STEVAL-IFW002V1;中文规格书,Datasheet资料

IntroductionThe PI2001-EVAL1 allows the user to test the basic principle and operational characteristics of an Active ORing function in a redundant power architecture, while also experiencing the benefits and value of the PI2001 solution versus conventional Active ORing solutions. The PI2001-EVAL1 evaluation board is configured to receive two independent power source inputs,per a typical redundant power architecture, through two Active ORing channels that are combined to form aredundant power output. Each channel contains a PI2001controller and an N-channel power MOSFET. The MOSFET foot print can take an SO-8 or Power SO-8 MOSFET package.Each channel is capable of up to 20 A, for high current Active ORing, above 20 A, the two channels provided on the evaluation board can be paralleled in a master /slave configuration and OR’d with a second evaluation board.The PI2001-EVAL1 evaluation board is designed withoptimized PCB layout and component placement to represent a realistic high density final design for an embedded Active ORing solution for ≤7 Vbus applications requiring up to 20 A.This evaluation board is intended as an easy and simple way to test the electrical and thermal performance of the PI2001Active ORing controller.Both dynamic and steady state testing of the PI2001 can be completed on the PI2001-EVAL1 evaluation board, in addition to using the key features of the product. Dynamic testing can be completed under a variety of system level fault conditions to check for response time to faults.This document provides basic instructions for initial start-up and configuration of the evaluation board. Further information on the functionality of the PI2001 can be found in the PI2001 product data sheet.PI2001-EVAL1Cool-ORing ™ SeriesPI2001-EVAL1 Active ORingEvaluation Board User Guide®PI2001-EVAL1 Evaluation Board featuring the Cool-ORing PI2001 Universal Active ORing controller.Cool-ORing™ SeriesThe PI2001-EVAL1 Evaluation Board is intended to acquaint the user with the benefits and features of the Cool-ORing TM PI2001Universal Active ORing controller. It is not designed to be installed in end-use equipment.Please read this document before setting up the PI2001-EVAL1Evaluation Board and refer to the PI2001 product data sheet for device specifications, functional description and characteristics.During operation, the power devices and surrounding structures can be operated safely at high temperatures.•Remove power and use caution when connecting and disconnecting test probes and interface lines to avoid inadvertent short circuits and contact with hot surfaces.•When testing electronic products always use approved safety glasses. Follow good laboratory practice and procedures.The Cool-ORing PI2001 with an external industry standard N-channel MOSFET provides a complete Active ORing solution designed for use in redundant power systemarchitectures. The PI2001 controller with N-channel MOSFET enables extremely low power loss with fast dynamic response to fault conditions, critical for high availability systems. A master /slave feature allows the paralleling of PI2001solutions for high current Active ORing requirements. The PI2001 can also drive multiple paralleled MOSFETs.The PI2001 controller with a low Rds(on) N-channel MOSFET provides very high efficiency and low power loss during steady state operation. The PI2001 controller provides an active low fault flag output to the system during excessive forward current, light load, reverse current, over-voltage,under-voltage, and over-temperature fault conditions. A temperature sensing function indicates a fault if themaximum junction temperature exceeds 160°C. The under-voltage and over-voltage thresholds are programmable via an external resistor divider.Figure 1 shows a photo of the PI2001-EVAL1 evaluation board, with two PI2001 controllers and two N-channelMOSFETs used to form the two Active ORing channels. The board is built with two identical Active ORing circuits with options and features that enable the user to fully explore thecapabilities of the PI2001 universal Active ORing controller.Figure 1 –PI2001-EVAL1 Evaluation Board (1.8" x 1.8")Terminals RatingVin1, Vin28V / 24 AVaux1, Vaux2, (R2 = R4 = 10 Ω)-0.3 V to 17.3 V / 40 mA SL1, SL2-0.3 V to 8.0 V / 10 mA FT1, FT2-0.3 V to 17.3 V / 10 mATerminal DescriptionVin1Power Source Input #1or bus input designed to accommodate up to 20 A continuous current.Vaux1Auxiliary Input Voltage #1to supply PI2001 VC power. Vaux1 should be equal to Vin1 plus 5 V or higher. See details in Auxiliary Power Supply (Vaux) section of the PI2001 data sheet.Rtn1Vaux1 Return Connection: Connected to Ground planeGnd Vin & Vout Return Connection:Three Gnd connections are available and are connected to a common point, the Ground plane. Input supplies Vin1 & Vin2 and the output load at Vout should all be connected to their respective local Gnd connection.SL1PI2001 (U1) Slave Input-Output Pin: For monitoring U1 slave pin. When U1 is configured as the Master, this pin functions as an output that drives slaved PI2001 devices. When U1 is configured in Slave mode, SL1 serves as an input.SL2PI2001 (U2) Slave Input-Output Pin: For monitoring U2 slave pin. When U2 is configured as the Master, this pin functions as an output that drives slaved PI2001 devices. When U2 is configured in Slave mode, SL2 serves as an input.Vin2Power Source Input #2or bus input designed to accommodate up to 20 A continuous current.Vaux2Auxiliary Input Voltage #2to supply PI2001 VC power. Vaux2 should be equal to Vin2 plus 5 V or higher. See details in Auxiliary Power Supply (Vaux) section of the PI2001 data sheet.Rtn2Vaux2 Return Connection: Connected to Ground plane FT1PI2001 (U1) Fault Pin: Monitors U1 fault conditions FT2PI2001 (U2) Fault Pin: Monitors U2 fault conditionsVoutOutput: Q1 and Q2 MOSFET Drain pins connection, connect to the load high side.Table 1 –PI2001-EVAL1 Evaluation Board terminals descriptionCool-ORing TM PI2001 Product DescriptionJumper DescriptionJ1, J3BK Jumpers: Connect jumper across M for master mode and across S for slave mode. Remove jumper to adjust reverse fault blanking time using Rbk. Rbk is R7 for U1 and R14 for U2 shown in the schematic, Figure 2.J2Slave Jumper: Remove the jumper unless one of the PI2001 is configured in slave mode.Table 2 –PI2001-EVAL1 Evaluation Board jumpers descriptionFigure 2 –PI2001-EVAL1 Evaluation Board schematic.Item QTY Reference Designator Value Description Footprint Manufacturer 12C1, C2 1 µF Capacitor, MLCC X5R, 06031 µF,16 V21C322 µF Capacitor, MLCC X7R,121022 µF, 25 V34C4, C5, C6, C7Not installed120642D1, D2LED, Super Red THIN 0603Lite-On, Inc.,58FT1, FT2, Rtn1, Rtn2, Turret Test point TURRET-1528Keystone SL1, SL2, Vaux1, Vaux2Electronics67Gnd1, Gnd2, Gnd3, Gnd4,Turret Test point TURRET-1502Keystone Vin1, Vin2, Vout1, Vout2Electronics 72J1, J3Header Pins 0.1" pitch 2 x 3mm81J2Header Pins 0.1" pitch 2 x 2mm92Q1, Q2FDS8812NZSO-8Fairchild 30 V, 20 A, N-MOSFET102R1, R88.45 KΩResistor,8.45 KΩ,1%0603112R2, R913.3 KΩResistor,13.3 KΩ,1%0603122R3, R1010 ΩResistor,10 Ω,5%0603132R4, R11 4.99 KΩResistor, 4.99 KΩ,5%0603144R5, R6, R12, R13 2.00 KΩResistor, 2.00 KΩ,1%0603152R7, R14Not Installed0603162U1, U2PI2001Picor Universal Active ORing Controller3mmx3mm; 10-TDFN PICOR Table 3 –PI2001-EVAL1 Evaluation Board bill of materialsInitial Test Set UpTo test the PI2001-EVAL1 evaluation board it is necessary to configure the jumpers (J1, J2 and J3) first based on the required board configuration.Failure to configure the jumpers prior to the testing may result in improper circuit behaviorBaseline Test Procedure (Refer to Figure 3)1.0 Recommended Equipment1.1Two DC power supplies - 0-10 V; 25 A.1.2DC power supply 12 V; 100 mA.1.3DC electronic load - 50 A minimum.1.4Digital Multimeter 1.5Oscilloscope.1.6Appropriately sized interconnect cables.1.7Safety glasses.1.8PI2001 Product Data sheet.Figure 3 –Layout configuration for a typical redundant power application, using PI2001 with both solutions configured in Master Mode.Reference Designator Value Functional Description C1, C2 1 µF VC Bypass Capacitor C322 µF Output (Load) CapacitorC4, C5, C6, C7Not installedSnubber to reduce voltage ringing when the device turns off D1, D2LED To indicate a fault exist when it is onJ1, J3Jumper To select between Master and Slave Modes J2Jumper Connection between SL1 and SL2Q1, Q2N-MOSFET ORing Main SwitchR1, R88.45 K ΩUV Voltage Divider Resistor ( R2UV in Figure 4) R2, R913.3 K ΩOV Voltage Divider Resistor ( R2OV in Figure 4) R3, R1010 ΩVC Bias resistor R4, R11 4.99 K ΩLED Current LimiterR5, R6 2.00 K ΩUV Voltage Divider Resistor ( R1UV in Figure 4) R7, R14Not Installed BK Delay Timer Programmable Resistor U1, U2PI2001Universal Active ORing ControllerTable 4 –Component functional descriptionBefore initial power-up follow these steps to configure the evaluation board for specific end application requirements: 2.0 Undervoltage (UV) and Overvoltage (OV) resistors set up:2.1UV and OV programmable resistors are configuredfor a 3.3 V Vin (BUS voltage) application in atwo-resistor voltage divider configuration as shown inFigure 4. UV is set to 2.6 V and OV is set for 3.8 V,R1OV and R1UV are 2.00KΩ1%. If PI2121-EVAL1 isrequired to be used in a different Vin voltage . .application please follow the following steps tochange the resistor values.2.1.1It is important to consider the maximum currentthat will flow in the resistor divider andmaximum error due to UV and OV input .current.R1UV=V(UV TH)I RUV2.1.2Set R1UV and R1OV value based on systemallowable minimum current and 1% error;I RUV ≥ 100 µAR2UV=R1UV (V(UV)–1)V(UV TH)Where:V(UV TH) : UV threshold voltageV(UV) : UV voltage set (0.5 V typ)I RUV: R1UV currentR2OV=R1OV (V(OV)–1)V(OV TH)Where:V(OV TH) : OV threshold voltageV(OV) : OV voltage set (0.5 V typ)I ROV: R1OV currentFigure 4 –UV & OV two-resistor divider configuration2.1.3Example for 2.0 V Vin (BUS voltage), to set UV and OV for ±10% Vin set UV at 1.8 V and OV at 2.2 V.R2UV= R1UV (V(UV)–1) = 2.00 KΩ*( 1.8 V–1)= 5.20 KΩ(or 5.23 KΩ% standard value)V(UV TH)0.5 VR2OV= R1OV (V(OV)–1) = 2.00 KΩ*( 2.2 V–1)= 6.80 KΩ(or 6.81 KΩ% standard value)V(OV TH)0.5 V3.0Blanking timer setup:3.1The blanking timer provides noise filtering fortypical switching power conversion that mightcause premature reverse current detection bymasking the reverse fault condition. The shortestblanking time is 50 ns when the BK pin isconnected to ground. Connecting an externalresistor (R BK, reference designators R7 for U1 andR14 for U2) between the BK pin and ground willincrease the blanking time as shown in Figure 5.Where:R BK≤ 200 KΩNote:When BK is connected to VC for slave mode .operation,then the blanking time will be 270 ns typically.4.0Auxiliary Power Supply (Vaux):4.1The PI2001 Controller has a separate input (VC) thatprovides power to the control circuitry and the gatedriver. An internal voltage regulator (VC) clamps theVC voltage to 15.5 V typically.4.2Connect independent power source to Vaux inputs ofPI2001-EVAL1 Evaluation Board to supply power tothe VC input. The Vaux voltage should be 5V higherthan Vin (redundant power source output voltage) tofully enhance the MOSFET. If the MOSFET is replacedwith different MOSFET, make sure that Vaux= Vin +0.5 V + required voltage to be enhance the MOSFET.4.310 Ωbias resistors (Rbias, reference designators R3and R10) are installed on the PI2001-EVAL1 betweeneach Vaux input and VC pin of one of the PI2001controller. 4.4If Vaux is higher than the Clamp voltage, 15.5 Vtypical, the Rbias value has to be changed using thefollowing equations:4.4.1Select the value of Rbias using the followingequation:Rbias =Vaux min–VC clampMAXIC max4.4.2Calculate Rbias maximum power dissipation:Pd Rbias= (Vaux max–VC clampMIN)2RbiasWhere:Vaux min: Vaux minimum voltageVaux max: Vaux maximum voltageVC ClampMAX:Maximum controllerclamp voltage, 16.0 VVC ClampMIN:Minimum controllerclamp voltage, 14.0 VIC max: Controller maximum bias current,use 4.2 mA4.4.3For example, if the minimum Vaux = 22 Vand the maximum Vaux = 28 VRbias = Vaux min–VC clampMAX =22 V–16 V = 1.429 KΩIC max 4.2 mA,use 1.43 KΩ1% resistorPd Rbias= (Vaux max–VC clampMIN)2= (28 V–14.0 V)2=137 mWRbias 1.43 KΩNote:Minimize the resistor value for low Vaux voltagelevels to avoid a voltage drop that may reduce the VCvoltage lower than required to drive the gate of theinternal MOSFET. Figure 5 –BK Resistor selection versus Blanking Time5.0Hook Up of the Evaluation Board5.1OV and UV resistors values are configured for a 3.3 Vinput voltage. If you are using the evaluation board ina different input voltage level you have to adjust theresistor values by replacing R1, R2, R8 and R9, orremove R2, R5, R9 and R12 to disable UV and OV.Please refer to the UV/OV section for details to set R1,R2, R8 and R9 proper values.5.2Verify that the jumpers J1 and J3 are installed formaster mode [across M] and no Jumper on J2.5.3Connect the positive terminal of PS1 power supplyto Vin1. Connect the ground terminal of PS1 to itslocal Gnd. Set the power supply to 3.3 V.Keep PS1 output disabled (OFF).5.4Connect the positive terminal of PS2 power supplyto Vin2. Connect the ground terminal of PS2 to itslocal Gnd. Set the power supply to 3.3 V. Keep PS2output disabled (OFF).5.5Connect the positive terminal of PS3 power supplyto Vaux1 and Vaux2. Connect the ground terminalof this power supply to Rtn1 and Rtn2. Set thepower supply to 12 V. Keep PS3 output disabled(OFF).5.6Connect the electronic load to the output betweenVout and Gnd. Set the load current to 10 A.5.7Enable (turn ON) PS1 power supply output.5.8Turn on the electronic load.5.9Verify that the electronic load input voltagereading is one diode voltage drop below 3.3 V.5.10Enable (turn ON) PS3 power supply output.5.11Verify that the electronic load voltage readingincreases to a few millivolts below 3.3 V. This verifiesthat the MOSFET is in conduction mode.5.12D1 should be off. This verifies that there is nofault condition.5.13Reduce PS1 output voltage to 2 V,5.14D1 should turn on, this verifies that the circuit is inan under-voltage fault condition.5.15Increase PS1 output to 3.3 V, D1 should turn off, thenincrease PS1 output to 4 V, D1 should turn onindicating an over-voltage fault condition5.16Verify that Vin2 is at 0V. This verifies that thePI2001 (U2) FET (Q2) is off.5.17D2 should be on. This is due to a reverse voltagefault condition caused by the bus voltage beinghigh with respect to the input voltage (Vin2).5.18Enable (turn ON) PS2 output.5.19Verify that both PS1 and PS2 are sharing loadcurrent evenly by looking at the supply current.5.20Disable (turn OFF) PS1, PS2 and PS3 outputs.5.21Enable (turn ON) PS2 output then Enable PS3 output.5.22Verify that the electronic load voltage reading isfew millivolts below 3.3 V. This verifies that the PI2001(U2) MOSFET (Q2) is in conduction mode.5.23D2 should be off. This verifies that there is nofault condition.5.24Reduce PS2 output voltage to 2 V,5.25D2 should turn on, this verifies that the circuit is inan under-voltage fault condition.5.26Increase PS2 output to 3.3 V, D2 should turn off, thenincrease PS2 output to 4 V, D2 should turn onindicating an over voltage fault condition.5.27Verify that Vin1 is at 0V. This verifies that thePI2001 (U1) FET (Q1) is off.5.28D1 should be on. This is due to a reverse voltagefault condition caused by the bus voltage beinghigh with respect to the input voltage (Vin1).6.0Slave Mode: Slave Mode can be demonstrated in two setups; either by using one PI2001-EVAL1 evaluation board as a single ORing function with both PI2001 effectively in parallel or two PI2001-EVAL1 evaluation boards to demonstrate a true redundant 40A system. The following test steps use a single PI2001-EVAL1 in a slave mode application. Note:In this experiment U1 is configured in master mode andU2 is configured in slave mode.6.1BK pin (J1) of the master device will be connected toground [across M] while the slaved device BK pin (J3)is connected to VCC [across S]. Place a jumper across J2to connect slave pins together.6.2Connect the positive terminal of PS1 power supplyto Vin1. Connect the ground terminal of this powersupply to Gnd. Set the power supply to 3.3 V. KeepPS1 output disabled (OFF).6.3Connect the positive terminal of PS2 power supplyto Vin2. Connect the ground terminal of this powersupply to Gnd. Set the power supply to 3.3 V. KeepPS2 output disabled (OFF).6.4Connect the positive terminal of PS3 power supplyto Vaux1 and Vaux2. Connect the ground terminalof this power supply to Rtn1 and Rtn2. Set thepower supply to 12 V. Keep PS3 output disabled (OFF).6.5Connect the electronic load between Vout andGnd. Set the load current to 10 A.6.6Enable (Turn ON) PS2, and PS3 outputs, and keepPS1 output disabled (OFF).6.7Turn on the electronic load.6.8Verify that electronic load voltage drops to a diodedrop below PS2. This verifies that the Q2 is off due tothe Master (U1) not being on.6.9Enable (turn on) PS1 output:6.10Verify that the electronic load input voltage reading isa few millivolts below 3.3 V and PS1 and PS2 aresharing the load current evenly. This verifies that both MOSFET's, Q1 and Q2, are in conduction mode.7.0Input short circuit test7.1To emulate a real application, the BUS supplies for thistest should have a solid output source such as DC-DC converter that supplies high current and can be connected very close to the evaluation board to reduce stray parasitic inductance. Or use theprospective supply sources of the end application where the PI2001 will be used. 7.2Stray parasitic inductance in the circuit can contributeto significant voltage transient conditions, particularly when the MOSFET is turned-off after a reverse current fault has been detected. When a short is applied at the output of the input power sources and the .evaluation board input (Vin), a large reverse current is sourced from the evaluation board output through the ORing MOSFET. The reverse current in the MOSFET may reach over 60 A in some conditions before the MOSFET is turned off. Such high current conditionswill store high energy even in a small parasitic element, and can be represented as ½ Li2. A 1 nH parasitic inductance with 60 A reverse current will generate 1.8 µJ. When the MOSFET is turned off, the stored energy will be released and will produce a high negative voltage at the MOSFET source and high positive voltage at the MOSFET drain. This event will create a high voltage difference across the drain and source of the MOSFET.7.3Apply a short at one of the inputs (Vin1 or Vin2) whenthe evaluation board is configured with bothcontrollers (U1 and U2) in master mode. The short can be applied electronically using a MOSFET connected between Vin and Gnd or simply by connecting Vin to Gnd. Then measure the response time between when the short is applied and the MOSFET is disconnected (or turned off). An example for PI2001 response time to an input short circuit is shown in Figure 6.Figure 6 –Plot of PI2001 response time to reverse current detectionFigure 7a–PI2001-EVAL1 layout top layer. Scale 2.0:1 Figure 7b–PI2001-EVAL1 layout mid layer 2. Scale 2.0:1Figure 7c–PI2001-EVAL1 layout mid layer 1. Scale 2.0:1 Figure 7d–PI2001-EVAL1 layout Bottom layer. Scale 2.0:1Mechancial Drawing分销商库存信息: VICORPI2001-EVAL1。

