioning and operation.In the interest of further technical developments, MTL reserve the right to make design changes.Contents 1 Introduction 3 1.1 Application and function 3 1.2 Variant description 3 2 System configuration 4 2.1 Associated system components 5 3 Selection of product and implications 6 4 Assessment of functional safety 6 4.1 Hardware safety integrity 6 4.1.1 MTLx531 Assessment 6 4.1.2 MTL5582 Assessment 7 4.2 Systematic Safety Integrity 8 4.3 SIL capability 8 4.4 EMC 8 4.5 Environmental 8 5 Installation 9 6 Maintenance 9 7 Appendices 10 7.1 Appendix A: Summary of applicable standards 10 7.2 Appendix B: Proof T est Procedure, MTL45/5500 Vibration Probe Interfaces 10Machine Monitor Interfaces† These modules have an inherent fault tolerance of 0.* The maximum SIL attainment is limited by The Systemic Capability,and is independent of Hardware Fault Tolerance. Refer to section 4.1 Introduction1.1 Application and functionThe MTL4531 and MTL5531 are single channel isolator modules which enable vibration sensors and probeslocated in a hazardous area to be connected to monitoring systems in the safe area. These modules aredesigned and assessed according to IEC 61508 for use in Safety instrument systems up to SIL2.For resistance temperature detectors, RTDs, the MTL4582B and MTL5582B module is a single channelisolator module that repeats the resistance value from hazardous to safe area. The modules are designed andassessed according to IEC 61508 for use in safety instrumented systems up to SIL1.The vibration modules are compatible with three-wire eddy-current probes and accelerometers or two-wirecurrent sensors. The RTD isolator is compatible with two, three or four-wire devices. There are configurationswitches on the modules that define the type and arrangement of the connected sensors.These modules are members of the MTL4500 and MTL5500 Series of products.MTL4500 AND 5500 SERIES1.2 Variant DescriptionFunctionally the MTL4500 and MTL5500 modules are the same but differ in the following way:- the MTL4500 modules are designed for backplane mounted applications- the MTL5500 modules are designed for DIN rail mounting.In both models the hazardous area field-wiring connections (terminals 1-3, and 4-6) are made through theremovable blue connectors on the top of the modules, but the safe area and power connections for theMTL4531 modules are made through the connector on the base, while the MTL5531/MTL5582 uses theremovable grey connectors on the top and side of the module.Note that the safe-area connection terminal numbers differ between the backplane and DIN-rail mounting models.The specific models covered by this manual are:MTL4531 and MTL5531 vibration transducer interfaceMTL4582 and MTL5582B resistance isolatorsNote: To avoid repetition, further use of MTLx531 in this document can be understood to include both DIN-railand backplane models. Individual model numbers will be used only where there is a need to distinguish them.SMx 531-82 Rev432 System configurationAn MTLx531 or MTLx582B module may be used in a single-channel (1oo1) safety instrumented function upto SIL1 where the safe state is the output de-energised. The worked example in this manual is forSIL1 application.The figures below show the system configuration and specifies the interfaces to the safety related and nonsafety-related system components. It does not aim to show all details of the internal module structure, but isintended to support understanding for the application.4SMx 531-82 Rev4The MTLx531 modules are designed to power a vibration sensor in the hazardous area and repeat themeasurement signal as a voltage output to a monitoring system in the safe area. Three-wire or two-wiresensors can be connected to the modules and the configuration switches accessible on the edge of themodule set to the required state. When used with a two-wire current sensor, field terminals 1 and 2 must belinked together .The MTLx582B connects to a 2-, 3-, or 4-wire