This is information on a product in full production.July 2012Doc ID 18080 Rev 41/15SPV1040High efficiency solar battery charger with embedded MPPTDatasheet — production dataFeatures■0.3 V to 5.5 V operating input voltage ■140 m Ω internal synchronous rectifier ■120 m Ω internal power active switch ■100 kHz fixed PWM frequency■Duty cycle controlled by MPPT algorithm ■Output voltage regulation, overcurrent and overtemperature protection■Input source reverse polarity protection ■Built-in soft-start ■Up to 95% efficiency■3 mm x 4.4 mm TSSOP8 packageApplications■Smart phones and GPS systems ■Wireless headsets ■Small appliances, sensors ■Portable media players ■Digital still cameras■Toys and portable healthcareDescriptionThe SPV1040 device is a low power, low voltage, monolithic step-up converter with an input voltage range from 0.3 V to 5.5 V , and is capable ofmaximizing the energy generated by even a single solar cell (or fuel cell), where low input voltage handling capability is extremely important.Thanks to the embedded MPPT algorithm, even under varying environmental conditions (such as irradiation, dirt, temperature) the SPV1040 offers maximum efficiency in terms of power harvested from the cells and transferred to the output.The device employs an input voltage regulation loop, which fixes the charging battery voltage viaa resistor divider. The maximum output current is set with a current sense resistor according to charging current requirements.The SPV1040 protects itself and other application devices by stopping the PWM switching if either the maximum current threshold (up to 1.8 A) is reached or the maximum temperature limit (up to 155 °C) is exceeded.An additional built-in feature of the SPV1040 is the input source reverse polarity protection, which prevents damage in case of reverse connection of the solar panel at the input.Table 1.Device summaryOrder code Package Packaging SPV1040T TSSOP8Tube SPV1040TTRTape and reelT SS OP8Contents SPV1040Contents1Block diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 2Pin description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43Maximum ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53.1Absolute maximum ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53.2Thermal data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 4Electrical characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 5Typical characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86Detailed description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 106.1Soft-start mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 106.2Startup mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 106.3MPPT mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 106.4Constant voltage regulation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 106.5Constant current regulation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 116.6Overcurrent protection (OVC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 116.7Overtemperature protection (OVT) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 116.8Shutdown mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 116.9Undervoltage lockout (UVLO) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 116.10Reverse polarity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 116.11Burst mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 126.12Sleep-IN mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 7ECOPACK® . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .13 8Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 142/15Doc ID 18080 Rev 4SPV1040Block diagramDoc ID 18080 Rev 43/151 Block diagramFor setting up the application and simulating the related test results please go to /edesignstudioPin description SPV10404/15Doc ID 18080 Rev 42 Pin descriptionTable 2.Pin descriptionPin NameType Description1MPP-SET INon-inverting input to sense the PV cell voltage. It cannot be leftfloating.2GNDGround Power ground reference.8XSHUT IShutdown input pin:XSHUT = LOW: device in Power Off modeXSHUT = HIGH: device enabled for Operating mode This pin cannot be left floating.3LX I Booster inductor connection.7ICTRL_PLUS I Non-inverting input of constant current control loop. It cannot be left floating.6ICTRL_MINUSI Inverting input of constant current control loop. It cannot be left floating.5VCTRL I Non-inverting input of constant voltage control loop. It cannot be left floating.4VOUTOBooster output voltage.SPV1040Maximum ratingsDoc ID 18080 Rev 45/153 Maximum ratings3.1 Absolute maximum ratings3.2 Thermal dataNote:R thJA was measured on a 2-layer PCB: FR4, 35 µm Cu thickness, 2.8 cm 2Table 3.Absolute maximum ratingsSymbol ParameterRange [min, max]Unit MPP-SET Analog input [-5.5, VOUT]V GND Ground 0V XSHUT Analog input [-5.5, VOUT]V LXAnalog input[-5.5, VOUT]V ICTRL_PLUS Analog input [-0.3, VOUT]V ICTRL_MINUS Analog input[-0.3, VOUT]V VCTRL Analog input [-0.3, VOUT]V VOUTAnalog output[-0.3, 5.5]VTable 4.TSSOP 8 thermal dataSymbol ParameterValue Unit R th j-amb Thermal resistance, junction-to-ambient 135°C/W Tj op Junction operating temperature -40 to 125°C TstgStorage temperature-40 to 150°CElectrical characteristics SPV10406/15Doc ID 18080 Rev 44 Electrical characteristicsVMPP-SET = 0.5 V , V CTRL = I ctrl+ = I ctrl- = GND, XSHUT = 0.5 V , T J = -40 °C to 125 °C,unless otherwise specified.Table 5.Electrical characteristicsSymbolParameterTest conditionMin.Typ.Max.UnitInput source section V MPP-SETLow boost voltage threshold V OUT = 3.3V0.40.450.50V I q Quiescent current I LOAD =0mA, V CTRL =2V , V OUT =3.3V , 6080μA I SD Shutdown current V OUT = 3.3V , V CTRL =2V , I LOAD = 0mA, XSHUT = GND 0.75μA I revReverse input source currentV MPP-SET =-4V , V OUT = 1.5V 15μAV UVLOUndervoltage lockout threshold for turn ON @V OUT = 3.3VV MPP-SET increasing0.270.34VUndervoltage lockoutthreshold for turn OFF @V OUT = 3.3VV MPP-SET decreasing 0.140.24VPower section R DS_ON-N N-channel power switch ON resistance 120m ΩR DS_ON-PP-channelsynchronous rectifier ON resistanceV CTRL =2V140m ΩControl section V MPPT -THR MPPT -mode threshold Vout increasing, V MPP-SET = 1.5V 1.7 1.82V V OUT Output voltage range V MPP-SET ≥ 1.5V 25.2(1)V P OUT (2)Maximum output powerV MPP-SET ≥ 1.5V3W I Lx Maximum inductor current peak1.5 1.65 1.8A F PWM PWM signal frequency 70100130kHz V REF Internal V CTRL reference voltage V OUT ≥ 1.8V , V CTRL increasing 1.2 1.25 1.3V V Ictrl Sensing current offset I CTRL + - I CTRL - decreasing 405060mV XSHUTXSHUT logic LOW XSHUT increasing 0.270.34V XSHUT logic HIGHXSHUT decreasing 0.140.24VThermal shutdownSPV1040Electrical characteristicsDoc ID 18080 Rev 47/15T shutdownOvertemperaturethreshold for turn OFF Temperature increasing155°C Overtemperature threshold for turn ONTemperature decreasing130°C1.In order to increase the Vout as much as possible up to 5.2 V a Schottky diode must be placed between theLx and Vout pins, as shown in Figure 2.2.Given T j = T a + R thJA x P D , and assuming R thJA = 135°C/W, and that in order to avoid device destructionTjmax must be ≤ 125 °C, and that in the worst conditions T A = 85 °C, the power dissipated inside the device is given by:Therefore, if in the worst case the efficiency is assumed to be 90%, then P IN-MAX = 3.3 W and P OUT-MAX = 3 W.Table 5.Electrical characteristics (continued)SymbolParameterTest conditionMin.Typ.Max.UnitP D T j T a–R thJA----------------≤295mW=Typical characteristics SPV10408/15Doc ID 18080 Rev 45 Typical characteristicsFigure 4.Efficiency vs output voltage 3 PVFigure 5.MPPT efficiency vs output voltage 3 Figure 6.Efficiency vs output voltage 4 PVFigure 7.MPPT efficiency vs output voltage 4SPV1040Typical characteristicsDoc ID 18080 Rev 49/15For setting up the application and simulating the related test results please go to /edesignstudioFigure 8.Efficiency vs output voltage 5 PVFigure 9.MPPT efficiency vs output voltage 5 Figure 10.V LX and I LX waveforms - D = 39%Figure 11.V LX and I LX waveforms - D = 68%I LXV LXV OUT = 3V I LXV LXV OUT = 3VDetailed description SPV104010/15Doc ID 18080 Rev 46 Detailed descriptionThe SPV1040 is a monolithic, high efficiency, low voltage, self-powered DC-DC converterthat operates over a 0.3 V to 5.5 V DC input voltage range and provides a single output voltage.The device provides regulated output voltage and current by sensing the VCTRL feedback of the external resistor divider and the voltage drop on the external sense resistor Rs, respectively.High efficiency is ensured by low power consumption in any working mode and by the embedded Perturb & Observe MPPT algorithm.The SPV1040 guarantees its own safety and application safety by stopping the N-channel power switch in case of overcurrent or overtemperature conditions.6.1 Soft-start modeIn order to guarantee powerup even when V OUT is very low (battery completely discharged),a proper startup strategy has been implemented.Taking into account that the device is powered by the V OUT voltage, If V OUT is lower than 0.8V , the device moves from power off to soft-start mode and the current flows from the input to output through the intrinsic body diode of the synchronous rectifier. In this condition V OUT follows the LX voltage. The IC exits Startup mode when V OUT reaches 0.8 V .6.2 Startup modeWhen V OUT goes above 0.8 V but it is still lower than 2 V, a proper biasing of both MOSFETsis not yet guaranteed. In such conditions, the N-channel power switch is forced ON with a fixed duty cycle and the energy is transferred to the load via the intrinsic body diode of the P-channel synchronous switch. If the shutdown overcurrent limit is exceeded, the power switch is immediately turned OFF . The SPV1040 leaves Startup mode as soon as V OUT goes above 2 V.6.3 MPPT modeOnce the device has exited Startup mode, the SPV1040 enters MPPT mode to search forthe maximum power point. The Perturb & Observe algorithm is based on monitoring either the voltage or the current supplied by the DC power source unit so that the PWM signal duty cycle is increased or decreased step by step according to the input power trend. Refer to Figure 12, which illustrates the MPPT working principle.6.4 Constant voltage regulationThe constant voltage control loop consists of an internal voltage reference, an op amp and an external resistor divider that senses the battery voltage and fixes the voltage regulation set-point at the value specified by the user.分销商库存信息:STMSPV1040TTR SPV1040T STEVAL-ISV006V1。

®意大利倍尔实验室仪器设备符号电磁力恢复：永久磁铁中的线圈，用于实现最精确的称重高精度称重传感器：应变计通过测量电阻的变化来测量变形RS232 数据接口：通过此接口连接天平与打印机和其他 PC 外围设备。

测量单位：选择天平显示重量时所用测量单位计件：此功能对相同的项目进行计数，有一些参考数量可供选择检重：上限和下限可以各自设置，用于计量和配料。

百分比称重功能：计算样本重量相比于参考重量(100%)的百分比值。

累计功能：测量多个项目的累计重量。

显示总计和当前重量动物称重：在不稳定条件(如称量活动的实验动物等)下提供准确读数。

密度测定功能：准确测定固态物体或液体的密度最大负荷(峰值保持)功能：称量一连串重物时保留峰值重量GLP 设置：允许存储天平、项目和用户的识别数据。

日期和时间日期和时间：天平显示当前的日期和时间多语言：天平的菜单中有多种语言可供选择配方：允许设置配方中每种成分的名称和公差。

自动配料悬挂称重：可以在天平的底面装一个配有挂钩的支架蓄电池：天平内自带蓄电池，或可连接可选外置蓄电池使用电池操作：天平可以使用一组 AA 电池。

统计功能：显示最小值(Min)、最大值(Max)、总和(Sum)、平均值(Average)、标准偏差(Standard Deviation)毛重-净重-皮重：此功能用于同时显示毛重、净重和皮重。

数据库：内置数据库，用于存储数据和干燥方法纺织功能：确定线的名称、测量单位：Tex 、Td 、Nm 、Nc 。

干燥方式：提供干燥过程在不同温度下的曲线红外传感器：非接触，调用“去皮”或“打印”功能而不用接触天平触摸显示屏：此技术用户友好、易于使用、直观易懂。

蓝牙接口：可以连接蓝牙设备USB 接口：可连接 U 盘图：实时干燥过程可视化显示图密码：用户配置文件可以用密码保护内存：最多可以存储 5 种不同的干燥方案RECIPE STATRS 232G L P % WEIGH%UNITSLIMITS– +UNDERPCSACCUANIMALADDPEAKDENSITYCLOCK LANGBATTERYAANETLC-HREM-FRN S RECIPESTATUNDERACCULANGBATTERYAANETDATABASETEXTILETOUCHSENSMODESBLUETOOTHUSBATGRAPHNET DATABASETEXTILE TOUCH SENS MODES USB PASSWORDM E M OGRAPH ET DATABASE TEXTILE TOUCHSENSMODES USB PASSWORDM E M OGRAPH ABASETEXTILE TOUCHSENSMODESUSBPASSWORD M E M O6-7半微量天平M5-HPB系列可读性 0,01mg8-9半微量天平HPB和S HPB系列可读性 0,01mg10分析天平M系列可读性 0,0001g11精密天平MW和LW 系列可读性 0,001g12可读天平M和L系列可读性 0,01g13可读天平L系列可读性 0,1g14-15可读天平M5-RB 和RB系列可读性 0,01g-0,1g16-17水分测定仪i-Thermo和M5-Thermo 系列可读性 0,0001g-0,001g-0,01g18 可读天平S系列可读性 0,001g-0,01g-0,1g可选配件19-21水分测定仪4( n = 标准 q = 可选的 s = 仅限某些型号)5全自动内部校准M5-HPB-425i 420,01Ø 800,03± 0,08M5-HPB-625i 620,01Ø 800,03± 0,08M5-HPB-105i 1020,01Ø 800,05± 0,08M5-HPB-1265Di 62/1200,01/0,1Ø 800,03 / 0,1± 0,08 / ± 0,2M5-HPB-2285Di 82/2200,01/0,1Ø 800,04 / 0,1± 0,08/ ± 0,2M5-HPB-22105Di102/2200,01/0,1Ø 800,05 / 0,1± 0,08 / ± 0,2系列 - 可读性 0,01mg - 0,1mg型号最大秤量 (g)可读性[d](mg)秤盘尺寸(mm)重复性 (mg)线性误差 (mg)②②②②②②ADD G L P % WEIGH %UNITS LIMITS – +PCS ANIMAL PEAK DENSITY CLOCK LANG RECIPE STAT G L PUNDER ACCU PEAK CLOCK LANG BATTERY AANET DATABASE TEXTILE TOUCH MODES BLUETOOTH USB USB GRAPH PASSWORD M E M O RECIPE ADD G L P % WEIGH %LIMITS – +PCS ANIMAL PEAK DENSITY CLOCK LANG RECIPESTAT G L PUNDER ACCU CLOCK LANGBATTERY AANET DATABASE TEXTILE STAT BATTERY AANET DATABASE TEXTILE M5-M214Ai 2200,1Ø 800,1± 0,0003M5-M314Ai 3100,1Ø 800,1± 0,0003M5-HPB 414i4100,1Ø 800,1mg 如果重量 ≤ 220g 0,3mg 从 220g 到 310g 0,35mg 从 310g 到 410g ± 0,0005M5-HPB 514i 5100,1Ø 800,1mg 如果重量 ≤ 220g 0,3mg 从 220g 到 310g 0,35mg 从 310g 到 510g ± 0,0005M5-HPB 614i 6100,1Ø 800,1mg 如果重量 ≤ 220g 0,3mg 从 220g 到 310g 0,35mg 从 310g 到 610g± 0,0005ADDRS 232G L % WEIGH %UNITSLIMITS– +PCS ANIMALPEAK DENSITY LC-HR7附件TX-110 串行打印机 (AC030)用于固体和液体的密度工具包(AC002)串行到 USB 转换器(E1002))串行电缆，用于串行输出到打印机或电脑(E743)8 GB U盘(AC020)触摸屏手写笔(AC021)技术数据n 量程漂移(+10 … +30°C): +/– 2ppm/°Cn外形尺寸 长×宽×高(毫米):345×215×345n 称重室尺寸 长×宽×高(毫米):162×171×225n 电源 110-230 Vac, 50/60 Hz:输出 24 V /500 mA / 13 VAn 净重：7,2 千克静电消除器技术数据n 操作方式: 2分钟或连续运作最多8小时n 臭氧浓度: 0-0.05 ppm(距离离子源2 厘米)n 放电时间: 9 秒/5 厘米,13秒/10 厘米n 环境条件: 0-50°C，20-80% 空气湿度(无冷凝)n 交流适配器: 交流电 100-240V，50-60 HzA主要功能页面使称重操作更简单百分比称量移液器校准清晰简单的GLP功能输入静电消除器与天平整合:在实验室日常操作过程中，静电会在多种待称重的样品上聚积。