resistance temperature device (RTD) or other resistance sensorlocated in a hazardous area, isolates it and repeats the resistance to a monitoring system in the safe area.The module is intended typically (but not exclusively) for use with Pt100 3- wire RTDs, and operates over therange of 10 ohms to 400 ohms. Switches located on edge of the module allow selection of 2-, 3-, or 4-wire RTD connection. The number of wires which can be connected on the safe-area side of the unit is independent ofthe number of wires which can be connected on the hazardous-area side. The module drives upscale in thecase of open-circuit detection.The yellow area in the diagrams shows the safety-relevant system connection when using these products insafety-related applications.2.1 Associated System ComponentsThere are many parallels between the loop components that must be assessed for intrinsic safety as well asfunctional safety, where in both situations the contribution of each part is considered in relation to the whole.The MTLx531 module is a component in the signal path between safety-related sensors and safety relatedmonitoring systems.The sensor and any associated amplifier must be suitable for the process and have been assessed and verifiedfor use in functional safety applications, as well as its certification for hazardous area mounting.Similarly, the RTD sensors connected to the MTLx582B module must be selected for their suitability for theprocess and their use in a functional safety application, even though they are regarded as ‘simple apparatus’with regard to intrinsic safety.SMx 531-82 Rev453 Selection of product and implicationsFor the MTLx531 modules there is only one function: to repeat the signal voltage and frequency from avibration sensor, powered through the module, into the input channel of a vibration monitoring system.This may be used within a safety function, with power off as the safe state. The input modules of the vibrationmonitoring system must be able to diagnose when the signal voltage is outside of the expected measuringrange and take appropriate action to declare the signal as ‘bad’.This is considering the hardware failure rate only and the user must consider the systematic implicationsof applying this equipment in safety functions where a number of safety-related subsystem channels areimplemented to achieve the requisite hardware fault tolerance.The MTLx582B transfers the value of resistance from its measuring circuit to the output terminals within a giventolerance. Here also, the requirement for the receiving system is that it must diagnose when the resistancemeasured at the module output terminals is outside of the expected range and take appropriate action.When using these modules within a safety instrumented function it is, of course, a requirement that thesensors have been assessed and verified for such an application and the failure rate data is available for use inthe relevant safety calculations.4 Assessment of functional safetyThe design features and the techniques/measures used to prevent systematic faults are suitable for the use inmodules in safety functions up to SIL1 (MTLx582B) or SIL2 (MTLx531).It is assumed that the module is powered from a nominal 24Vdc supply. The product has been assumed tooperate at a maximum ambient temperature of 45°C under normal conditions.4.1 Hardware safety integrity4.1.1 MTLx531 AssessmentThe hardware assessment shows that MTLx531 vibration interfaces:• have a hardware fault tolerance of 0• are classified as Type A devices (“Non-complex” component with well-defined failure modes)• there are no internal diagnostic elements of these products.The definitions for product failure of the modules at an ambient temperature of 45°C weredetermined as follows:-• FITs means failures per 109 hours or failures per thousand million hours.• Reliability data for this analysis is taken from IEC TR 62380:2004 Reliability Data Handbook.