Data briefFor further information contact your local STMicroelectronics sales office.January 2012Doc ID 022709 Rev 11/11STEVAL-ISV002V23000 W photovoltaic converter for grid-connected applicationsFeatures■DC-DC input voltage: 200 V to 400 V ■DC-DC output voltage: 450 V ■DC-AC output voltage: 230 Vac ■Nominal output power: 3 kW ■DC-AC switching frequency: 17 kHz ■DC-DC switching frequency: 35 kHz ■Transformer turns ratio: 1.2■Grid voltage: 230 V rms +/-20%■Grid frequency: 50 Hz■Power factor: above 10%; rated power > 0.9■THD @ full load: < 5%■RoHS compliantDescriptionInterest in photovoltaic (PV) applications has grown exponentially in recent years. As PV systems require an electronic interface to beconnected to the grid or standalone loads, the PV market is increasingly appealing for many power electronics manufacturers.The STEVAL-ISV002V2 demonstration board implements a conversion system for PV applications with the aim of achieving highefficiency and significant reduction in production costs. It consists of a high-frequency isolated input power section which performs the DC-DC conversion, and an inverter section capable of delivering sinusoidal current at 50 Hz to the grid. The system operates with input voltages in the range of 200 V to 400 V , and is tied to the grid at 230 V rms , 50 Hz, through an LCL filter.Other unique characteristics of the proposed converter are integration level, decoupled active and reactive power control and flexibility towards the source.A fully digital control algorithm, including power management for grid-connected operation and MPPT (maximum power point tracking) algorithm, has been implemented on a dedicated control board, equipped with a latest-generation 32-bit (STM32) microcontroller.Schematic diagramsSTEVAL-ISV002V22/11Doc ID 022709 Rev 11 Schematic diagramsSTEVAL-ISV002V2Schematic diagramsDoc ID 022709 Rev 13/11Schematic diagrams STEVAL-ISV002V24/11 Doc ID 022709 Rev 1STEVAL-ISV002V2Schematic diagramsDoc ID 022709 Rev 15/11Schematic diagrams STEVAL-ISV002V26/11 Doc ID 022709 Rev 1STEVAL-ISV002V2Schematic diagramsDoc ID 022709 Rev 17/11Schematic diagrams STEVAL-ISV002V28/11 Doc ID 022709 Rev 1STEVAL-ISV002V2Schematic diagramsDoc ID 022709 Rev 19/11Revision history STEVAL-ISV002V210/11 Doc ID 022709 Rev 12 Revision historyTable 1.Document revision historyDate RevisionChanges24-Jan-20121Initial release.STEVAL-ISV002V2Please Read Carefully:Information in this document is provided solely in connection with ST products. STMicroelectronics NV and its subsidiaries (“ST”) reserve the right to make changes, corrections, modifications or improvements, to this document, and the products and services described herein at any time, without notice.All ST products are sold pursuant to ST’s terms and conditions of sale.Purchasers are solely responsible for the choice, selection and use of the ST products and services described herein, and ST assumes no liability whatsoever relating to the choice, selection or use of the ST products and services described herein.No license, express or implied, by estoppel or otherwise, to any intellectual property rights is granted under this document. If any part of this document refers to any third party products or services it shall not be deemed a license grant by ST for the use of such third party products or services, or any intellectual property contained therein or considered as a warranty covering the use in any manner whatsoever of such third party products or services or any intellectual property contained therein.UNL ESS OTHERWISE SET FORTH IN ST’S TERMS AND CONDITIONS OF SAL E ST DISCL AIMS ANY EXPRESS OR IMPL IED WARRANTY WITH RESPECT TO THE USE AND/OR SAL E OF ST PRODUCTS INCL UDING WITHOUT L IMITATION IMPL IED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE (AND THEIR EQUIVALENTS UNDER THE LAWS OF ANY JURISDICTION), OR INFRINGEMENT OF ANY PATENT, COPYRIGHT OR OTHER INTELLECTUAL PROPERTY RIGHT. UNL ESS EXPRESSL Y APPROVED IN WRITING BY TWO AUTHORIZED ST REPRESENTATIVES, ST PRODUCTS ARE NOT RECOMMENDED, AUTHORIZED OR WARRANTED FOR USE IN MILITARY, AIR CRAFT, SPACE, LIFE SAVING, OR LIFE SUSTAINING APPLICATIONS, NOR IN PRODUCTS OR SYSTEMS WHERE FAILURE OR MALFUNCTION MAY RESULT IN PERSONAL INJURY, DEATH, OR SEVERE PROPERTY OR ENVIRONMENTAL DAMAGE. ST PRODUCTS WHICH ARE NOT SPECIFIED AS "AUTOMOTIVE GRADE" MAY ONLY BE USED IN AUTOMOTIVE APPLICATIONS AT USER’S OWN RISK.Resale of ST products with provisions different from the statements and/or technical features set forth in this document shall immediately void any warranty granted by ST for the ST product or service described herein and shall not create or extend in any manner whatsoever, any liability of ST.ST and the ST logo are trademarks or registered trademarks of ST in various countries.Information in this document supersedes and replaces all information previously supplied.The ST logo is a registered trademark of STMicroelectronics. All other names are the property of their respective owners.© 2012 STMicroelectronics - All rights reservedSTMicroelectronics group of companiesAustralia - Belgium - Brazil - Canada - China - Czech Republic - Finland - France - Germany - Hong Kong - India - Israel - Italy - Japan - Malaysia - Malta - Morocco - Philippines - Singapore - Spain - Sweden - Switzerland - United Kingdom - United States of AmericaDoc ID 022709 Rev 111/11。

October 2009Doc ID 15599 Rev 21/15UM0696User manualPractiSPIN™.spmd demonstration systemconfiguration and set up guideIntroductionPractiSPIN™.spmd is a demonstration system that can be used with severalSTMicroelectronics stepper motor driver modules.The system consists of a graphical user interface (GUI) program which runs on an IBM-PC under windows, a common ST7-based interface board that communicates with the PC and the PractiSPIN™.spmd software via a serial COMM port, and a module-specificdemonstration board (target board) that connects to the ST7 interface board via a standard 34-pin ribbon cable interface, as shown in Figure 1.The module demonstration board connects to the motor and to a user-supplied DC power supply generally in the range of 12 to 48 VDC, plus a logical supply rated 5 VDC.The PractiSPIN™.spmd system is designed to operate the target module under the control of the PractiSPIN™.spmd software.Figure 1.The PractiSPIN™.spmd system block diagramContents UM0696Contents1System overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 2Starting PractiSPIN™.spmd . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53Stepper motor driver . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73.1Constant speed mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73.2Indexing mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 4STEVAL-SPMD250V1, STEVAL-SPMD250V2 . . . . . . . . . . . . . . . . . . . . . 10 5STEVAL-SPMD150V1, STEVAL-SPMD150V2 . . . . . . . . . . . . . . . . . . . . . 12 6Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 142/15 Doc ID 15599 Rev 2UM0696List of figures List of figuresFigure 1.The PractiSPIN™.spmd system block diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 Figure 2.PractiSPIN™ launch window . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 Figure 3.Calibration window . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 Figure 4.PractiSPIN™.spmd constant speed mode window . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 Figure 5.PractiSPIN™.spmd indexing mode window. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 Figure 6.STEVAL-SPMD250V1 / STEVAL-SPMD250V2 demonstration system. . . . . . . . . . . . . . . 10 Figure 7.STEVAL-SPMD250V1 / STEVAL-SPMD250V2 schematic . . . . . . . . . . . . . . . . . . . . . . . . 11 Figure 8.STEVAL-SPMD150V1 / STEVAL-SPMD150V2 demonstration system. . . . . . . . . . . . . . . 12 Figure 9.STEVAL-SPMD150V1 / STEVAL-SPDM150V2 schematic . . . . . . . . . . . . . . . . . . . . . . . . 13Doc ID 15599 Rev 23/15System overview UM06964/15 Doc ID 15599 Rev 21 System overviewThe purpose of this document is to illustrate the operation of the complete system made upby a module specific demonstration board (target board), the control board PractiSPIN™,the SW PractiSPIN™.spmd and a stepper motor. For details concerning PractiSPIN™,STEVAL-SPMD250V1, STEVAL-SPMD250V2, STEVAL-SPMD150V1 and STEVAL-SPMD150V2, please refer to the specific application notes.To be operated the target board needs two supply voltages and a stepper motor connectedto the proper connectors.Through the control board and friendly user interface the PractiSPIN™.spmd systemsupports the following measurements and demonstrations:●to drive the module with normal or half step sequence ●to select the current recirculation mode–slow decay –fast decay●to change the motor rotation –forward–reverse ●to fix the acceleration and deceleration ramp and the running speed ●to differentiate the motor current during the ramp–normal working mode –steady state modeA sequence of moving and waiting times can be fixed and repeated indefinitely.Note:For a detailed description of the control boards please refer to the PractiSPIN™ applicationnote.2 StartingPractiSPIN™.spmdSince the PractiSPIN™.spmd system is capable of supporting several moduledemonstration boards the user must first select the module that is evaluated.●Module demonstration board set up: configure the jumpers/switches on the targetboard and the control board as described in the paragraph for the specificdemonstration board being used.●Control board - PC connection: connect the control board to a serial COMM port of thePC via a standard (straight through) 9 pin D connector cable.●Powerup: energize the power supply●Start PractiSPIN™.spmd software: on the PC, start the PractiSPIN™.spmd program●Communication settings: click the drop down list under "port selection" and select theCOMM port being used. Baud rate and other communication parameters are fixed onboth sides of the link and do not need to be set.●Establish COMM link: click the "connect to ST7 hardware". At this point thePractiSPIN™.spmd software transmits several commands to the control board toinitialize the processor. The PractiSPIN™.spmd software reads the revision code of thefirmware currently stored in the Flash memory of the ST7 and determine if the correctversion of firmware resides in the ST7. If the PractiSPIN™.spmd software detects thata firmware update is necessary, either because there is an old version of firmware orthe firmware currently in the Flash memory is not the correct firmware for the motortype selected, one or more dialogue boxes appear asking if the program shouldproceed with the update. Accept the updates and the PractiSPIN™.spmd softwareautomatically updates the firmware. The system then initializes the settings to the laststored settings and open the appropriate PractiSPIN™.spmd software for the selectedtarget board.Figure 2.PractiSPIN™ launch windowAM04220v1●Calibrate current setting: when communication is established the user has the option toadjust the offset and maximum current settings. If this is the first time you use thesystem, calibration may be needed to adjust out the offset in the reference biascircuitry. Calibration ensures that the reference voltage provided to target modulefollows the PractiSPIN™.spmd software current settings. Calibration is a two-stepprocess; first the offset is adjusted then the maximum current is set. Clicking on"connect ST7 hardware" button, the calibration window appears.Doc ID 15599 Rev 25/156/15 Doc ID 15599 Rev 2Figure 3.Calibration window●To null out the offset, click on calibrate zero (for details please refer to the specific target board section).●To set the maximum current click on calibrate max (for details please refer to the specific target board section).●Click doneAM04221v1UM0696Stepper motor driver Doc ID 15599 Rev 27/153 Stepper motor driverAfter the system has established the connection to the control board, it initializes thesettings to the last stored settings and open the PractiSPIN™.spmd GUI. For the steppermotor, the system can operate in either a constant speed or positioning (indexing) mode.The constant speed mode can easily be used to see that the system is working.The stepper motor driving window, from which it is possible to select the motor workingconfiguration, appears.3.1 Constant speed modeFigure 4.PractiSPIN™.spmd constant speed mode window●Speed control screen: a large blue button at the bottom of the screen should read, "switch to indexing mode". If the button reads, "switch to speed control mode", click thebutton once to go to speed control mode.●Stepping mode: in the stepping mode box, select either normal or half step. Micro stepping mode is only available when using the STEVAL-SPMD150STP .●Device selection: in the device selection box, select the device being evaluated●Direction: in the direction box, click the toggle switch to pick forward or reverse. This is somewhat arbitrary since the direction sense of the motor is unknown. Once the motoris running, toggle this switch to reverse the motor direction if desired. To reverse themeaning of the forward and reverse designations, disable the motor (orange disablebutton at bottom of screen) and then swap the motor wires at either CN3 or CN4.●Decay mode: set the toggle switch to slow decay●Acceleration rate: set the acceleration rate to about 1000 steps per sec 2 (steps/sec 2).In the PractiSPIN™.spmd system all motion parameters are given in terms of the basicunits of steps and seconds: position in steps, velocity in steps/sec, andacceleration/deceleration in steps/sec 2. In order to relate these settings to rotations,RPM, and RPM/second it is necessary to know the number of steps (or half steps) perrotation for the stepper motor being used. A common value is 200 steps or 400 halfsteps per rotation.AM04222v1Stepper motor driver UM06968/15 Doc ID 15599 Rev 2●Running speed: set running speed to about 100 steps/sec ●Deceleration rate: set deceleration rate to about 1000 steps/sec 2●Acceleration current: set acceleration current to about 25%. This is an initial guess as to the required setting and may need further adjustment. Generally higher accelerationrate settings require higher acceleration current settings so that the stepper motor doesnot start to "slip poles" and fall behind the desired position. Since we have initially setthe acceleration rate setting quite low, 25% is probably adequate.●Running current: set the running current to 25%. In practice the running current can often be set to a lower value than the acceleration current since the torque requirementis generally less during the constant speed part of the move. A lower running currentsetting can help to keep the device and the motor running cooler.●Deceleration current: set the deceleration current to 25%. Since friction aids in decelerating the motor it may also be possible to set the deceleration current lower.●Holding current: set the holding current to 25%. Whenever the motor is stopped (after a run,) this level of current circulates in the motor so that it holds position against anymechanical disturbance. In the case of a strong static load (perhaps a gravity load ofsome sort) it may be necessary to increase this setting. If not much holding torque isrequired, then the setting can be reduced so that operating temperatures can be held toa minimum.Note:Holding current is turned off (bridge completely disabled) whenever the disable button isclicked.●Run: make sure that the motor is free to turn in either direction and click the run button. The motor should quickly come up to speed ((100 steps/sec)/(1000 steps/sec 2) = 0.1sec.). To change the motor direction, click the direction toggle switch. If the motor doesnot run click the stop button, increase all four current settings to 50%, and click runbutton. If the motor still does not run an oscilloscope and current probe should be usedto observe the motor current.●Stop: click stop to stop the motor After the basic operation of the system has been verified, the acceleration rates, top speed,and current settings can be adjusted to see how the motor responds.UM0696Stepper motor driverDoc ID 15599 Rev 29/153.2 Indexing modeFigure 5.PractiSPIN™.spmd indexing mode windowThe system can be switched to operate in the positioning (indexing) mode by clicking on"switch to indexing mode". In the indexing mode a new box appears on the right of thescreen. Y ou can enter up to twelve indexed movements in the box and the wait time betweeneach movement. When started, the software executes each movement by accelerating up tothe peak speed, moving the required number of steps and then decelerating back to a stopso that the total distance moved is the number of steps indicated, then wait the indicatedtime before starting the next movement. A negative number entered in the relative positioncauses the motor to run in the "reverse" direction.AM04223v1STEVAL-SPMD250V1, STEVAL-SPMD250V2UM069610/15 Doc ID 15599 Rev 24 STEVA L -SPMD250V1, STEVA L -SPMD250V2To make the STEVAL-SPMD250V1 and STEVAL-SPMD250V2 boards operative, performthe following simple steps:●Connect the boards to the control board by means of the 34-wires flat cable and the control board to the host PC.●Connect the stepper motor to the P3 and P4 connectors ●Put jumpers on JR1, JR2, JR3●Apply 5 V to P1 connector ●Apply motor voltage VS to P2 connector ●Launch the PractiSPIN™.spmd program on the host PC ●Click on "connect to ST7 hardware" and perform calibration–Click on calibrate zero and verify that VTP3 is zero.–Click on calibrate max and set the maximum current, corresponding to 100%current setting in the PractiSPIN™.spmd software, adjusting the RV1 trimmer onthe target board until the voltage on VTP3 corresponds to the motor current. Therelationship between voltage/current is V = 0.165 I motor .●Click done and enter "speed control mode" or "indexing mode"Figure 6.STEVAL-SPMD250V1 / STEVAL-SPMD250V2 demonstration system AM04224v1分销商库存信息:STMSTEVAL-SPMD250V2STEVAL-SPMD150V2。

IntroductionThe STEVAL-LLL002V1 evaluation kit consists of the STEVAL-LLL002M1 main board and the STEVAL-LLL002D1 USB-UART bridge.It has been designed to test and evaluate ALED1262ZT performance.The STEVAL-LLL002M1 is a LED array driver system evaluation board with local dimming and diagnostics for automotive applications. It is based on the ALED1262ZT 12-channel LED driver controlled through the STM8AF6266 microcontroller I²C interface.A 48 red LED matrix is driven by four ALED1262ZT LED drivers.The on-board A7986A DC-DC converter, accepting standard adapter input voltages with reverse polarity protection, provides the voltages and power for the board operation.The STEVAL-LLL002V1 evaluation kit jumpers simulate LED open circuit faults and the 4-pin SWIM connector is used to debug and develop the STM8AF6266 microcontroller firmware.The evaluation kit can operate in bus driven mode (BDM), standalone mode (SAM) and GUI mode.In the bus driven mode, the board is controlled via on-board push buttons and potentiometers. Commands to the ALED1262ZT driver are sent by STM8A microcontroller over I²C bus.In the standalone mode, the STEVAL-LLL002V1 evaluation kit is not controlled by the MCU and you can select two possible output configurations using OTP ½ SPDT switch (SW2).In the GUI mode, the board is connected to a PC via USB-UART bridge and you can observe and control various features of the driver through the graphical user interface.Figure 1.STEVAL-LLL002V1 evaluation kitGetting started with the evaluation kit for automotive rear lights with patternanimations based on ALED1262ZT and STM8AF6266UM2381User manual1Hardware description1.1STEVAL-LLL002M1 main boardThe STEVAL-LLL002M1 evaluation board includes four ALED1262ZT LED drivers, an 8-bit automotive grade MCU, a SWIM connector to program the MCU, 48 red LEDs, push buttons to switch modes, and potentiometers to control brightness and speed.The on-board A7986A DC-DC converter, accepting standard adapter input voltages (12 – 24 V), provides the voltages and power for the board operation.Figure 2.STEVAL-LLL002V1M main board (top side)Figure 3.STEVAL-LLL002V1M main board (bottom side)1.1.1Chip select (CS) one time programming (OTP)The STEVAL-LLL002M1 evaluation board has four ALED1262ZT drivers.The ALED1262ZT LED driver is provided with five one time programming (OTP) memory cells that can beprogrammed to provide a permanent address to the device, creating a total of 32 driver addresses, that is, at a given time, a maximum of 32 drivers can be connected to the to the MCU via I²C bus.Table 1. STEVAL-LLL002M1 evaluation board: ALED1262ZT addressesHardware descriptionOn-board J2 is used to select the ALED1262ZT device for OTP . The LED driver is given a particular command over I²C providing 18 V (±1 V) to be applied at the corresponding chip select (CS) pin.Note:For more information please refer to the ALED1262ZT datasheet on .1.2STEVAL-LLL002D1 USB-UART bridgeThe STEVAL-LLL002V1 evaluation kit is also equipped with a USB-UART bridge for the communication between PC and microcontroller.Figure 4. STEVAL-LLL002V1D (top side)Figure 5. STEVAL-LLL002V1D (bottom side)STEVAL-LLL002D1 USB-UART bridge1.3Evaluation kit block diagramFigure 6.STEVAL-LLL002V1 block diagram1.4STEVAL-LLL002V1 key devicesThe STEVAL-LLL002V1 main devices are:•A7986A : a high efficiency step down 250 kHz (programmable up to 1 MHz) switching regulator with max. 3 ADC output current. Input voltage varies from 4.5 to 38 V and also depends on the required output. It supports low dropout operation along with zero load current operation. Overcurrent and thermal protection are provided for safe board operation. It powers the red LEDs.•LM2931: an AEC-Q100 qualified 100 mA LDO regulator designed for automotive environments.•STM8AF6266: an automotive grade 8-bit microcontroller, featuring 10 MIPS at 16 MHz CPU, advancetimers, UART, ADC, robust I/O's, nested interrupt controller.•L78L33ACUTR : a three terminal positive regulator. It gives output current up to 100 mA and output voltageof 3.3 V. The L78L series uses as Zener diode/resistor combination replacement, resulting in a lower quiescent current and lower noise.•Diode bridge: at the power supply input ensures board operation regardless of the input voltage polarity.•48 red SMD LEDs mounted in a 12x4 matrix to display different patterns. The minimum luminous intensity ofa LED is around 3.55 cd with wide viewing angle of 120º and wavelength of 623 nm.Evaluation kit block diagramSTEVAL-LLL002V1 connections 2STEVAL-LLL002V1 connections2.1Power supplyThe STEVAL-LLL002V1 evaluation kit is powered by standard 12–24 V DC power adapter.The power source must deliver sufficient current depending on the input voltage for proper functioning.Reverse voltage protection and input surge protection are provided to avoid any damage.2.2Microcontroller SWIMThe STEVAL-LLL002V1M board is equipped with a standard 4-pin SWIM connector allowing to debug anddevelop the STM8AF6266 microcontroller firmware.2.3Jumpers for LED open-circuit simulationLED errors can be simulated by using J5 to J8 jumpers.Removing a jumper on J5, J6, J7 and J8 causes LED open-circuit error in D48, D49, D50 and D51 respectively.These simulated errors can be detected in error detection mode: the defective LED is signaled by lighting theadjacent LED on the board in standalone mode, and by flashing the corresponding light in the LED map in GUImode.2.4USB-UART bridgeThe STEVAL-LLL002V1 communicates with the GUI via the USB-UART board, which acts as the bridge betweenSTM8AF6266 and your PC.It communicates with the main board via UART interface and with PC via USB.Operation modes 3Operation modes3.1Bus driven modeIn this mode, STEVAL-LLL002V1 is controlled via on-board push buttons and potentiometers.Commands to the ALED1262ZT LED driver are sent by STM8AF6266 microcontroller through I²C interface.After DC input is applied for the first time, the board goes into free running mode and displays all patterns andmodes, one after another.You can exit from this free running mode using the BCK or FWD button.3.1.1FeaturesIn bus driven mode, the board features:•Pre-configured patterns (with adjustable brightness/speed) as rolling text, wave effect, super car scanning, dot sequence, etc.•On-board push buttons to switch between the demos•Potentiometers as sliders to control the pattern speed or brightness•Open circuit error simulation using open circuit jumpers (J5-J8)•Jumper to switch from bus driven mode to standalone mode (J4)•OTP ½ switch (SW2) to choose between two different predefined pattern in SAM mode3.1.2Normal modeThe STEVAL-LLL002V1 evaluation kit enters the bus driven mode (BDM) when powered.In this mode, the MCU sends data over I²C bus to the ALED1262ZT LED driver.Note:To operate in BDM mode, jumper J4 should be placed.The bus driven mode main controls are:•Push-buttons for transition among different demos:–BCK button: to switch on the previous pattern or mode–FWD button: to switch on the next pattern or mode•Potentiometers:–Brightness and speed control: on rotating potentiometer clockwise/anticlockwise, brightness/speed among transitions increases/decreases.•Open circuit error detection to detect LED failureNote: On powering up, the evaluation board goes into free running mode displaying pattern changes after a fixedinterval of time. You can exit from this mode by pressing FWD or BCK push buttons.The evaluation board displays different patterns in BDM:1.Dot Sequence Rail2.Back Light (all LEDs on)3.Super Car Scanning Effect - I4.Alphanumeric Flashing5.Super Car Scanning Effect - II6.Alphanumeric Rolling7.Animation – 3D8.Horizontal Wave9.Pattern – I10.Vertical Wave11.Diagonal WaveBus driven mode12.Pattern – II13.Error DetectionNote:In Alphanumeric Flashing Pattern, you can control the speed only.In Super Car Scanning Effect – I, Super Car Scanning Effect – II, Animation – 3D, Pattern – I and Pattern – IIyou cannot control brightness as the ALED1262ZT PWM (7-bit individual channel control) feature is enabled.3.1.3Error detectionALED1262ZT driver is capable of detecting error for open circuit.The STEVAL-LLL002V1 evaluation kit provides the option to simulate and detect errors by entering the errordetection mode using FWD or BCK buttons.Removing jumpers J5, J6, J7 and J8 causes LED open circuit error in D48, D49, D50 and D51 respectively.The defective LED is signaled by switching on the adjacent LED.Table 2. STEVAL-LLL002V1 error detection modeFigure 7. STEVAL-LLL002V1 evaluation kit: error detection mode (J6 and J7 removed)3.2Standalone mode (SAM)The STEVAL-LLL002V1 enters the SAM mode when the driver supply falls belows 3 V (removing jumper J4 that is disconnecting the ALED1262ZT LED driver).In standalone mode configuration, the device is not controlled by the MCU or a controller board.You can select two possible output configurations using OTP ½ SPDT switch (SW2).Figure 8.STEVAL-LLL002V1 evaluation kit: standalone mode (configuration 1)Figure 9.STEVAL-LLL002V1 evaluation kit: standalone mode (configuration 2)3.2.1FeaturesThe board enters the standalone mode by removing J4.This mode mainly features:•ALED1262ZT working without external controller •Two different ouptus •OTP ½ switch (SW2) to choose a configuration3.3GUI modeThe board can be connected to a PC through a USB-UART bridge using the graphical user interface (GUI) to control and evaluate the ALED1262ZT driver features.3.3.1FeaturesAll the bus driven mode features can also be controlled via GUI that manages also:•Global brightness control to change the brightness of all the channels •Frame programming mode and four predefined presets with variable transition time between framesStandalone mode (SAM)•Open circuit error detection in "no loop" and in 1 s and 2 s (approx.) loops•Read/write configuration register•Individual channel brightness control3.3.2GUI setupTo use the STEVAL-LLL002V1 GUI, you have to install the virtual COM port (VCP) driver on your PC/laptop byfollowing the procedure below.Step 1.Install the .exe file on your PC.The GUI appears in your program list.Step 2.If the VCP driver is not installed, install it from ...\Program Files\ STMicroelectronics\LED Driver Demo \ST VCP Driver. A 32-bit version and a 64-bit version are included in the setup.On launching the GUI, the initial screen appears as shown below.Figure 10. STEVAL-LLL002V1 evaluation kit: GUI initial screenStep 3.Connect the STEVAL-LLL002M1 to the PC and power it up.Step 4.Press [Connect].The GUI identifies the board and automatically establishes a connection (COM3 is shown as anexample in the picture above), otherwise it prompts the user to select the port to which the board isconnected.Step 5.If the GUI does not automatically identify the board, choose the port manually and press [Select].When the GUI is able to interact with the board, a "Port is open” message is shown.3.3.3Modes3.3.3.1Basic modeThe STSW-LLL002GUI basic mode mainly features:•Replication of on-board control buttons to select different modes from the GUI•Buttons to enable/disable on-board push buttons•Open circuit error detection with different frequencies•Adjustable global brightness for all the channels•Control registers write/read (BDM_Conf 1)•Various flag status reading (BDM_status)The basic mode has five sections to address different requirements:•Button control•Error detection•Brightness control for all channels•Configuration registers•Individual channel ON/OFF controlFigure 11. STSW-LLL002GUI basic mode3.3.3.1.1Button controlThe control buttons replicate the on-board BCK and FWD buttons and are used to toggle among preconfigureddemos.The on-board buttons can be enabled or disabled by pressing [Enable] or [Disable] respectively.3.3.3.1.2Error detectionThe error detection section demonstrates open circuit error (if any) present in the 12x4 LED matrix.Error detection frequency can be selected from three options:•No loop - error detection is performed just once and the results are displayed till any other button is pressed• 1 second loop - error detection is performed every 1 s by the drivers and the results are updated in real-time• 2 second loop - same as 1 second loop but error detection is performed every 2 s3.3.3.1.3Brightness control for all channelsBrightness of all the channels is simultaneously changed by varying brightness control for all channel slider.Brightness can be varied in 256 steps (5% to 100%).3.3.3.1.4Configuration registersThe configuration register section represents two registers for the ALED1262ZT LED driver:•BDM_Conf 1: is common for all ALED1262ZT LED drivers. You can set or reset different bits of the registers.•BDM_status: gives the status information for a particular LED driver selected from the drop down bar.For further details, refer to the ALED1262ZT datasheet on .Figure 12. ALED1262ZT configuration register3.3.3.2Advanced modeThe advanced mode section displays the individual channel brightness control (0% to 100%).The brightness of each channel can be adjusted through a 7 bit PWM grayscale brightness control according tolocal dimming register PWM_gain_x.You can change the brightness using the scroll bars put in a 12x4 pattern.Figure 13. STSW-LLL002GUI advanced mode3.3.3.3Frame programming modeThis mode features:•Frame programming to display any arbitrary pattern up to 20 frames with variable transition speed•Four preconfigured patterns for quick visualization of frame programming mode on the STEVAL-LLL002V1 evaluation kitFrame programming displays user defined patterns in round robin sequence on the evaluation board. This modecontains a set of 20 (maximum) independent frames and each frame represents one instance of the board LEDs.The frames can be designed by the user or you can select preconfigured frame patterns using [Presets].Transition time among frames in milliseconds is set by the value in the [Transition Time] text box.Figure 14. STSW-LLL002GUI frame programming mode3.3.3.3.1Frame designA frame on the STSW-LLL002GUI represents LEDs on the evaluation board in a similar fashion. There are amaximum of 20 frames (00 to 19) to be set using [Set Frame Count]. To design the frames and demonstratethem on the evaluation board follow the procedure below.Step 1.Click on the LEDs to configure them.Step 2.Select the desired brightness using [Frame Brightness].Step 3.Press the [Play] button for the STSW-LLL002GUI sequence of frames to visualize the whole pattern to be displayed on the board.Step 4.Set the required transition time between the frames and press [Program].Note:Transition time has to be set between 10 to 10000 milliseconds. If a wrong value in entered in the box, the color of the text box changes to red and no command is sent to the board.3.3.3.3.2Using preconfigured frame patternsIn frame programming mode, four preconfigured frame patterns called Presets are provided.Preset1, Preset2, Preset3 and Preset4 can be loaded by clicking on the corresponding preset button.Figure 15. STSW-LLL002GUI frame programming mode Preset1Figure 16. STSW-LLL002GUI frame programming mode Preset2Figure 17. STSW-LLL002GUI frame programming mode Preset3Figure 18. STSW-LLL002GUI frame programming mode Preset44Schematic diagramsFigure 19.STEVAL-LLL002M1 circuit schematicUM2381Schematic diagramsFigure 20.STEVAL-LLL002D1 circuit schematicUART_TX_USB 32CONNECTORGND1J6USB_UART_ConnectorUART_RX_USB 4VDDUM2381Schematic diagrams5Bill of materialsTable 3. STEVAL-LLL002V1M bill of materialsTable 4. STEVAL-LLL002V1M bill of materials6LayoutFigure 21.STEVAL-LLL002V1M layout: top layerFigure 22.STEVAL-LLL002V1M layout: bottom layerLayout7Thermal behaviorThe ALED1262ZT is available in a TSSOP24-EP package (mounted on the evaluation board) with 37.5 °C/Wthermal resistance.The average forward voltage drop of red channels is 2 V and the maximum channel current is configured for 42.5mA.The STEVAL-LLL002V1 evaluation kit thermal image at the ≅45 mA current in all the channels are shown below.Figure 23. STEVAL-LLL002V1 thermal layout at 12 V DC input (top side)Figure 24. STEVAL-LLL002V1 thermal layout at 12 V DC input (bottom side)Figure 25. STEVAL-LLL002V1 thermal layout at 20 V DC input (top side)Figure 26. STEVAL-LLL002V1 thermal layout at 20 V DC input (bottom side)Revision historyTable 5. Document revision historyContents1Hardware description (2)1.1STEVAL-LLL002M1 main board (2)1.1.1Chip select (CS) one time programming (OTP) (2)1.2STEVAL-LLL002D1 USB-UART bridge (3)1.3Evaluation kit block diagram (3)1.4STEVAL-LLL002V1 key devices (4)2STEVAL-LLL002V1 connections (5)2.1Power supply (5)2.2Microcontroller SWIM (5)2.3Jumpers for LED open-circuit simulation (5)2.4USB-UART bridge (5)3Operation modes (6)3.1Bus driven mode (6)3.1.1Features (6)3.1.2Normal mode (6)3.1.3Error detection (7)3.2Standalone mode (SAM) (7)3.2.1Features (8)3.3GUI mode (8)3.3.1Features (8)3.3.2GUI setup (9)3.3.3Modes (10)4Schematic diagrams (15)5Bill of materials (17)6Layout (21)7Thermal behavior (22)Revision history (25)List of tablesTable 1. STEVAL-LLL002M1 evaluation board: ALED1262ZT addresses (2)Table 2. STEVAL-LLL002V1 error detection mode (7)Table 3. STEVAL-LLL002V1M bill of materials (17)Table 4. STEVAL-LLL002V1M bill of materials (19)Table 5. Document revision history (25)List of figuresFigure 1. STEVAL-LLL002V1 evaluation kit (1)Figure 2. STEVAL-LLL002V1M main board (top side) (2)Figure 3. STEVAL-LLL002V1M main board (bottom side) (2)Figure 4. STEVAL-LLL002V1D (top side) (3)Figure 5. STEVAL-LLL002V1D (bottom side) (3)Figure 6. STEVAL-LLL002V1 block diagram (4)Figure 7. STEVAL-LLL002V1 evaluation kit: error detection mode (J6 and J7 removed) (7)Figure 8. STEVAL-LLL002V1 evaluation kit: standalone mode (configuration 1) (8)Figure 9. STEVAL-LLL002V1 evaluation kit: standalone mode (configuration 2) (8)Figure 10. STEVAL-LLL002V1 evaluation kit: GUI initial screen (9)Figure 11. STSW-LLL002GUI basic mode (10)Figure 12. ALED1262ZT configuration register (11)Figure 13. STSW-LLL002GUI advanced mode (11)Figure 14. STSW-LLL002GUI frame programming mode (12)Figure 15. STSW-LLL002GUI frame programming mode Preset1 (12)Figure 16. STSW-LLL002GUI frame programming mode Preset2 (13)Figure 17. STSW-LLL002GUI frame programming mode Preset3 (13)Figure 18. STSW-LLL002GUI frame programming mode Preset4 (14)Figure 19. STEVAL-LLL002M1 circuit schematic (15)Figure 20. STEVAL-LLL002D1 circuit schematic (16)Figure 21. STEVAL-LLL002V1M layout: top layer (21)Figure 22. STEVAL-LLL002V1M layout: bottom layer (21)Figure 23. STEVAL-LLL002V1 thermal layout at 12 V DC input (top side) (22)Figure 24. STEVAL-LLL002V1 thermal layout at 12 V DC input (bottom side) (23)Figure 25. STEVAL-LLL002V1 thermal layout at 20 V DC input (top side) (23)Figure 26. STEVAL-LLL002V1 thermal layout at 20 V DC input (bottom side) (24)IMPORTANT NOTICE – PLEASE READ CAREFULLYSTMicroelectronics NV and its subsidiaries (“ST”) reserve the right to make changes, corrections, enhancements, modifications, and improvements to ST products and/or to this document at any time without notice. Purchasers should obtain the latest relevant information on ST products before placing orders. ST products are sold pursuant to ST’s terms and conditions of sale in place at the time of order acknowledgement.Purchasers are solely responsible for the choice, selection, and use of ST products and ST assumes no liability for application assistance or the design of Purchasers’ products.No license, express or implied, to any intellectual property right is granted by ST herein.Resale of ST products with provisions different from the information set forth herein shall void any warranty granted by ST for such product.ST and the ST logo are trademarks of ST. For additional information about ST trademarks, please refer to /trademarks. All other product or service names are the property of their respective owners.Information in this document supersedes and replaces information previously supplied in any prior versions of this document.© 2019 STMicroelectronics – All rights reserved。