• Failure mode distributions are taken principally from IEC 62061:2005 Safety of Machinery.6SMx 531-82 Rev4Example of use in a safety functionIn this example for a module the application context is assumed to be:• the safety function is to repeat voltage within ±2% over a voltage range of -0.5V to -18Vand a frequency range of DC to 15kHz.• the monitoring system will diagnose voltages outside the range of -0.5V to -18V as faults and take appropriate actionThe failure modes shown above can then be defined as :The failure rates for these categories are then (FITs)In this example, the safe failure fraction is 60%.4.1.2 MTL5582 AssessmentThe hardware assessment shows that MTLx582B resitance isolators:• have a hardware fault tolerance of 0• are classified as Type A devices (“Non-complex”component with well-defined failure modes)• there are no internal diagnostic elements of these products.The definitions for product failure of the modules at an ambient temperature of 45°C weredetermined as follows:-Example of use in a safety functionIn this example for a module the application context is assumed to be:• the isolator safety function is to repeat resistance within ±4 Ω.• the monitoring system will diagnose resistances above 400 Ω and below 10 Ω as faults andtake appropriate actionSMx 531-82 Rev47The failure modes shown above can then be defined as :The failure rates for these categories are then (FITs)In this example, the safe failure fraction is 78%.4.2 Systematic Safety Integrity4.2.1 MTLx531 modulesThe design features and the techniques/measures used to prevent systematic faults give the MTLx531 asystematic safety integrity measure of SC 2.Note: Revision 3 this manual inferred a systematic safety integrity for MTLx531 modules of SC 1. Subsequentre-assessment of the design features and techniques/measures used to avoid systematic faults has allowed themodules to be awarded SC 2. No change has been made to the product designs; the SC 2 systematic integritymeasure therefore applies retrospectively to MTLx531 modules installed under previous revisions of thismanual.4.2.2 MTLx582B modulesThe design features and the techniques/measures used to prevent systematic faults give the MTLx582Bmodules a systematic safety integrity measure of SC1.4.3 SIL capability4.3.1 MTLx531 modulesConsidering both the hardware safety integrity and the systematic capability, this allows MTLx531 modules tobe used in SIL 2 safety functions in a simplex architecture (HFT = 0).4.3.2 MTLx582B modulesConsidering both the hardware safety integrity and the systematic capability, this allows MTLx582B modulesto be used in SIL 1 safety functions in a simplex architecture (HFT = 0). Note that the SIL capability is limited bythe systematic capability and is independent of the hardware fault tolerance.4.4 EMCThe MTL4500 and MTL5500 modules are designed for operation in normal industrial electromagneticenvironment but, to support good practice, modules should be mounted without being subjected to undueconducted or radiated interference, see Appendix A for applicable standards and levels.It is important that the effect of electromagnetic interference on the operation of any safety function is reducedwhere possible. For this reason it is recommended that the cable connections from the logic solver to theisolator modules be a maximum of 30 metres and are not exposed to possible induced surges, keeping theminside a protected environment.Any maintenance or other testing activity should only be conducted when the field loop is not in service, toavoid any possibility of introducing a transient change in the field signal.8SMx 531-82 Rev44.5 EnvironmentalThe MTL4500 and MTL5500 modules operate over the temperature range from -20°C to +60°C, and at up to95% non-condensing relative humidity.The modules are intended to be mounted in a normal industrial environment without excessive vibration, asspecified for the MTL4500 & MTL5500 product ranges. See Appendix A for applicable standards and levels.Continued reliable operation will be assured if the exposure to temperature and vibration are within the valuesgiven in the specification.5 InstallationThere are two particular aspects of safety that must be considered when installing the MTL4500 or MTL5500modules and these are:• Functional safety• Intrinsic safetyReference must be made to the relevant sections within the instruction manual for MTL4500 Series (INM4500)or MTL5500 Series (INM5500) which contain basic guides for the installation of the interface equipment tomeet the requirements of intrinsic safety. In many countries there are specific codes of practice, together withindustry guidelines, which must also be adhered to.Provided that these installation requirements are followed then there are no additional factors to meet theneeds of applying the products for functional safety use.To guard against the effects of dust and water the modules should be mounted in an enclosure providing atleast IP54 protection degree, or the location of mounting should provide equivalent protection such as inside anequipment cabinet.In applications using MTL4500 Series, where the environment has a high humidity, the mounting backplanesshould be specified to include conformal coating.6 MaintenanceTo follow the guidelines pertaining to operation and maintenance of intrinsically safe equipment in a hazardousarea, yearly periodic audits of the installation are required by the various codes of practice.In addition, proof-testing of the loop operation to conform with functional safety requirements should becarried out at the intervals determined by safety case assessment.Proof testing must be carried out according to the application requirements, but it is recommended that this becarried out at least once every three years.Refer to Appendix B for the proof testing procedure of the MTLx531 or MTLx582B modules.Note that there may also be specific requirements laid down in the E/E/PE operational maintenance procedurefor the complete installation.If an MTL4500 or MTL5500 module is found to be faulty during commissioning or during the normal lifetimeof the product then such failures should be reported to MTL. When appropriate, a Customer Incident Report(CIR) will be notified to enable the return of the unit to the factory for analysis. If the unit is within the warrantyperiod then a replacement unit will be sent.Consideration should be made of the normal lifetime for a device of this type which would be in the region often years.SMx 531-82 Rev497 Appendices7.1 Appendix A: Summary of applicable standards and recommendationsThe MTL4531 and MTL5531 are single channel isolator modules which enable vibration sensors andprobes located in a hazardous area to be connected to monitoring systems in the safe area. For resistancetemperature detectors, RTDs, the MTL5582 module is a single channel isolator module that repeats theresistance value from hazardous to safe area. The modules are also designed and assessed according to IEC61508 for use in safety instrumented systems up to SIL1.7.2 Appendix B: Proof T est Procedures7.2.1 MTLx531 Proof T est ProcedureFor MTL5531, remove the module from the target system and make the safe and hazardous area connectionsas shown below:Test circuit for MTL553110SMx 531-82 Rev4Measure the voltage on terminal 3 with respect to terminal 1; this should be >19V. Vary the potentiometersetting and check that the reading on voltmeter V varies by no more than ±100mV.Note that the safe-area terminal numbers of MTL4531 differ from those of MTL5531: refer to the appropriateproduct data sheet. If an MTL4531 is to be tested in situ (ie installed on a backplane in the target system),it is imperative that the safe area terminals are disconnected from the input to the logic solver before thetest is conducted. Alternatively, the module may be removed from the target system and bench-tested on aseparate backplane.7.2.2 MTLx582B Proof T est ProcedureDue to the nature of the MTLx582B, testing of the