March 2009Rev 21/11STEVAL-TDR007V13 stage RF power amplifier demonstration board using:PD57002-E, PD57018-E, 2 x PD57060-EFeatures■N-channel enhancement-mode lateral MOSFETs■Excellent thermal stability ■Frequency: 1030 MHz ■Supply voltage: 36 V ■Peak power: 200 W typical ■Input power: 23 dBm ■Harmonics < -45 dBc ■Rise and fall time < 100 ns ■RoHS compliantDescriptionThe STEVAL-TDR007V1 is a 200 W RF power amplifier intended for IFF - 1030 MHz interrogator using PD57002-E + PD57018-E + 2 x PD57060-E N-channel lateral MOS field-effect transistors. STEVAL-TDR007V1 is designed in cooperation with ETSA in France.Table 1.Device summaryOrder codeSTEVAL-TDR007V1Contents STEVAL-TDR007V1 Contents1Electrical data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31.1Maximum ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 2Electrical characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 3Circuit schematic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 4Circuit layout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 5Package mechanical data:PD57002-E, PD57018-E, PD57060-E . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65.1Mounting indications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 6Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 102/11STEVAL-TDR007V1Electrical data3/111 Electrical data1.1 M aximum ratings2 Electrical characteristicsT A = +25 o C, V DD = 36 V, I dq = 100 mA, Freq. = 1030 MHz, PW = 32 μs, DC = 2.5 %Table 2.Absolute maximum ratingsSymbol ParameterValue Unit V DD Supply voltage 36V I D Drain current1.0A T CASE Operating case temperature +80°C T AMax. ambient temperature-10 to +50°CTable 3.Electrical specificationSymbol Test conditionsMin Typ MaxUnit P OUT @ P IN = 23 dBm 5253dBm IRL @ P IN = 23 dBm -10dB I TOTAL@ P IN = 23 dBm500600mA Rise andFall time @ P IN = 23 dBm100ns Power droop (1)1.1000 µF connected to 36 V supply pin@ P IN = 23 dBm0.21dB Harmonics @ P IN = 23 dBm-60-45dBcCircuit schematic STEVAL-TDR007V14/113 Circuit schematicFigure 1.Circuit schematicSTEVAL-TDR007V1Circuit layout5/114 Circuit layoutFigure 2.Circuit layoutPackage mechanical data: PD57002-E, PD57018-E, PD57060-E STEVAL-TDR007V16/115Package mechanical data:PD57002-E, PD57018-E, PD57060-EIn order to meet environmental requirements, ST offers these devices in different grades of ECOPACK ® packages, depending on their level of environmental compliance. ECOPACK ® specifications, grade definitions and product status are available at: . ECOPACK is an ST trademark.STEVAL-TDR007V1Package mechanical data: PD57002-E, PD57018-E, PD57060-E7/115.1 M ounting indicationsFigure 3.PowerSO-10 mounting indicationsFigure 4.Recommended heat profile / reflow solderingMetal-backed boardEpoxy FR4 boardPackage mechanical data: PD57002-E, PD57018-E, PD57060-E STEVAL-TDR007V1Table 4.PowerSO-10RF formed lead (gull wing) mechanical dataDim.mm.InchMin Typ Max Min Typ Max A100.050.10.0.00190.0038A2 3.4 3.5 3.60.1340.1370.142A3 1.2 1.3 1.40.0460.050.054A40.150.20.250.0050.0070.009a0.20.007b 5.4 5.53 5.650.2120.2170.221c0.230.270.320.0080.010.012D9.49.59.60.3700.3740.377D17.47.57.60.2900.2950.298E13.8514.114.350.5440.5550.565E19.39.49.50.3650.370.375E27.37.47.50.2860.2920.294E3 5.9 6.1 6.30.2310.240.247F0.50.019G 1.20.047L0.81 1.10.0300.0390.042R10.250.01R20.80.031T 2 deg 5 deg8 deg 2 deg 5 deg8 degT1 6 deg 6 degT210 deg10 degNote:Resin protrusions not included (max value: 0.15 mm per side)8/11STEVAL-TDR007V1Package mechanical data: PD57002-E, PD57018-E, PD57060-E9/11Figure 6.PowerSO-10RF tape and reelRevision history STEVAL-TDR007V110/116 Revision historyTable 5.Document revision historyDate RevisionChanges01-Jul-20081Initial release 24-Mar-20092Updated coverpageSTEVAL-TDR007V1Please Read Carefully:Information in this document is provided solely in connection with ST products. STMicroelectronics NV and its subsidiaries (“ST”) reserve the right to make changes, corrections, modifications or improvements, to this document, and the products and services described herein at any time, without notice.All ST products are sold pursuant to ST’s terms and conditions of sale.Purchasers are solely responsible for the choice, selection and use of the ST products and services described herein, and ST assumes no liability whatsoever relating to the choice, selection or use of the ST products and services described herein.No license, express or implied, by estoppel or otherwise, to any intellectual property rights is granted under this document. If any part of this document refers to any third party products or services it shall not be deemed a license grant by ST for the use of such third party products or services, or any intellectual property contained therein or considered as a warranty covering the use in any manner whatsoever of such third party products or services or any intellectual property contained therein.UNLESS OTHERWISE SET FORTH IN ST’S TERM S AND CONDITIONS OF SALE ST DISCLAIM S ANY EXPRESS OR IM PLIED WARRANTY WITH RESPECT TO THE USE AND/OR SALE OF ST PRODUCTS INCLUDING WITHOUT LIM ITATION IM PLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE (AND THEIR EQUIVALENTS UNDER THE LAWS OF ANY JURISDICTION), OR INFRINGEMENT OF ANY PATENT, COPYRIGHT OR OTHER INTELLECTUAL PROPERTY RIGHT. UNLESS EXPRESSLY APPROVED IN WRITING BY AN AUTHORIZED ST REPRESENTATIVE, ST PRODUCTS ARE NOT RECOMMENDED, AUTHORIZED OR WARRANTED FOR USE IN MILITARY, AIR CRAFT, SPACE, LIFE SAVING, OR LIFE SUSTAINING APPLICATIONS, NOR IN PRODUCTS OR SYSTEMS WHERE FAILURE OR MALFUNCTION MAY RESULT IN PERSONAL INJURY, DEATH, OR SEVERE PROPERTY OR ENVIRONMENTAL DAMAGE. ST PRODUCTS WHICH ARE NOT SPECIFIED AS "AUTOMOTIVE GRADE" MAY ONLY BE USED IN AUTOMOTIVE APPLICATIONS AT USER’S OWN RISK.Resale of ST products with provisions different from the statements and/or technical features set forth in this document shall immediately void any warranty granted by ST for the ST product or service described herein and shall not create or extend in any manner whatsoever, any liability of ST.ST and the ST logo are trademarks or registered trademarks of ST in various countries.Information in this document supersedes and replaces all information previously supplied.The ST logo is a registered trademark of STMicroelectronics. All other names are the property of their respective owners.© 2009 STMicroelectronics - All rights reservedSTMicroelectronics group of companiesAustralia - Belgium - Brazil - Canada - China - Czech Republic - Finland - France - Germany - Hong Kong - India - Israel - Italy - Japan - Malaysia - Malta - Morocco - Singapore - Spain - Sweden - Switzerland - United Kingdom - United States of America11/11。

Service Diagram Tech NotesScalpel ™-DTSwiss SSD210L Rear ShockPage 1of 1TN001.PDFAugust 2003Publication TitlePublication No.We haveon page 2.You can also view it onlineSCHWEIZSWITZERLANDSUISSEDT Swiss AG Solothurnstrasse 1Postfach 6023CH-2500 Biel/Bienne 6 Phone:+41 32 344 79 30 Fax:+41 32 341 91 52e-mail:**************** DEUTSCHLANDGERMANYALLEMAGNEDT SwissCustomer Support Deutschland Hegnerweg 17D-71101 SchönaichPhone:+49 7031 410 18 56 Fax:+49 7031 410 18 57 e-mail:********************** FRANKREICHFRANCEFRANCEDT SwissCentre SAV FranceLes grandes ferragesBP 11F-84120 Beaumont de Pertuis Phone:+33 680 249 278 Fax:+33 490 080 019e-mail:**********************ITALIENITALYITALIEBike Suspension CenterVia Monte Leone 4I-39010 CermesPhone:+39 0473 563 107Fax:+39 0473 559 630e-mail:************ÖSTERREICHAUSTRIAAUTRICHEB & S Bike + SportUntersee 153A-4823 SteegPhone:+43 6135 6409Fax:+43 6135 640914e-mail:*****************GROSSBRITANNIENGREAT BRITAINGRANDE-BRETAGNEMadisonBurnell House8 Stanmore HillStanmoreGB-Middlesex HA7 3BQPhone:***********Fax:+44 20 8385 3443e-mail:**************************NIEDERLANDE / BELGIEN / LUXEMBURGNETHERLAND / BELGIUM / LUXEMBURGPAYS-BAS / BELGIQUE / LUXEMBOURGICC ServiceWeststraat 42NL-4527 BT AardenburgPhone:+31 117 49 28 20Fax:+31 117 49 28 35e-mail:****************SPANIENSPAINESPAGNEServicio tecnico DT SwissC / Pozas 36 - 38E-28200 S.L. EscorialPhone:+34 91 890 58 97Fax:+34 91 890 02 69e-mail:***********************VEREINIGTE STAATEN VON AMERIKAUNITED STATES OF AMERICAÉTATS-UNIS D'AMÉRIQUEDT Swiss Inc.2493 Industrial Blvd.USA-Grand Junction / CO 81505Phone:+1 970 242 9232Fax:+1 970 244 8918e-mail:*******************B E D I E N U N G S A N L E I T U N G U N DG A R A N T I E B E S T I M M U N G E N(E U R O P A)U S E R’S M A N U A L A N D W A R R A N T Y(E U R O P E/U S A)M O D E D’E M P L O I E TD I S P O S I T I O N S DE G A R A N T I E(E U R O P E)If your DT Swiss LRCS isstill not working properly, contact yourlocal dealer or our national DT SwissService Centre.Prior removing thelockout shaft, the lockout lever mustbe switched to the lockout position,to prevent internal damage of therear shock!U S E R'S M A N U A L A N D W A R R A N T Y(E U R O P E/U S A)Thank you for choosing DT Swiss LRCS (L ockout R emote C ontrol S ystem)! You have bought a product of best Swiss quality and innovative technology.Please read the complete user's manual attentively before installing or using the DT Swiss LRCS! The manual has to be given to every rider using the unit.The DT Swiss LRCS is a remote control for the DT Swiss SSD 210L rear shock, and is only to be used as such. Do not use the DT Swiss LRCS or any of its components as a tool or toy or for anything else than described in the user's manual.Compliance with the following instructions concerning assembly and maintenance of the DT Swiss LRCS is imperative for proper and accident-free operation. Disregarding these instructions can cause accidents with serious injuries. Functional limitations of the DT Swiss LRCS,which occur because the instructions in this document were not followed correctly, can neither be viewed nor claimed as a manufacturing fault. In addition the manufacturer's guarantee is void under such circumstances.A S S E MB L YIf the DT Swiss LRCS is not assembled correctly or is improperly maintained it is dangerous and may cause accidents with serious injuries.We strongly recommend having the DT Swiss LRCS assembled and maintained by an experienced expert.Compliance with the following instructions concerning assembly of the DT Swiss LRCS is imperative for proper and accident-free operation. Disregarding these instructions can cause accidents with serious injuries.Functional limitations of the DT Swiss LRCS, which occur because the instructions in this document were not followed correctly, can neither be viewed nor claimed as a manufacturing fault. In addition the manufacturer's guarantee is void under such circumstances.If you encounter uncertainties or difficulties, please contact a national DT Swiss Service Centre,for assembly and maintainance of the DT Swiss LRCS by an experienced expert.IMPORTANT!IMPORTANT!IMPORTANT!IMPORTANT!CAUTION!1234678101213The DT Swiss LRCS is designed for the use with the DT Swiss SSD 210L rear shock. The lockout lever has been optimised for the use with Shimano Rapidfire® and Dual Control®-shifters. Using the lockout lever in combination with SRAM Grip Shift®-shifters could cause problems. Using the lockout lever in combination with SRAM Grip Shift®- shifters could cause problems.C O M P A T I B I L I T I E SThe DT Swiss LRCS requires up to ¾" of handlebar width without bends. Please check your handlebars for the required clearance on the left side of the right shifter before assembling.IMPORTANT!On some handlebars you can simplify the assembly of the lockout lever by gently loosening the Shimano Rapidfire® Optical Gear Display. Remember to re-tighten it again after finishing the lockout lever installation!Prior to the assembly remove the rear shock from the bike according to the SSD 210L user's manual. During the whole assembly of the DT Swiss LRCS the rear shock does not get disassembled.A) Check completeness of the required parts.B) If you own a DT Swiss SSD 210L rear shock with the new lockout shaft, skip to step 8.Remove the old lockout pin.CAUTION!Release the locking screw by using a2 mm Allen key.Remove shaft and lever.Add a tiny amount of Loctite® screwlock to the screw. Screw in the screw allthe way.911Release the screw ¼ of a turn.Clip on the DT Swiss LRCS socket(the internal "nose" must snap in).Screw in the M3x20 screw with a2.5 mm Allen key.Mind the low tighteningtorque : Max. 0.6 Nm (5 InLbs)!CAUTION!Place the cable stop in the way thatworks best for your bike.Tight the M2.5x8 screw by using a1.5 mm Allen key.Mind the low tighteningtorque : Max. 0.4 Nm (3 InLbs)!Place the spring’s open end into the leftbore.1415Put on the DT Swiss LRCS disc orientedaccording to the sketch and press it oncompletely. Next lift it to create a gap ofapprox. 8.5 mm, so that the disc’s lowerend may slide over the upper end of thedisc stop nose.Put in the 6 mm Allen key and turnright 270°, press down the disc and letit snap back against the disc stop nose.Tighten the M4x6 screw by using a3 mm Allen key.Mind the thigtening tor-que: Max. 1.3 Nm (11 InLbs)!CAUTION!16Reassemble the shock according to theDT Swiss SSD 210L owner's manual.Make sure the DT SwissLRCS won’t contact any part of the frameor the seatpost whilst using the bike.CAUTION!17181920Place the bracket behind the handle barand under the gear display.Slip on the lever so it is aligned with thebracket.A)Tighten the internal headless M5x10screw by using a 2.5 mm Allen key.Make sure that theDT Swiss LRCS lever, shifter and thebrake lever do not interfere with eachother or hinder you in any way duringoperation!B)The function of the brakes or shiftersshould not be disturbed!CAUTION!Position and shorten the outer cable(not included in set) according to therequirements of your bike. Make sure tohave minimum friction in your cablerouting (use a gore tex-cable ®).Check the clearance ofthe outer cables by flipping the handlebar completely to each side!CAUTION!21Insert the derailleur cable as shown below.Screw on the front cap.22M4x6M3x20M2.5x8A)B)original sizeOLD NEW3.4.5Grease the new lockout shaft and pressit in as shown below.Mind the alignement!correctwrong6.7.OPTIONAL:lead pipe(art.-no.d.3.00.8187)A)A S S E M B L Y D T S W I S S L R C S W I T H T H E R E A R S H O C KB)A S S E M B L Y O F T H E D T S W I S S L R C S L E V E Rcorrectforkrear shockforkrear shock forkrear shockSlip the cable through the hole in theDT Swiss LRCS disc, and then pull thecable to avoid play. The DT Swiss LRCSlever must be positioned in the "open"position!23Tighten the headless screw by using a1.5 mm Allen key.24CAUTION!Check functions:A) Push up the main lever until the release lever snaps in. Close the lockout.B) Press the release lever until the main lever flips down. Open the lockout.2523.24.A)B)C)F U N C T I O N A L T E S T D T S W I S S L R C S26Release the headless screw for two turnsand create a gap of 1 - 3 mm betweendisc stop nose an disc by using a 6 mmAllen key. Pull the cable and tighten theheadless screw again as mentioned instep 24 without releasing the 6 mmAllen key. Repeat step 23 to 25.Does the DT Swiss LRCS works? . . . . . . . . . . .Yes:Skip to step 27.. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .No:Skip to step 26.27Cut the cable and...28...add the cable end.29Place the black plastic pin in the centreof the front disc.M A I N T E N A N C EA)Release the plastic pin.B)Unscrew the front disc with a 5 mm Allen key.C)Grease the indicated inner portions of the lever as well as shown on the right.D)Close the DT Swiss LRCS lever as mentioned in step 22.E)Check functions as mentioned in step 25.W A R R A N T Y(E U R O P E)The purchaser has the right to claims under the guarantee as covered by general law, against the sales contract partner (retailer). In addition to the general guaranteerequired by law, DT Swiss LTD with head office in Biel/Switzerland, guarantees the DT Swiss LRCS for two years (24 months) from the date of purchase.There shall be no claim under the guarantee for:-normal wear of parts, subject to wear (glidings, seals, sliding surfaces, shifters etc.)- incorrect assembly or in combination with products that do not fit- incorrect maintenance, incorrect repair or alteration- incorrect use, bad treatment, misuse, negligence, carelessness during installation, maintenance or use,commercial use or use in cycling competitions- delivery and transport damageCAUTION!DT Swiss LTD shall reject any liability for both indirect damage caused by accidents and consequential damage. In case of warranty repair/replacement please contact thedealer where you bought the product. DT Swiss LRCS which have to be checked, can be sent postage paid to a DT Swiss Service Centre.Legal venue and place of performance is Biel (Switzerland). Swiss law shall apply. Subject to technical changes. Please keep the user manual and warranty for future use.Have a lot of fun with your DT Swiss LRCS!For DT Swiss Service Centre Addresses see the backor check .Grease these parts.CAUTION!A)B)180°0°60°15.14.A)B)ø 4.0 - 4.2 mmTightening torque:max 2.5 Nm (22 InLbs)!CAUTION!Tightening torque :Max. 1.3 Nm!CAUTION!There shall be no claim under the guarantee for secondary damages in combination with front forks:- incorrect assembly or in combination with products that do not fit- incorrect use, bad treatment, misuse, negligence, carelessness during installation, maintenance or use,commercial use or use in cycling competitionsCAUTION!min. 8.5 mmCheck the lockout shaftfor easy operation by using a 6 mm or¼"- wrench!CAUTION!L I M I T E D E Q U I P M E N T W A R R A N T Y(U S A)DT Swiss LTD makes every effort to assure that its product meets high quality and durability standards and warrants to the original retail consumer/purchaser of our pro-duct that each product is free from defects in materials and workmanship as follows:2 YEAR LIMITED WARRANTY ON THIS LRCS PRODUCT. This warranty does not apply to defects due directly or indirectly tomisuse, abuse, negligence or accidents, repairs or alterations outside our facilities or to a lack of maintenance. DT SWISS LTD LIMITS ALL IMPLIEDWARRANTIES TO THE PERIOD OF TWO YEARS FROM THE DATE OF INITIAL PURCHASE AT RETAIL. EXCEPT AS STATED HEREIN, ANY IMPLIEDWARRANTIES OF MERCHANTABILITY AND FITNESS ARE EXCLUDED. SOME STATES MAY NOT ALLOW LIMITATIONS ON HOW LONG THE IMPLIEDWARRANTY LASTS, SO THE ABOVE LIMITATION MAY NOT APPLY TO YOU. DT SWISS LTD SHALL IN NO EVENT BE LIABLE FOR DEATH, INJURIESTO PERSONS OR PROPERTY OR FOR INCIDENTAL, CONTINGENT, SPECIAL OR CONSEQUENTIAL DAMAGES ARISING FROM THE USE OF OURPRODUCTS. SOME STATES MAY NOT ALLOW THE EXCLUSION OR LIMITATION OF INCIDENTAL OR CONSEQUENTIAL DAMAGES, SO THE ABOVELIMITATION OR EXCLUSION MAY NOT APPLY TO YOU.CAUTION!To take advantage of this warranty, the product or part must be returned for examination, postage prepaid, to the dealer where you bought the product or to aDT Swiss Service Centre.Proof of purchase date and an explanation of the complaint must accompany the product. If our inspection discloses a defect, DT Swiss willeither repair or replace the product or refund the purchase price, if we cannot readily and quickly provide a repair or replacement. DT Swiss will return repaired product orreplacement at DT Swiss expense, but if it is determined there is no defect, or that the defect resulted from causes not within the scope of this warranty, then the usermust bear the cost of shipping. This warranty gives you specific legal rights, and you may also have other rights which vary from state to state.Legal venue and place of performance is Biel (Switzerland). Swiss law shall apply. Subject to technical changes.Please keep the user manual and warranty for future use.Have a lot of fun with your DT Swiss LRCS!Indication:Weight difference of conversion: 59 g (exkl. cable)Tightening torque:Max. 2.5 Nm (22 InLbs)!CAUTION!。