module in isolation can be complex. If bench-testing facilitiesare unavailable, and the safety system is out of service (for example during a plant shut-down), the module maybe tested in combination with the logic solver. In this case, a simple test procedure would be to disconnectthe RTD sensor cables from the hazardous-area input terminals of the module and connect a precisionresistor directly across the module terminals (linking the 3- and 4-wire compensating terminals if necessary inaccordance with the module configuration). Using published charts for the appropriate RTD sensor type, checkthat the logic solver reads a temperature within an accuracy of ±4 ohms of the resistor value. Some additionalallowance for the inaccuracy of the logic solver may need to be made. The test should be conducted at twodifferent resistances within the range of the RTD sensor, for example by using values of 100 ohms and 250ohms.If it is not possible to test the module in situ, it may be bench tested as above, using a 1mA current source topass current through the safe-area + and – terminals.SMx 531-82 Rev411The given data is only intended as a product description and should not be regarded as a legal warranty of properties or guarantee. In the interest of further technical developments, we reserve the right to make design changes.Eaton Electric Limited, Great Marlings, Butterfield, Luton Beds, LU2 8DL, UK.Tel: + 44 (0)1582 723633 Fax: + 44 (0)1582 422283E-mail:******************** © 2018 EatonAll Rights Reserved Publication No. SMx 531-82 Rev 4 070918September 2018AUSTRALIA MTL Instruments Pty Ltd, 10 Kent Road, Mascot, New South Wales, 2020, Australia Tel: +61 1300 308 374 Fax: +61 1300 308 463E-mail:*********************BeNeLux MTL Instruments BV Ambacht 6, 5301 KW Zaltbommel The Netherlands Tel: +31 (0) 418 570290 Fax: +31 (0) 418 541044E-mail:*********************CHINA Cooper Electric (Shanghai) Co. Ltd 955 Shengli Road, Heqing Industrial Park Pudong New Area, Shanghai 201201Tel: +86 21 2899 3817 Fax: +86 21 2899 3992E-mail:****************FRANCE MTL Instruments sarl,7 rue des Rosiéristes, 69410 Champagne au Mont d’Or France Tel: +33 (0)4 37 46 16 53 Fax: +33 (0)4 37 46 17 20E-mail:*******************GERMANY MTL Instruments GmbH, Heinrich-Hertz-Str. 12, 50170 Kerpen, Germany Tel: +49 (0)22 73 98 12 - 0 Fax: +49 (0)22 73 98 12 - 2 00E-mail:*******************INDIA MTL India, No.36, Nehru Street, Off Old Mahabalipuram Road Sholinganallur, Chennai - 600 119, India Tel: +91 (0) 44 24501660 /24501857 Fax: +91 (0) 44 24501463E-mail:***********************ITAL Y MTL Italia srl, Via San Bovio, 3, 20090 Segrate, Milano, ItalyTel: +39 02 959501 Fax: +39 02 95950759E-mail:******************JAPAN Cooper Industries Japan K.K.Unizo Nogizaka Bldg. 7th Floor, 8-11-37, Akasaka, Minato-ku, Tokyo, Japan 107-0052Tel: +81 (0)3 6434 7890 Fax:+81 (0)3 6434 7889E-mail:****************NORWA Y Norex AS Fekjan 7c, Postboks 147, N-1378 Nesbru, Norway Tel: +47 66 77 43 80 Fax: +47 66 84 55 33E-mail:*************RUSSIA Cooper Industries Russia LLC Elektrozavodskaya Str 33Building 4Moscow 107076, RussiaTel: +7 (495) 981 3770 Fax: +7 (495) 981 3771E-mail:*******************SINGAPORE Cooper Crouse-Hinds Pte Ltd 100G Pasir Panjang Road, Interlocal Centre #07-08 Singapore 118523 Tel: +65 6645 9888 Fax: +65 6645 9811E-mail:***********************SOUTH KOREA Cooper Crouse-Hinds Korea 7F . Parkland Building 237-11 Nonhyun-dong Gangnam-gu,Seoul 135-546, South Korea.Tel: +82 6380 4805 Fax: +82 6380 4839E-mail:*******************UNITED ARAB EMIRATES Cooper Industries/Eaton Corporation Office 205/206, 2nd Floor SJ Towers, off. Old Airport Road, Abu Dhabi, United Arab Emirates Tel: +971 2 44 66 840 Fax: +971 2 44 66 841E-mail:*****************UNITED KINGDOM Eaton Electric Limited, Great Marlings, Butterfield, Luton Beds LU2 8DL Tel: +44 (0)1582 723633 Fax: +44 (0)1582 422283E-mail:********************AMERICAS Cooper Crouse-Hinds MTL Inc. 3413 N. Sam Houston Parkway W.Suite 200, Houston TX 77086, USA Tel: +1 800-835-7075 Fax: +1 866-298-2468E-mail:*********************EUROPE (EMEA): +44 (0)1582 723633 ********************THE AMERICAS: +1 800 835 7075 *********************ASIA-PACIFIC: +65 6645 9888 ***********************。