Ferrite BeadsAxial EMI Suppression FerritesSMD Power InductorsQ +productsAxial EMI Suppre SMD Power Induc 207/14Würth Elektronik eiSos ®Q +products have given rise to plenty of discussions since their launch.The most frequently asked questions: What advantage do these products give us? To whom may I sell them? And for which applications are they suitable?Q +products Benefits1Optimized construction4High process capability levelInternal structures of the products in the Q +products portfolio are very different from conventional ones. For example, the wire connec-tion between coil wire and component is not made with a conven-tional solder joint, but by means of a welding process. Another exam-ple is ferrite sleeves; compared with the conventional industry article, the surface form is optimized and this considerably simplifies the routing of lines.Process capability is determined by means of familiar statistics and describes the stability of a manufacturing process. A statistical eval-uation by itself will not make a manufacturing process more stable, however. This also depends on the added values of other Q +prod-ucts.3Automation vs. partial automation / manual process Increasing the degree of automation in the manufacturing process changes the variance of process parameters positively by eliminat-ing the influence of the operator. This also ensures even more effec-tive process controlling.Higher level of automation2AEC-Q 200 qualificationAll Q +products are qualified in accordance with the AEC-Q 200. The Automotive Electronics Council Qualification (AECQ) does not reflect the qualification standard of the automotive industry in all cases, but describes product quality very precisely only by means of a variety ofreliability checks. 307/14Würth Elektronik eiSos ®Q +products Benefi ts6Production on strictly defined production linesAdditional quality controls can be carried out efficiently only if theyare used for previously evaluated production lines. Even two identical manufacturing processes can have different results. So pro-cess-based influences are difficult to generalize, which is why we specially select and monitor the production lines.5Additional quality controls are geared specifically to the familiar, crit-ical quality features of the individual Q +products. These features are directly monitored, documented and qualified according to their re-quirements in the appropriate manufacturing step.Additionalquality controls7The market requires tough products. So we have already extended the temperature range of Q +products ferrite sleeves to -55 °C / +150 °C. We also aim to extend such increases in temperature range to include all Q +products.Extended temperature range 407/14Würth Elektronik eiSos ®Q +products Qualifi cation StandardThe qualification standard refers to the AEC-Q 200 and is performed for all products which are shown in this catalogue. For your reference, you can find in the following table a short summary of the performed tests for inductors / transformers.High Temperature ExposureStorage for 1000 hours to at rated operating temperature (according to the datasheet)Temperature Cycling1000 cycles at operating temperature (according to the datasheet, e.g. -40 °C / +125 °C). with an maximum dwell time of one minute.Biased Humidity1000 hours at 85 °C and 85 % RH without electrical stressOperational Life1000 hours at operating temperature minus self-heating tempera-ture under electrical stress (rated current)External VisualInspection of the device looking / construction, workmanship and marking.Physical DimensionThe mechanical dimension have to be in between the specificationTerminal Strength (SMD)The parts will be stressed with a pull of force of 17.7 Newton for 60 seconds. The focus is on the soldering joint.Resistance to SolventsThree different kinds of solvent do not have any impact to the device construction, marking and looking.Mechanical ShockMechanical shocks shall not have any impact to the device construc-tion or function. These shocks will be simulated 18 times, by a am-plitude of 100 g’s for 6 milliseconds.VibrationVibrations of 10 g’s in a frequency range from 15 up to 2000 Hz for20 minutes shall not have any impact to the construction of the device. This process will be done in 12 cycles for each of the Axis.Resistance to Soldering HeatA Reflow Oven Test for five times shall not have any impact to the deviceESDAn Electrostatic discharge of 6 kV with direct contact, 12 kV, 16 kV and 25 kV with air contact shall not have any impact to the device.SolderabilityThree different Soldering procedures will be gone through. In each case an impact to the device and construction isn’t allowed.Electrical CharacterizationParametrically test which shows in a summary the min, max, man and standard deviation at room temperature as well as at min andmax operating temperature.Board FlexAt surface mounted devices, an impact due to bending, flexing and pulling forces shall be not be given.507/14Würth Elektronik eiSos®Q +productsStandards by ComparisonAlthough it might seem much better at the first sight, it doesn’t mean, that the industrial parts are less qualified than the Q + Products. The difference in here is the higher reliable requirements which we going to prove accordance to the AEC-Q 200. To show the difference, the following table contrasts some main parts out of the industrial qualification standard of Würth Elektronik eiSos with the main necessary qualification standards out of the AEC-Q 200.High Temperature Exposure 500 hours 1000 hours Temperature Cycling 500 cycles1000 cycles Biased Humidity –1000 hoursMoisture Resistance 500 hours –Operational Life 1000 hours1000 hoursExternal Visual Physical Dimension –Terminal strength Resistance to solvent – 3 different SolventsMechanical Shock –VibrationResistance to Soldering Heat 5 time Reflow5 time ReflowESD –SolderabilityElectrical Characterization –Board FlexLow Temperature Exposure–✓✓✓✓✓✓✓✓✓✓✓✓✓✓✓Legend to the table:✓ both of the tests are the same – not testedProduction SiteQuality & Design CenterWaldenburg (Germany)Taichung (Taiwan)Shenyang (China)Longgang (China)Seoul (Korea)607/14Würth Elektronik eiSos ®CharacteristicsReliable Ni-Sn electrodes High rated current up to 5 A Recommended soldering: ReflowOperating temperature: -55 °C to +125 °CSize 0402ApplicationsPerfect as data lined filter and for uncoupling of distribution voltageType definition of SMD ferrites WE-CBAThe special SMD chip bead ferrites can be put directly on the printed circuit board. They offer excellent anti-EMI properties and low DC-resistance. Placed very close next to the interference source even with smallest size 0402, maximal impedance at 1000 Ω can be reached.High Speed:“High Speed” SMD ferrites WE-CBA have lower impedance in the lower frequency ranges thus they have only a low attenuation for fast signals.Application e.g. USB 2.0, IEEE 1394, LVDSWide Band:“Wide Band” SMD ferrites WE-CBA already show high impedance in low frequency range. Therefore they are wide band through the whole spectrum.Application e.g. control signals, RS232, RS422, DC/DC converterHigh Current:“High Current” SMD ferrites WE-CBA are designed for high current (over 1 A). The rated current refers to 40 K self-heating. High current SMD ferrites are available in all three types (High Speed, Wide Band and High Frequency).Application e.g. power supply, DC/DC converterAdvice: Pay attention for the use of SMD ferrites for high rated current >1 A and ambient temperature over +85 °C that the rated current has to be reduced when temperature is above +85 °C (Derating).The characteristic line in the right figure shows, that e.g. at +100 °C ambient temperature the maximal rated current has to add up to only 60 % of the data sheet value, without an overload of the component.Derating +85 °CDerating +105 °CElectrical propertiesOrder Code Z @ 100 MHz(Ω)Z max (Ω)Testcondition Z max(MHz)I R (mA)R DC (Ω)Type of Application 782 422 1011001805005000.30Wide Band 782 422 2212203304004000.30Wide Band 782 422 3313306403003000.50Wide Band 782 422 5115107303002000.80Wide Band 782 422 6016008003002000.80Wide Band 782 422 10210001200170200 1.00Wide Band 782 423 100101770015000.03High Current 782 423 7007014060010000.09High CurrentSize 0402Typical impedance characteristics Wide BandHigh Current 807/14Würth Elektronik eiSos ®Size 0603Typical impedance characteristics High Speed 907/14Würth Elektronik eiSos ®Size 0603Typical impedance characteristics Wide BandHigh Current 1007/14Würth Elektronik eiSos ®Size 0805Typical impedance characteristics High SpeedSize 0805Typical impedance characteristics High CurrentSize 1206Typical impedance characteristics Wide BandHigh CurrentSize 1806Typical impedance characteristics High CurrentCharacteristicsFerrite core made of NiZn, a material which worksin a wide frequency rangeMany different types for the best possibleinterference suppressionOperating temperature: -55 °C up to +150 °CApplicationsIn general for: wires, coaxial cables, wire-wrappingcables, multiconductor wiresData and signal linesOn board power supply lineMultimedia cable interfacesVarious, other cable interfacesElectrical propertiesOrder Code OD(mm)ID(mm)H(mm)Cable Diameter(mm)Z @ 25 MHz1 turn (Ω)Z @ 100 MHz1 turn (Ω)782 013 033 15012.0 3.5515.0≤ 3.3150205782 013 044 0959.5 4.759.5≤ 4.46084782 013 046 18511.5 5.018.5≤ 4.6135186782 013 046 25011.5 5.025.0≤ 4.6185255782 013 057 45012.0 6.145.0≤ 5.7255370782 013 059 28514.0 6.328.5≤ 5.9195270782 013 068 25014.07.225.0≤ 6.8150210782 013 069 15512.07.315.5≤ 6.970100782 013 069 28515.57.328.5≤ 6.9190270782 013 076 28516.08.028.5≤ 7.6170240782 013 076 50816.08.050.8≤ 7.6325460782 013 079 28514.08.228.5≤ 7.9140200782 013 086 28016.09.028.0≤ 8.6140205782 013 091 28517.59.528.5≤ 9.1150220782 013 100 28015.510.528.0≤ 10.0100150782 013 110 50819.011.550.8≤ 11.0235345782 013 125 28019.013.028.0≤ 12.595150782 013 125 28526.013.028.5≤ 12.5170240782 013 150 28526.015.528.5≤ 15.0130190Temperature rangeup to +150 °CTypical impedance characteristicsTypical impedance characteristicsSize 7332CharacteristicsWire connection: welding technologyOperating Temperature -40°C up to +125 °C Highes possible current loading for SMD Inductors Magnetically shielded version which results in a low leakage field High storage capacity Low self-losses Core Material: NiZnApplicationsMultimedia applicationsSwitching regulators with low operating voltages (Computer, Notebook, smart phones) Integrated DC/DC-converterPerfect suitable for switching regulators withextremely high efficiency (> 86 %)Electrical propertiesOrder Code L (μH)Tolerance (%)R DC (mΩ) max.I R (A)I Sat (A)784 778 010 1.020 %36 5.37 6.40784 778 022 2.220 %50 4.00 4.80784 778 033 3.320 %65 3.42 4.20784 778 047 4.720 %79 2.90 3.90784 778 068 6.820 %95 2.50 2.75784 778 0828.220 %103 2.2 2.4784 778 1001020 %126 1.83 2.20784 778 2202220 %190 1.40 1.40784 778 4704720 %350 1.10 1.00784 778 10110020 %7200.750.67784 778 22122020 %16200.540.42784 778 47147020 %33000.320.31784 778 102100020 %72000.200.18Inductance vs. Current0,11101001000111,0784778010784778100784778101784778102Rated current [A]I n d u c t a n c e [µH ]Size 7345Size 1260Size 1280Size 121007/14Würth Elektronik eiSos®21 2207/14Würth Elektronik eiSos ®Size 4532CharacteristicsOpen sizeCurrent capability up to 14 AOperating temperature: -40 °C to +125 °C Recommended solder profile: ReflowApplicationsSwitching regulators with low operating voltage (navigation system, air conditioning, entertainment, park assistance control) Integrated DC/DC-converterPerfectly suitable for switching regulators with extremely high efficiencyElectrical properties: Size 4532Order Code L (µH)Tolerance (%)R DC typ. (Ω)R DC max. (Ω)I R (A)I sat (A)784 773 0 1.0±200.0140.049 4.00 5.72784 773 018 1.80.0280.064 2.70 3.60784 773 022 2.20.0340.071 2.50 3.38784 773 033 3.30.0410.086 2.00 2.88784 773 039 3.90.0540.094 1.88 2.57784 773 047 4.70.0590.110 1.82 2.46784 773 056 5.60.0690.126 1.58 2.43784 773 068 6.80.0760.131 1.54 2.10784 773 0828.20.1160.146 1.50 1.80784 773 10100.1180.182 1.45 1.74784 773 112120.1560.210 1.28 1.62784 773 115150.2040.235 1.20 1.46784 773 118180.2250.338 1.10 1.29784 773 122220.2610.370 1.00 1.22784 773 12727±100.3280.5220.94 1.00784 773 133330.3700.5400.860.90784 773 139390.4180.5870.770.87784 773 147470.5230.8440.680.77784 773 156560.7140.9370.640.75784 773 168680.7541.1170.560.68NoteThe ambient temperature when operating the WE-PD series of storage chokes at full current rating load should generally range from -40 °C to +85 °C. The self-heating of the component must be taken into account at higher ambient temperatures in order that the permissible solder joint temperature is not exceeded or the wire insulation damaged. The wire used can withstand a temperature of up to +150 °C. The ferrite core itself may be used over a far greater temperature range (approx. -50 °C to +250 °C [Curie tempera-ture]). However, in this case, the tolerance limits of the inductor may be exceeded due to the temperature dependence of permeability.Current derating at ambient temperature of > 85 ºCInductance vs. DC bias current2307/14Würth Elektronik eiSos ®Size 4532 / Size 5848Land pattern (in mm): Size 4532Solder Resist4,5ref.1,5r e f .5,0r e f .1,75r e f .Dimensions (in mm): Size 5848Land pattern (in mm): Size 5848Electrical properties: Size 5848Order Code L (µH)Tolerance (%)R DC typ. (Ω)R DC max. (Ω)I R (A)I sat (A)784 774 0030.33±200.0060.00810.815.30784 774 0060.6-40/+200.0090.0188.2013.50784 774 022 2.2±200.0260.041 4.608.20784 774 027 2.70.0320.045 4.008.00784 774 033 3.30.0420.060 3.707.50784 774 047 4.70.0560.071 3.00 5.50784 774 068 6.80.0710.082 2.40 4.50784 774 10100.0780.100 2.20 2.50784 774 112 120.0820.110 2.00 1.94784 774 115150.0890.140 1.53 1.90784 774 118180.1040.150 1.45 1.69784 774 122220.1090.180 1.28 1.53784 774 127270.1330.200 1.19 1.40784 774 13333±150.1500.230 1.09 1.17784 774 139390.2150.3200.94 1.10784 774 147470.2600.3700.86 1.00784 774 15656±100.2980.4200.770.90784 774 168680.3130.4600.640.86784 774 182820.4750.6000.600.72784 774 201000.5100.6500.570.68784 774 2121200.6600.9300.490.63784 774 2151500.720 1.1000.460.54784 774 2181800.850 1.3800.420.50784 774 2222200.9451.5700.410.472,0 ±0,45,8 ± 0,35,2±0,34,5±0,35Solder Resist1,7r e f .6,0r e f .5,5ref.2,15r e f .Inductance vs. rated current: Size 5848784 774 222784 774 156784 774 118784 774 0220,11100,1110Rated current [A]I n d u c t a n c e [µH ]100784 775 222784 775 247784 775 127784 775 0121000,11100,1110Rated current [A]I n d u c t a n c e [µH ]784 773 168784 773 127784 773 0784 773 0821000,11100,1110Rated current [A]I n d u c t a n c e [µH ]100784 775 222784 775 247784 775 127784 775 0120,11100,1110Rated current [A]I n d u c t a n c e [µH ]100784 776 222784 776 247784 776 127784 776 0120,1110I n d u c t a n c e [µH ]100Inductance vs. rated current: Size 4532Size 7850Size 105425Size 2506 / Size 2508Characteristics⏹Magnetic iron alloy allows high rated currents⏹Compact design⏹Magnetically shielded⏹H igh current capability and handles high transientcurrent spikes⏹Low acoustic noise and low leakage flux noise⏹Operating temperature: –40 °C to 125 °CApplications⏹DC/DC-converter for high current power supplies⏹D C/DC-converter for Field Programmable Gate Array(FPGA)⏹POL-converters⏹Portable power like PDA, digital camera⏹Mainboards/graphic cards⏹Battery powered devices⏹W ireless communication devices⏹P ower supplies for smartphones, tablet PCs andother mobile devicesElectrical properties: Size 2506Order Code L(µH)Tolerance(%)IR(A)Isat(A)RDC typ.(mΩ)RDC max.(mΩ)784 383 210 0470.47±302.23.776.095.0784 383 210 10 1.0 1.25 2.5163.0196.0I referring to 40 K heating above ambient temperatureI referring to inductance loss of 20% typicalElectrical properties: Size 2508Order Code L(µH)Tolerance(%)IR(A)Isat(A)RDC typ.(mΩ)RDC max.(mΩ)784 383 220 0470.47±302.25 4.470.087.0784 383 220 10 1.0 1.75 3.35107.0133.0784 383 220 22 2.2 1.34 2.2252.0302.0I referring to 40 K heating above ambient temperatureI referring to inductance loss of 20% typicalNEW!4-times higher saturation currentBest efficiency Minimized package2607/14Würth Elektronik eiSos® 2707/14Würth Elektronik eiSos®Size 2510 / Size 3010 2807/14Würth Elektronik eiSos®Size 3012 2907/14Würth Elektronik eiSos®Size 3015 3007/14Würth Elektronik eiSos®Design Kit WE-CBASMD EMI Suppression Ferrite BeadOrder Code 782 792, Version 1.1Electrical propertiesOrder Code SizeZ @ 100 MHz(Ω)I R (mA)R DC (Ω)Type of Application 782 422 10104021005000.300Wide Band 782 422 2212204000.300Wide Band 782 422 3313303000.500Wide Band 782 422 5115102000.800Wide Band 782 422 6016002000.800Wide Band 782 422 1021000200 1.000Wide Band 782 423 1001015000.030High Current 782 423 7007010000.090High Current 782 631 10106031005000.200High Speed 782 631 3313304000.250High Speed 782 631 182********.750High Speed 782 632 620625000.150Wide Band 782 632 1211205000.200Wide Band 782 632 1811805000.200Wide Band 782 632 5115103000.350Wide Band 782 632 10210002000.500Wide Band 782 633 6206225000.040High Current 782 633 60160010000.200High Current 782 851 102080510003000.350High Speed 782 851 20222002000.450High Speed 782 853 2002050000.008High Current 782 853 2702740000.015High Current 782 853 6806830000.025High Current 782 853 9109120000.060High Current 782 853 12112025000.035High Current 782 583 22122020000.050High Current 782 853 56156015000.100High Current 782 853 11211008000.300High Current 752 853 152********.350High Current 782 762 30112063005000.100Wide Band 782 763 8208230000.025High Current 782 763 62162015000.100High Current 782 763 102100010000.300High Current 782 963 56018065650000.008High Current 782 963 8208235000.020High CurrentCharacteristicsReliable Ni-Sn electrodes High rated current up to 5 A Recommended soldering: ReflowOperating temperature: -55 °C to +125 °CApplicationsPerfect as data lined filter and for uncoupling of distribution voltage 3107/14Würth Elektronik eiSos ®Design Kit WE-AEFAAxial EMI Suppression FerriteOrder Code 782 013, Version 1.1CharacteristicsFerrite core made of NiZn, a material which works in a wide frequency rangeMany different types for the best possible interference suppressionOperating temperature: -55 °C up to +150 °CApplicationsIn general for: wires, coaxial cables, wire-wrapping cables, multiconductor wires Data and signal linesOn board power supply line Multimedia cable interfaces Various, other cable interfacesElectrical propertiesOrder Code OD (mm)ID (mm)H (mm)Cable Diameter (mm)Z @ 25 MHz 1 turn (Ω)Z @ 100 MHz 1 turn (Ω)782 013 033 15012.0 3.5515.0≤ 3.3150205782 013 044 0959.5 4.759.5≤ 4.46084782 013 046 18511.5 5.018.5≤ 4.6135186782 013 046 25011.5 5.025.0≤ 4.6185255782 013 057 45012.0 6.145.0≤ 5.7255370782 013 059 28514.0 6.328.5≤ 5.9195270782 013 068 25014.07.225.0≤ 6.8150210782 013 069 15512.07.315.5≤ 6.970100782 013 069 28515.57.328.5≤ 6.9190270782 013 076 28516.08.028.5≤ 7.6170240782 013 076 50816.08.050.8≤ 7.6325460782 013 079 28514.08.228.5≤ 7.9140200782 013 086 28016.09.028.0≤ 8.6140205782 013 091 28517.59.528.5≤ 9.1150220782 013 100 28015.510.528.0≤ 10.010******* 013 110 50819.011.550.8≤ 11.023******* 013 125 28019.013.028.0≤ 12.595150782 013 125 28526.013.028.5≤ 12.5170240782 013 150 28526.015.528.5≤ 15.0130190Design Kit WE-PDA SMD Power InductorOrder Code 784 770 & 784 778, Version 1.1 Electrical properties: Order Code 784 770Order Code Size L(μH)RDC(Ω)IR(A)Isat(A)784 771 010126018.509.0016.50784 771 022 2.212.507.2010.50 784 771 033 3.314.50 6.509.00 784 771 047 4.717.50 6.208.00 784 771 068 6.821.50 5.50 6.00 784 771 0828.224.00 5.05 5.50 784 771 1001026.50 5.00 5.25 784 771 2202240.00 3.20 3.50 784 771 4704777.00 2.30 2.50 784 771 101100174 1.50 1.70 784 771 2212203480.99 1.10 784 771 102100017050.480.53784 770 10128019.008.3022.00784 770 22 2.214.507.0015.00 784 770 33 3.317.00 6.6012.00 784 770 47 4.720.00 6.0011.00 784 770 68 6.825.00 5.208.50 784 770 1001031.00 5.00 6.80 784 770 2202244.50 4.00 4.70 784 770 4704771.00 3.10 3.40 784 770 101100144.00 2.10 2.30 784 770 471470570.000.80 1.00 784 770 10210001200.000.720.80784 770 901 0121018.509.2023.00784 770 902 2 2.214.507.5016.00 784 770 903 3 3.317.007.0013.50 784 770 904 7 4.719.00 6.0011.00 784 770 906 8 6.824.00 5.509.00 784 770 910 01030.00 5.007.50 784 770 922 02244.00 4.30 5.00 784 770 947 04767.00 3.20 3.50 784 770 910 1100120.00 2.20 2.40 784 770 922 1220245.00 1.45 1.60 784 770 947 1470490.000.90 1.10 784 770 910 2100010600.630.70Electrical properties: Order Code 784 778Order Code Size L(μH)RDC(Ω)IR(A)Isat(A) 784 777 0107332139 3.708.00 784 777 022 2.261 2.70 5.25 784 777 033 3.370 2.50 4.70 784 777 047 4.784 2.35 3.70 784 777 068 6.898 2.20 3.20 784 777 0828.2117 2.00 2.80 784 777 10010126 1.90 2.60 784 777 22022215 1.40 1.80 784 777 47047300 1.15 1.25 784 777 1011004700.720.80 784 777 22122027200.500.55 784 777 47147057500.350.38 784 777 102100057600.250.28 784 778 0107345136 3.507.00 784 778 022 2.250 3.10 5.00 784 778 033 3.365 2.65 3.70 784 778 047 4.779 2.40 3.10 784 778 068 6.8107 2.30 2.50 784 778 0828.2103 2.20 2.40 784 778 10010126 1.85 2.20 784 778 22022187 1.55 1.60 784 778 47047348 1.10 1.05 784 778 1011007200.720.75 784 778 22122016200.480.50 784 778 47147033000.300.35 784 778 102100072000.230.25CharacteristicsWire connection: welding technology Operating Temperature -40°C up to +125 °CHighes possible current loading for SMD InductorsMagnetically shielded version which results in alow leakage fieldHigh storage capacityLow self-lossesCore Material: NiZnApplicationsMultimedia applicationsSwitching regulators with low operating voltages(Computer, Notebook, smart phones)Integrated DC/DC-converterPerfect suitable for switching regulators withextremely high efficiency (> 86 %)l3207/14Würth Elektronik eiSos® 3307/14Würth Elektronik eiSos ®Order Code 784 773 & 784 775, Version 1.1CharacteristicsOpen sizeCurrent capability up to 14 AOperating temperature: -40 °C to +125 °C Recommended solder profile: ReflowApplicationsSwitching regulators with low operating voltage(navigation system, air conditioning, entertainment, park assistance control) Integrated DC/DC-converterPerfectly suitable for switching regulators with extremely high efficiencyElectrical properties: Order Code 784 775Order Code SizeL (μH)R DC (Ω)I R (A)I sat (A)784 775 107850100.040 2.30 2.95784 775 112120.042 2.18 2.23784 775 115150.044 1.93 2.20784 775 118180.053 1.89 2.14784 775 122220.065 1.76 1.81784 775 127270.074 1.48 1.62784 775 133330.130 1.35 1.47784 775 139390.116 1.25 1.33784 775 147470.134 1.17 1.24784 775 168680.2180.99 1.05784 775 182820.2480.900.95784 775 201000.2810.770.86784 775 2151500.4670.600.71784 775 2181800.5740.550.57784 775 2222200.6140.510.56784 775 2272700.6990.470.51784 775 239396 1.1510.380.43784 775 247470 1.3700.360.38784 776 101054100.028 2.98 3.24784 776 118180.043 2.36 2.43784 776 122220.051 2.04 2.07784 776 127270.063 1.95 1.98784 776 133330.083 1.78 1.89784 776 139390.088 1.62 1.80784 776 147470.095 1.45 1.62784 776 156560.112 1.36 1.53784 776 168680.138 1.19 1.49784 776 182820.150 1.11 1.17784 776 201000.200 1.02 1.10784 776 2121200.2430.940.99784 776 2151500.3000.810.90784 776 2181800.3200.760.78784 776 2222200.4510.670.77784 776 2333300.7500.520.59784 776 2474700.9690.440.50Electrical properties: Order Code 784 773Order Code SizeL (μH)R DC (Ω)I R (A)I sat (A)784 773 045321.000.014 4.0 5.72784 773 018 1.80.0282.703.60784 773 022 2.20.034 2.50 3.38784 773 033 3.30.041 2.00 2.88784 773 039 3.90.054 1.88 2.57784 773 0474.70.059 1.82 2.46784 773 068 6.80.076 1.54 2.10784 773 10100.118 1.45 1.74784 773 112120.156 1.28 1.62784 773 115150.204 1.20 1.46784 773 118180.225 1.10 1.29784 773 122220.261 1.00 1.22784 773 127270.3280.94 1.00784 773 133330.3700.860.90784 773 147470.5230.680.77784 773 168680.7540.560.68784 774 02258482.20.026 4.608.20784 774 027 2.70.032 4.008.00784 774 0333.30.042 3.707.50784 774 0474.70.056 3.005.50784 774 0686.80.071 2.40 5.00784 774 10100.078 2.20 2.5784 774 112120.082 2.00 1.94784 774 115150.089 1.53 1.90784 774 118180.104 1.45 1.69784 774 122220.109 1.28 1.53784 774 127270.133 1.19 1.40784 774 133330.150 1.09 1.17784 774 147470.2600.86 1.00784 774 156560.2980.770.90784 774 168680.3130.640.86784 774 182820.4750.600.72784 774 201000.5100.570.68784 774 2151500.7200.460.54784 774 2222200.9450.410.47Op ReOrder Code 784 3833 & 784 3832, Version 1.0Characteristics⏹Magnetic iron alloy allows high rated currents⏹Compact design⏹Magnetically shielded⏹H igh current capability and handles high transient current spikes⏹Low acoustic noise and low leakage flux noise⏹Operating temperature: –40 °C to 125 °C Applications⏹DC/DC-converter for high current power supplies ⏹D C/DC-converter for Field Programmable Gate Array (FPGA)⏹POL-converters⏹Portable power like PDA, digital camera⏹Mainboards/graphic cards⏹Battery powered devices⏹W ireless communication devices⏹P ower supplies for smartphones, tablet PCs and other mobile devicesElectrical properties: Order Code 784 3833Order Code Size L(μH)IR(A)Isat(A)RDC(Ω)784 383 330 2230102.2 1.4 3.9150784 383 330 33 3.3 1.1 2.95232 784 383 330 47 4.70.9 2.4356784 383 340 03330120.33 4.811.119.0784 383 340 0470.47 4.09.422.0 784 383 340 0560.56 3.68.529.0 784 383 340 0680.68 3.57.736.0 784 383 340 10 1.0 2.75 6.642.1 784 383 340 12 1.2 2.65 6.055.0 784 383 340 15 1.5 2.0 5.780.0 784 383 340 22 2.2 1.80 5.0100 784 383 340 33 3.3 1.4 4.0156.3 784 383 340 47 4.7 1.1 3.80267.7 784 383 340 56 5.6 1.0 3.0338.3 784 383 340 68 6.80.88 2.7368.2784 383 350 1030151.0 2.7 4.539.0784 383 350 22 2.2 1.8 3.594.0 784 383 350 33 3.3 1.7 3.2114 784 383 350 47 4.7 1.5 2.8141 784 383 350 68 6.8 1.1 2.4250 784 383 351 0010.00.85 2.0446 784 383 351 5015.00.65 1.71720 784 383 352 2022.00.60 1.60940 784 383 353 3033.00.50 1.301210 784 383 354 7047.00.39 1.182090Electrical properties: Order Code 784 3832Order Code Size L(μH)IR(A)Isat(A)RDC(Ω)784 383 210 04725060.47 2.2 3.776.0 784 383 210 10 1.0 1.25 2.5163.0 784 383 220 04725080.47 2.25 4.470.0 784 383 220 10 1.0 1.75 3.35107.0 784 383 220 22 2.2 1.34 2.2252.0 784 383 230 03325100.33 3.4 6.229.0 784 383 230 047 0.47 3.2 5.537.0 784 383 230 068 0.68 3.1 4.746.0 784 383 230 082 0.82 2.6 4.2553.0 784 383 230 10 1.0 2.5 4.063.0 784 383 230 12 1.2 1.9 3.882.0 784 383 230 15 1.5 1.8 3.592.0 784 383 230 22 2.2 1.3 2.5147 784 383 230 33 3.3 1.25 2.1220 784 383 230 47 4.70.94 1.75338 784 383 230 68 6.80.85 1.55563 784 383 230 828.20.7 1.45646 784 383 231 0010.00.6 1.35733Order Code 784 3833 & 784 383C3407/14Würth Elektronik eiSos®。