ApplicationLift StationsIndustrial and municipal pump liftstations collect and transfer wastewater or stormwater into treatment. These receptacles are dynamic environments that contain dirt, grease, oil, agitation, sludge, foam, condensation, chemicals or vapor. The LR31 pulse radar sensor is unaffected by such challenging process conditions, and is designed for bracket mount installation, either downhole orabove grade based on your needs.The intrinsically safe 26 GHz. pulse radar transmitter providescontinuous level measurement up to 98.4’ (30m) with a 4-20 mA analog and HART digital signal output, and is configured via its remote push button display module or HART communicator. The non-contact liquid level sensor is intended for industrial wastewater, municipal storm or sewer lift station, reservoir, river, canal or open channel applicationslocated below or above grade. Select this sensor for challenging process conditions that may include light surface foam or agitation, small trash or plant material, wind, condensation or vapor. Each comes with a 32.8’ (10m) cable, mounting bracket and display module. The sensoris designed for bracket mount installation suspended above the liquidFeaturesRugged IP68 sensor enclosure with 304 SS mounting bracket Configuration via push button display or HART communicator 26 GHz. pulse radar is unaffected by sump process conditions Wall mounted display with windowed enclosure rated IP6712” (30cm) dead band enables utilization of the entire sump LCD displays level in feet or meters with percent of span bar Optional display mode indicates the echo signal return curve Self diagnostics with selectable fail-safe signal outputs Recognition, storage and rejection of false echo signal returnsLR31-0021-10-00ShownPush Button Display Module12” to 98.4’ (30cm to 30m)26 GHz.± 3mm 12” (30cm)12º21.6 to 26.4 VDC 22.5 mA4-20 mA, two-wire, HART 74-20 mA, 20-4 mA 3.9 mA, 20.5 mA, 22 mA F: -40º to 212ºC: -40º to 100ºAutomatic Atmospheric IP68Nylon6-conductor, shielded 32.8’ (10m) PVC304 SS bracket or 1” NPT LCD, dot matrix Feet and meters Percent of span Echo signal curve Push button, HART 7Wall mount IP67Polycarbonate(2) 1/2” NPT connectors Non-volatile F: -40º to 176ºC: -40º to 80ºIntrinsically safeATEX IIG Ex ia II C T6...T3 Ga IEC Ex ia IIC T6...T3 GaCSA Class I, Div 1, Groups A, B, C & D; Class II, Div 1, Groups E, F & G; (T6...T3); Class I Zone 0 AEx ia IIC (T6...T3) Ga & Zone 20 AEx ia IIIC (T76ºC to T146ºC) Da; Ex ia IIC (T6...T3) Ga & Ex ia IIIC (T76ºC to T146ºC) GaFCC CE, RoHSNOTESIncludes the sensor, bracket, cable and display.If you want help in selecting a sensor for your application, please go to our website and submit a Level Questionnaire. An engineer will review your requirements and suggest a product solution via email.1)2)DimensionsSpecificationsOrderingLR31-0021-10-00EchoProLR31Pulse Radar Liquid Level TransmitterSENSORRange:Frequency:Accuracy:Dead band:Beam angle:Supply voltage:Max consumption:Signal output:Signal invert:Signal fail-safe:Process temp.: Temp. comp.:Pressure:Enclosure rating:Encl. material:Cable type:Cable length:Cable jacket mat.:Process mount:DISPLAYDisplay type:Display units:Display bar:Display graph:Configuration:Enclosure type:Enclosure rating:Encl. material:Conduit entrance:COMMONMemory: Storage temp.:Classification:Approvals:Certification:Compliance:Display Front ViewDisplay Side View0.2"(1) (2)。

5833中⽂资料Designed to reduce logic supply current, chip size, and system cost, the UCN5833A/EP integrated circuits offer high-speed operation for thermal printers. These devices can also be used to drive multi-plexed LED displays or incandescent lamps within their 125 mA peak output current rating. The combination of bipolar and MOS technolo-gies gives BiMOS II smart power ICs an interface flexibility beyond the reach of standard buffers and power driver circuits.These 32-bit drivers have bipolar open-collector npn Darlington outputs, a CMOS data latch for each of the drivers, a 32-bit CMOS shift register, and CMOS control circuitry. The high-speed CMOS shift registers and latches allow operation with most microprocessor-based systems at data input rates above 3.3 MHz. Use of these drivers with TTL may require input pull-up resistors to ensure an input logic high.The UCN5833A is supplied in a 40-pin dual in-line plastic package with 0.600" (15.24 mm) row spacing. At an ambient temperature of +75°C, all outputs of the DlP-packaged device will sustain 50 mA continuously. For high-density applications, the UCN5833EP is available. This 44-lead plastic chip carrier (quad pack) is intended for surface-mounting on solder lands with 0.050" (1.27 mm) centers.CMOS serial data outputs permit cascading for applications requiring additional drive lines.FEATURESI To 3.3 MHz Data Input Rate I 30 V Minimum Output Breakdown I Darlington Current-Sink Outputs I Low-Power CMOS Logic and LatchesBiMOS II 32-BIT SERIAL-INPUT,LATCHED DRIVERAlways order by complete part number:Part Number Package UCN5833A 40-Pin DIP UCN5833EP 44-Lead PLCCData Sheet 26185.16A*58335833BiMOS II 32-BIT SERIAL-INPUT,LATCHED DRIVER115 Northeast Cutoff, Box 15036Worcester, Massachusetts 01615-0036 (508) 853-5000SERIAL DATA IN POWER STROBE OUT OUT OUT OUT OUT OUT 123456OUT7OUT 8OUT 9OUTOUT OUTOUT OUTLOGIC SUPPLY OUT OUT Dwg. No. A-13,051TYPICAL OUTPUT DRIVERSUBOUT115 Northeast Cutoff, Box 15036Worcester, Massachusetts 01615-0036 (508) 853-5000Copyright ? 1986, 1995, Allegro MicroSystems, Inc.5833BiMOS II 32-BIT SERIAL-INPUT,LATCHED DRIVERTRUTH TABLEL = Low Logic Level H = High Logic Level X = Irrelevant P = Present State R = Previous StateELECTRICAL CHARACTERISTICS at T A = +25°C, V DD = 5 V (unless otherwise noted).Limits CharacteristicSymbol Test Conditions Min.Max.Units Output Leakage Current I CEX V OUT = 30 V, T A = 70°C —10µA Collector-Emitter V CE(SAT)l OUT = 50 mA — 1.2V l OUT = 100 mA— 1.7V Input VoltageV IN(1) 3.5 5.3V V IN(0)-0.3+0.8V Input Currentl IN(1)V IN = 5.0 V — 1.0µA l IN(0)V IN = 0 V —-1.0µA Serial Output VoltageV OUT(1)I OUT = -200 µA 4.5—V V OUT(0)I OUT = 200 µA—0.3V Supply Currentl DD One output ON, l OUT = 100 mA — 1.0mA All outputs OFF—50µA Output Rise Time t r l OUT = 100 mA, 10% to 90%—500ns Output Fall Timet fl OUT = 100 mA, 90% to 10%—500nsNOTE: Positive (negative) current is defined as going into (coming out of) the specified device pin.Saturation Voltage5833BiMOS II 32-BIT SERIAL-INPUT,LATCHED DRIVER115 Northeast Cutoff, Box 15036Worcester, Massachusetts 01615-0036 (508) 853-5000TIMING CONDITIONS(V DD = 5.0 V, Logic Levels are V DD and Ground)A.Minimum Data Active Time Before Clock Pulse(Data Set-Up Time)..........................................................................75 ns B.Minimum Data Active Time After Clock Pulse(Data Hold Time).............................................................................75 ns C.Minimum Data Pulse Width ................................................................150 ns D.Minimum Clock Pulse Width...............................................................150 nsE.Minimum Time Between Clock Activation and Strobe.......................300 nsF.Minimum Strobe Pulse Width .............................................................100 nsG.Typical Time Between Strobe Activation andOutput Transition ...........................................................................500 nsDwg. No. A-12,276ASerial Data present at the input is transferred to the shift register on the logic “0” to logic “1” transition of the CLOCK input pulse. On succeeding CLOCK pulses, the registers shift data information towards the SERIAL DATA OUTPUT. The SERIAL DATA must appear at the input prior to the rising