June 2008Rev 1 1/29UM0529User manualSTUSB02E and STUSB03 low-speedevaluation boards: STEVAL-PCC004V1 and STEVAL-PCC003V1IntroductionThis user manual explains the details of both the STUSB02E and STUSB03 USB low-speed evaluation boards.For evaluation purposes, the USB microcontroller used is the ST72F63B.The STUSB02E or STUSB03 connected with a USB controller is ideal for use in mobile phones, digital cameras, printers, PDAs, etc.The STUSB02E or STUSB03 USB low-speed evaluation board is designed fordemonstration and evaluation purposes.■Reference:–STEVAL-PCC003V1: low-speed USB evaluation board based on the STUSB03 transceiver and ST72F63B–STEVAL-PCC004V1: low-speed USB evaluation board based on the STUSB02E transceiver and ST72F63BFigure 1.USB low-speed evaluation board - Contents UM0529Contents1Getting started . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61.1Package contents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61.1.1Hardware . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61.1.2Software . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61.1.3Documentation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61.2Hardware installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61.2.1Powering on the board . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61.3Software installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61.3.1Drivers for evaluation board . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61.3.2System requirements for USB HID demonstration GUI . . . . . . . . . . . . . . 6 2Evaluation board hardware . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83Evaluation board components . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93.1Microcontroller U1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93.1.1Oscillator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93.2STUSB02E/STUSB03E transceiver U5 . . . . . . . . . . . . . . . . . . . . . . . . . . . 93.374LCX139MTR low voltage dual 2-to-4 decoder/demultiplexer U2,U3 . . . 93.4LD2985BM33R voltage regulator U4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 4Power requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 115Pin assignments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 125.1Jumpers details . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 125.2Switch assignments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 145.3Connector assignments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 155.4USB pin assignments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 155.5Decoder U2/U3 pin description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 155.5.1Decoder/demultiplexer U2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 165.5.2Decoder/demultiplexer U3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 165.6STUSB02E and STUSB03 transceiver pin configuration . . . . . . . . . . . . . 176Firmware . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 206.1Communication with the application board . . . . . . . . . . . . . . . . . . . . . . . . 212/29UM0529Contents6.1.1PC software control of the evaluation board . . . . . . . . . . . . . . . . . . . . . 216.1.2Display of evaluation board state . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 216.2USB suspend . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 7Schematics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 8Bill of material . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 Appendix A Port configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 Appendix B Abbreviations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 9Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 283/29List of figures UM0529 List of figuresFigure B low-speed evaluation board - STEVAL-PCC003V1. . . . . . . . . . . . . . . . . . . . . . . . . . . 1 Figure 2.STUSB02E/STUSB03E- low-speed evaluation board enumeration in GUI . . . . . . . . . . . . . 7 Figure 3.STUSB02E/ STUSB03 evaluation board block diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 Figure 4.STUSB02E/STUSB03E evaluation board enumeration. . . . . . . . . . . . . . . . . . . . . . . . . . . 20 Figure 5.STUSB02E/ STUSB03 evaluation board demonstration . . . . . . . . . . . . . . . . . . . . . . . . . . 21 Figure 6.STUSB02E/STUSB03E evaluation board schematic. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 4/29UM0529List of tables List of tablesTable 1.Microcontroller details. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 Table 2.General jumper assignments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 Table 3.Voltage regulator U4 related jumper assignment. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 Table B transceiver U5 related jumper assignment. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 Table 5.CONFIG section related jumper assignment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 Table 6.Evaluation board switch assignments. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 Table 7.Evaluation board connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 Table B mini-B pin assignments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 Table 9.Decoder pin U2/ U3 description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 Table 10.Truth table for first input of U2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 Table 11.Truth table for second input of U2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 Table 12.Truth table for first input of U3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 Table 13.Truth table for second input of U3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 Table 14.Pin description for STUSB02E transceiver. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 Table 15.Pin description for STUSB03 transceiver. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18 Table 16.BOM list . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 Table 17.Port configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 Table 18.Abbreviations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 Table 19.Document revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 285/29Getting started UM05296/291 Getting started1.1 Package contentsThe STUSB02E and STUSB03 evaluation board kit package comprises the following:1.1.1 Hardware●STUSB02E / STUSB03 - low-speed evaluation board ●USB to mini-B cable1.1.2 Software●USB HID demonstration GUI1.1.3 Documentation●User manual ●Detailed presentation of applications and STUSB02EQR / STUSB03EQR features1.2 Hardware installation1.2.1 Powering on the boardConnect the evaluation board to the PC using the J7 connector via the USB to mini-B cable.The power status LED D2 lights up indicating successful power-up of the board.1.3 Software installationTo work with the STUSB02E or STUSB03 low-speed evaluation board, install the USB HIDdemonstration GUI on the PC.1.3.1 Drivers for evaluation boardThe firmware programmed in the evaluation board is based on HID class of USB. WindowsOS have built-in drivers for HID functionality1.3.2 System requirements for USB HID demonstration GUIFor low-speed evaluation board communication with GUI, a recent version of Windows, suchas Windows 2000 or Windows XP must be installed on the PC.Windows is a registered trademark of Microsoft Corporation in the United States and othercountries.Note:The version of the Windows OS installed on your PC can be determined by clicking on thesystem icon in the control panel.After successful installation of USB HID demonstration GUI and board connection to PC,open the USB HID demonstration GUI. The low-speed evaluation board is enumerated inthe GUI as shown in Figure 2.UM0529Getting started Figure 2.STUSB02E/STUSB03E- low-speed evaluation board enumeration in GUINow the evaluation board installation procedure is complete. For demonstration of theboard features refer to Section6.1: Communication with the application board on page21.7/29Evaluation board hardware UM05298/292 Evaluation board hardwareAll the hardware components except the transceiver IC are the same for the STUSB02E andSTUSB03 evaluation boards. The evaluation boards are comprised of one mini-B USBconnector, one USB controller, one USB transceiver, two 2-to-4 demultiplexers and allrequired discrete components (pull-up resistors, series resistors and power supplycapacitors). The device can be configured through a set of jumpers and the main signalscan be accessed through test points.The evaluation board is powered from a USB mini-B or optionally from an external supply.The transceiver STUSB02EQR/ STUSB03EQR is connected at the USB communicationlines of the microcontroller. The USBVCC 3.3 V is obtained from the controller for providingthe VIF to the transceiver and also the supply to 74LCX139. Since the ST72F63B is a USBlow-speed microcontroller, therefore the pull-up resistor is connected to the D- pin of thetransceiver. Hence, STUSB02E / STUSB03 acts as a low-speed transceiver. Also the SPDpin of the transceiver is connected to GND for low-speed selection.The 74LCX139MTR is used to convert 5 V signals from the microcontroller to 3.3 V signalsto STUSB02E/STUSB03E. This device is used because some signals need polarityconversion whereas other signals just need the level conversion. This is explained inSection 3.3: 74LCX139MTR low voltage dual 2-to-4 decoder/demultiplexer U2,U3.9/293 Evaluation board components3.1 Microcontroller U1The microcontroller used for the STUSB02E/STUSB03E transceiver evaluation board isST72F63B. It is programmed with firmware to support the USB HID functionality fordemonstration purposes.3.1.1 OscillatorA 12 MHz crystal is used for providing the necessary clock to the microcontroller. C3 and C4capacitors are used along with a quartz crystal.3.2 STUSB02E/STUSB03E transceiver U5The STUSB02E and STUSB03 are single chip USB transceivers that support both USB full-speed and USB low -speed operations. Both have an integrated 5 V to 3.3 V regulator whichallows direct powering from the VBUS. The transceivers also support sharing mode whenVBUS is not present which allows the D+/D- lines to be shared with other serial protocols.They are also designed to operate down to 1.6 V so that they are compatible with lowersystem voltages of most portable systems, which include PDAs, MP3 players and cellphones.3.3 74LCX139MTR low voltage dual 2-to-4 decoder/demultiplexerU2,U3The 74LCX139MTR is a low -voltage CMOS dual 2-to-4 line decoder/ demultiplexer. It isideal for low-power and high-speed 3.3 V applications. It can be interfaced to 5 V signalenvironment for inputs. The active low enable input can be used for gating or as a data inputfor demultiplexing applications. While the enable input is held high, all four outputs are highindependently of the other inputs.It has the same speed performance at 3.3 V as well as the 5 V , combined with lower powerconsumption. All inputs and outputs are equipped with protection circuits against staticdischarge, giving them 2 KV ESD immunity and transient excess voltage.As explained above this device is used for interfacing between the microcontroller andSTUSB02/STUSB03E for 5 V to 3.3 V signals. The 74LVX139MTR device can also be usedas it also has 5 V tolerant inputs.Note:The 74LCX139MTR is used for interfacing the ST72F63B microcontroller with an operatingvoltage ranging from 4 V to 5.5 V in the evaluation board to transceiver. In the final Table 1.Microcontroller detailsFeatureDescription Sales typeST72F63BK4B1PackagePSDIP32Operating voltage 4.0 V to 5.5 Vapplication involving the USB02E/USB03E, such a voltage converter is not needed as theUSB microcontroller will have the V IF ranging from 1.6 V to 3.3 V as required for thetransceiver. Also, we need signal inversion for the USBOE and SUS signals of transceiver.This task is also performed by the 74LCX139MTR in this board. Hence, 74LCX139MTRusage is basically microcontroller specific.voltage regulator U43.4 LD2985BM33RThe LD2985BM33R is a 150 mA fixed output voltage regulator. The ultra-low drop voltageand the low quiescent current make them particularly suitable for low-noise, low-powerapplications and in battery-powered systems. In sleep mode, quiescent current is less than1 µA when the INHIBIT pin is pulled low. Shutdown logic control function is available on pin3 (TTL compatible).Note:LD2985BM33R usage is optional in the board. By configuring jumpers J9,J13,J11, the external voltage regulator can be switched off. In this case, the internal voltage regulator ofthe microcontroller is used to power 74LCX139MTR and STUSB02E/ STUSB03 V IF.When external voltage regulator LD2985BM33R is used for powering 74LCX139MTR andSTUSB02E/ STUSB03 V IF , overall current consumption of the board increases.10/29分销商库存信息:STMSTEVAL-PCC003V1STEVAL-PCC004V1。