edge of the CLOCK input waveform.Information present at any register is transferred to its respective latch when the STROBE is high (serial-to-parallel conversion). The latches will continue to accept new data as long as the STROBE is held high. Applications where the latches are bypassed (STROBE tied high) will require that the OUTPUT ENABLE input be low during serial data entry.When the OUTPUT ENABLE input is low, all of the output buffers are disabled (OFF) without affecting the information stored in the latches or shift register. With the OUTPUT ENABLE input high, the outputs are controlled by the state of the latches.CLOCK DATA INSTROBE NOUTPUT ENABLEOUT5833BiMOS II 32-BIT SERIAL-INPUT,LATCHED DRIVERNOTES:1.Exact body and lead configuration at vendor’s option within limits shown.2.Lead spacing tolerance is non-cumulative.3.Lead thickness is measured at seating plane or below.UCN5833ADimensions in Inches (controlling dimensions)Dimensions in Millimeters (for reference only)123Dwg. MA-003-40 mm20421123Dwg. MA-003-40 in2045833BiMOS II 32-BIT SERIAL-INPUT,LATCHED DRIVER115 Northeast Cutoff, Box 15036Worcester, Massachusetts 01615-0036 (508) 853-5000UCN5833EPDimensions in Inches (controlling dimensions)Dimensions in Millimeters (for reference only)Dwg. MA-005-44A mm0.53340Dwg. MA-005-44A in0.021740NOTES:1.Exact body and lead configuration at vendor’s option within limits shown.2.Lead spacing tolerance is non-cumulative.5833BiMOS II 32-BITSERIAL-INPUT,LATCHED DRIVERThe products described here are manufactured under one or more U.S. patents or U.S. patents pending.Allegro MicroSystems, Inc. reserves the right to make, from time to time, such departures from the detail specifications as may be required to permit improvements in the performance, reliability, or manufacturability of its products. Before placing an order, the user is cautioned to verify that the information being relied upon is current.Allegro products are not authorized for use as critical components in life-support devices or systems without express written approval.The information included herein is believed to be accurate and reliable. However, Allegro MicroSystems, Inc. assumes no responsi-bility for its use; nor for any infringement of patents or other rights of third parties which may result from its use. 5833BiMOS II 32-BIT SERIAL-INPUT,LATCHED DRIVER115 Northeast Cutoff, Box 15036Worcester, Massachusetts 01615-0036 (508) 853-5000POWERINTERFACE DRIVERSFunctionOutput Ratings*Part Number ?SERIAL-INPUT LATCHED DRIVERS8-Bit (saturated drivers)-120 mA 50 V?58958-Bit 350 mA 50 V 58218-Bit 350 mA 80 V 58228-Bit 350 mA 50 V?58418-Bit 350 mA 80 V?58428-Bit (constant-current LED driver)75 mA 17 V 62758-Bit (DMOS drivers)250 mA 50 V 65958-Bit (DMOS drivers)350 mA 50 V?6A5958-Bit (DMOS drivers)100 mA 50 V 6B59510-Bit (active pull-downs)-25 mA 60 V 5810-F and 6809/1012-Bit (active pull-downs)-25 mA 60 V 5811 and 681116-Bit (constant-current LED driver)75 mA 17 V 627620-Bit (active pull-downs)-25 mA 60 V 5812-F and 681232-Bit (active pull-downs)-25 mA 60 V 5818-F and 681832-Bit100 mA 30 V 583332-Bit (saturated drivers)100 mA 40 V 5832PARALLEL-INPUT LATCHED DRIVERS4-Bit350 mA 50 V?58008-Bit -25 mA 60 V 58158-Bit350 mA 50 V?58018-Bit (DMOS drivers)100 mA 50 V 6B2738-Bit (DMOS drivers)250 mA 50 V 6273SPECIAL-PURPOSE DEVICESUnipolar Stepper Motor Translator/Driver 1.25 A 50 V?5804Addressable 8-Bit Decoder/DMOS Driver 250 mA 50 V6259Addressable 8-Bit Decoder/DMOS Driver 350 mA 50 V?6A259Addressable 8-Bit Decoder/DMOS Driver 100 mA 50 V 6B259Addressable 28-Line Decoder/Driver 450 mA30 V6817*Current is maximum specified test condition, voltage is maximum rating. See specification for sustaining voltagelimits.Negative current is defined as coming out of (sourcing) the output.Complete part number includes additional characters to indicate operating temperature range and package style. Internal transient-suppression diodes included for inductive-load protection.。