Eaton 199129Eaton Moeller® series Rapid Link - DOL starter, 6.6 A, Sensorinput 4, Actuator output 2, PROFINET, HAN Q4/2, with manualoverride switchGeneral specificationsEaton Moeller® series Rapid Link DOLstarter1991294015081971879120 mm270 mm220 mm 1.83 kgCCCIEC/EN 60947-4-2 UL approval RoHSCEUL 60947-4-2Assigned motor rating: for normal internally and externally ventilated 4 pole, three-phase asynchronous motors with 1500 rpm at 50 Hz or 1800 min at 60 HzRAMO5-D420PNT-412RS1Product Name Catalog NumberEANProduct Length/Depth Product Height Product Width Product Weight Certifications Catalog NotesModel CodeParameterization: FieldbusParameterization: KeypadParameterization: drivesConnect mobile (App) Parameterization: drivesConnectKey switch position OFF/RESETKey switch position HAND2 Actuator outputsThermistor monitoring PTCTwo sensor inputs through M12 sockets (max. 150 mA) for quick stop and interlocked manual operationElectronic motor protectionKey switch position AUTOManual override switchThermo-clickShort-circuit releaseExternal reset possibleTemperature compensated overload protection CLASS 10 AIP65NEMA 12Class A10,000,000 Operations (at AC-3)10,000,000 Operations (at AC-3)Direct starter0.3 A6.6 AIIIMotor starterPROFINET IO4000 VAC voltageCenter-point earthed star network (TN-S network) Phase-earthed AC supply systems are not permitted.DOL starterDCFeatures Fitted with:Functions ClassDegree of protectionElectromagnetic compatibility Lifespan, electricalLifespan, mechanicalModelOverload release current setting - min Overload release current setting - max Overvoltage categoryProduct categoryProtocolRated impulse withstand voltage (Uimp) System configuration typeTypeVoltage typeVertical15 g, Mechanical, According to IEC/EN 60068-2-27, 11 ms, Half-sinusoidal shock 11 ms, 1000 shocks per shaftResistance: 10 - 150 Hz, Oscillation frequencyResistance: 57 Hz, Amplitude transition frequency on accelerationResistance: 6 Hz, Amplitude 0.15 mmResistance: According to IEC/EN 60068-2-6Max. 1000 mMax. 2000 mAbove 1000 m with 1 % performance reduction per 100 m -10 °C55 °C-40 °C70 °CIn accordance with IEC/EN 50178< 95 %, no condensationAdjustable, motor, main circuit0.3 - 6.6 A, motor, main circuit6.6 A (at 150 % Overload)Maximum of one time every 60 seconds 380 - 480 V (-15 %/+10 %, at 50/60 Hz) 20 - 35 ms20 - 35 ms50/60 HzAC-53a47 Hz 3 HP10 kA0 AType 1 coordination via the power bus' feeder unit, Main circuit0 V0 V0 VMounting position Shock resistance Vibration AltitudeAmbient operating temperature - min Ambient operating temperature - max Ambient storage temperature - min Ambient storage temperature - max Climatic proofingCurrent limitationInput currentMains switch-on frequency Mains voltage tolerance Off-delayOn-delayOutput frequency Overload cycleRated frequency - min Rated frequency - max Assigned motor power at 460/480 V, 60 Hz, 3-phaseRated conditional short-circuit current (Iq)Rated conditional short-circuit current (Iq), type 2, 380 V, 400 V, 415 VShort-circuit protection (external output circuits)Rated control supply voltage (Us) at AC, 50 Hz - minRated control supply voltage (Us) at AC, 50 Hz - maxRated control supply voltage (Us) at AC, 60 Hz - min63 Hz6.6 A6.6 A0.09 kW3 kW0 kW3 kW480 V AC, 3-phase400 V AC, 3-phase50/60 Hz, fLN, Main circuitAC voltageCenter-point earthed star network (TN-S network) Phase-earthed AC supply systems are not permitted.0 V0 V0 V24 V DC (-15 %/+20 %, external via AS-Interface® plug) Connections pluggable in power section210 m, Radio interference level, maximum motor cable lengthMeets the product standard's requirements. Meets the product standard's requirements. Meets the product standard's requirements. Meets the product standard's requirements.Rapid Link 5 - brochureDA-SW-drivesConnectDA-SW-Driver DX-CBL-PC-3M0DA-SW-drivesConnect - installation helpDA-SW-USB Driver DX-COM-STICK3-KITDA-SW-drivesConnect - InstallationshilfeDA-SW-USB Driver PC Cable DX-CBL-PC-1M5Material handling applications - airports, warehouses and intra-logistics eaton-bus-adapter-rapidlink-reversing-starter-dimensions-003.epsRated operational current (Ie) at 150% overloadRated operational current (Ie) at AC-3, 380 V, 400 V, 415 V Rated operational power at 380/400 V, 50 Hz - minRated operational power at 380/400 V, 50 Hz - maxRated operational power at AC-3, 220/230 V, 50 HzRated operational power at AC-3, 380/400 V, 50 HzRated operational voltageSupply frequencySystem configuration type Rated control supply voltage (Us) at AC, 60 Hz - max Rated control supply voltage (Us) at DC - minRated control supply voltage (Us) at DC - maxRated control voltage (Uc)ConnectionNumber of auxiliary contacts (normally closed contacts) Number of auxiliary contacts (normally open contacts)Cable length10.2.2 Corrosion resistance10.2.3.1 Verification of thermal stability of enclosures10.2.3.2 Verification of resistance of insulating materials to normal heat10.2.3.3 Resist. of insul. mat. to abnormal heat/fire by internal elect. effects10.2.4 Resistance to ultra-violet (UV) radiation Brochure DisegniMeets the product standard's requirements.Does not apply, since the entire switchgear needs to be evaluated.Does not apply, since the entire switchgear needs to be evaluated.Meets the product standard's requirements.Does not apply, since the entire switchgear needs to be evaluated.Meets the product standard's requirements.Does not apply, since the entire switchgear needs to be evaluated.Does not apply, since the entire switchgear needs to be evaluated.Is the panel builder's responsibility.Is the panel builder's responsibility.Is the panel builder's responsibility.Is the panel builder's responsibility.Is the panel builder's responsibility.The panel builder is responsible for the temperature rise calculation. Eaton will provide heat dissipation data for the devices.Is the panel builder's responsibility. The specifications for the switchgear must be observed.Is the panel builder's responsibility. The specifications for the eaton-bus-adapter-rapidlink-reversing-starter-dimensions-002.eps eaton-bus-adapter-rapidlink-speed-controller-dimensions-002.eps eaton-bus-adapter-rapidlink-speed-controller-dimensions-003.epsETN.RAMO5-D420PNT-412RS1.edzIL034092ZUramo5_v13.stpramo5_v13.dwgGeneration change RAMO4 to RAMO5Generation change from RA-SP to RASP 4.0Generation Change RASP4 to RASP5Generation change from RA-MO to RAMO 4.0Generation Change RA-SP to RASP5Configuration to Rockwell PLC for Rapid LinkDA-DC-00003964.pdfDA-DC-00004184.pdfDA-DC-00004525.pdfDA-DC-00004523.pdf10.2.5 Lifting10.2.6 Mechanical impact10.2.7 Inscriptions10.3 Degree of protection of assemblies10.4 Clearances and creepage distances10.5 Protection against electric shock10.6 Incorporation of switching devices and components 10.7 Internal electrical circuits and connections10.8 Connections for external conductors10.9.2 Power-frequency electric strength10.9.3 Impulse withstand voltage10.9.4 Testing of enclosures made of insulating material 10.10 Temperature rise10.11 Short-circuit rating10.12 Electromagnetic compatibility eCAD modelIstruzioni di installazione mCAD modelNote per l'applicazione Report di certificazioneEaton Corporation plc Eaton House30 Pembroke Road Dublin 4, Ireland © 2023 Eaton. Tutti i diritti riservati. Eaton is a registered trademark.All other trademarks areproperty of their respectiveowners./socialmediaswitchgear must be observed.The device meets the requirements, provided the information in the instruction leaflet (IL) is observed.10.13 Mechanical function。

May 2015DocID026978 Rev 11/12UM1824User manualLi-Ion linear battery charger with LDOIntroductionThe STEVAL-ISB032V1 is a product evaluation board based on the STNS01, which is a linear charger for single cell Li-Ion batteries integrating an LDO regulator and several battery protection functions.The device uses a CC/CV algorithm to charge the battery; the fast-charge current can be programmed using an external resistor. Precharge current and termination current are scaled accordingly. The floating voltage value is 4.2 V.The input supply voltage is normally used to charge the battery and provide power to the LDO regulator; when a valid input voltage is not present and the battery is not empty, the device automatically switches to battery power.The STNS01 integrates overcharge, overdischarge and overcurrent protection circuitry to prevent the battery from being damaged under fault conditions; it also features a charger enable input to stop the charging process when a battery overtemperature is detected by external circuitry.When the shutdown mode is activated the battery power consumption is reduced to less than 500 nA to maximize battery life during shelf time.Figure 1. STEVAL-ISB032V1 evaluation boardGeneral features UM18242/12DocID026978 Rev 11 General features•Charges single-cell Li-Ion batteries with CC-CV algorithm and charge termination •Charge current programmable up to 400 mA •1% accuracy on floating voltage (4.2 V)•Integrated 3.1 V LDO regulator •Automatic power path management •Battery overcharge protection •Battery overdischarge protection •Battery overcurrent protection •Charging timeout•Very low battery leakage in overdischarge/shutdown mode •Low quiescent current •Charge/fault status output •Charger enable inputUM1824Schematic diagramdiagram2 SchematicDocID026978 Rev 13/12Schematic diagram UM1824Table 1. Bill of material (BOM)Component Manufacturer Part number / Description Value Size C1Murata GRM188R71A225KE15D 2.2 µF0603C3 Murata GRM188R71A225KE15D 2.2 µF0603C2Murata GRM188R71A225KE15D 2.2 µF0603C4Murata GRM188R61A475KE15D 4.7 µF0603R2Any Resistor 1 KΩ - 13 KΩ 0603R1Any Resistor600 Ω0603R5Any Resistor0 Ω0603R NTC1Any Resistor10 kΩ0603R3, R4Any Depending on the BATMS status0603D1Any Diode Led06034/12DocID026978 Rev 1UM1824Input/output connections 3 Input/outputconnectionsTable 2. Input and output connectionsReferenceDesignatorName DescriptionJP1VIN –JP1_1: GND power –JP1_2: VIN powerJP2LDO –JP2_1: LDO pin –JP2_2: GNDJP3SYS –JP3_1: GND–JP3_2: SYS pinJP4CHG –JP4_1: CHG pin –JP4_2: GNDJP5CEN –JP5_1: LDO–JP5_2: CEN pin –JP5_3: GNDJP6SD –JP6_1: LDO –JP6_2: SD pin –JP6_3: GNDJP7BATMS –JP7_1: ADC_IN –JP7_2: ADC_EN –JP7_3: GNDJP8BATTERY –JP8_1: BATSNS pin –JP8_2: BAT pin–JP8_3: NTC pin–JP8_4: GNDCN1USB Micro –CN1_1: GND –CN1_2: NC –CN1_3: NC –CN1_4: NC –CN1_5: VINDocID026978 Rev 15/12Input/output connectionsUM18246/12DocID026978 Rev 1Figure 3. In/out connectors1.Connect a power supply source between VIN power (JP1_2) and GND power (JP1_1) and battery between BAT (JP8_2) and GND (JP8_4). The EWM charging the battery at the current value set by R2.2. Connect a battery between BAT (JP8_2) and GND (JP8_4).3. Connect a multimeter between BATSNS (JP8_1) and GND (JP8_4) for a precise battery output voltage sensing.4.Connect a multimeter between SYS (JP3_2) and GND (JP3_1) for a precise SYS voltage sensing. This pin outputs a 3.1 V regulated voltage and can supply up to 100mA5. Connect a multimeter between LDO (JP2_2) and GND (JP2_1) for a precise LDO voltage sensing. This pin can be used to supply up to 100 mA to external devices6.JP5 - Charger enable: A logic low level on this pin disables the battery charger. Atransition from high to low and then back to high restarts the charger when the charge cycle has been stopped for one of the following reasons:–Charging timeout (precharge, fast-charge)–Battery voltage below VPRE after the fast charge has already started –End of charge–The CEN pin has no effect if the charge cycle has been stopped for a battery overcharge condition.7. The CEN pin has no effect if the charge cycle has been stopped for a battery overcharge condition.8.JP6 - Shutdown input: A logic high level on this pin when the input voltage (V IN ) is not valid makes the device enter shutdown mode. In this mode the battery drain is reduced to less than 500 nA and the SYS and LDO voltages are not present. Connecting a valid input voltage (V UVLO <V IN <V INOVP ) restores normal operating conditions if the battery voltage is higher than 3 V (V ODCR , battery voltage overdischarge).9.JP7 - Battery voltage measurement: This pin is internally shorted to the BATSNS pin during normal operating conditions to monitor the battery voltage. The BATMS pin is disconnected from the battery if the LDO output voltage drops to zero (batterydischarge overcurrent, battery overdischarge, shutdown mode, short-circuit on SYS or LDO). By calculating appropriate values of R3 and R4 is possible to obtain a voltage divider of battery voltage to be read with an ADC converter.UM1824Application informationinformation4 ApplicationOperation descriptionThe STNS01 is a power management IC integrating a battery charger with power pathfunction, battery protection circuitry, battery temperature monitoring and a 3.1 V 100 mALDO.When a valid input voltage (V IN) is present on the IN pin, after security checks areperformed, the battery charger starts charging the battery using a constant current /constantvoltage charging algorithm.The input voltage (V IN) is considered to be valid if it is higher than V UVLO and lower thanV INOVP.The power path architecture allows charging the battery and supplying the system at thesame time. When the input voltage is not valid, the LDO (and every external IC connected toSYS) is supplied by the battery through a low resistance path.The device also provides protection to the battery against the following fault conditions:•overcharge•overdischarge•charge overcurrent•discharge overcurrentIf a fault condition is detected while the input voltage is valid (V UVLO < V IN < V INOVP), theCHG pin starts toggling to inform the control logic that an error occurred.The device can also be put in reduced battery drain mode (shutdown, I BAT < 500 nA) tomaximize battery life during end-product shipping and shelf time.Programming the output currentConnect a resistor (R ISET) to ground to set the fastcharge current (I FAST) according to thefollowing equation:I FAST = V ISET / R ISET * KWhere V ISET = 1 V and K = 200. Fast charge currents ranging from 15 mA to 200 mA can beprogrammed. Precharge current and end of charge current are scaled accordingly.Charging currents higher than 200 mA can be programmed but the increased voltage dropover internal MOSFETs can limit the minimum input voltage (V IN) needed to obtain fullcharge.Battery chargeThe charging process starts if the battery voltage is higher than V BATMIN. If the battery isdeeply discharged (the battery voltage is lower than V PRE and higher than V BATMIN) thecharger enters the pre-charge phase and starts charging in constant-current mode using alow current (I PRE = 20% I FAST). If the battery voltage does not reach the V PRE thresholdwithin t PRE, the charging process is stopped and a fault is signaled. When the batteryvoltage reaches the V PRE threshold, the constant-current fast-charge phase is entered andthe charging current is increased to I FAST. The value of I FAST can be programmed from 15mA to 200 mA.DocID026978 Rev 17/12Application information UM1824 Once the fast charge phase has started, if the battery voltage decreases again below V PRE,the charging process is stopped and a fault is signaled. The constant current fast chargephase lasts as long as the battery voltage is lower than V FLOAT. When V BAT reaches V FLOAT,the charging algorithm switches to constant-voltage (CV) mode. During the CV mode thebattery voltage is regulated to V FLOAT and the charging current starts decreasing. When thecharging current reaches the I END threshold (I END = 10%I FAST), the charging process isstopped and the CHG pin is put in high impedance. If the fast charge phase is notterminated within t FAST, the charging process is stopped and a fault is signaled.Figure 4. CC-CV Charging profile (not to scale)Figure 5. Charging cycle profile8/12DocID026978 Rev 1DocID026978 Rev 19/12UM1824Application informationSYS pinLDO input voltage. This pin can be used to supply up to 100 mA to external devices. The voltage source of this pin can be either IN or BAT depending on the operating conditions.LDO pinLDO output voltage. This pin outputs a 3.1 V regulated voltage and can supply up to 100 mA.Table 3. SYS/LDO pin voltageV INV BAT V SYS LDO > V UVLO & < V INOVPx (don't care)V IN (1)1.Voltage drop over internal MOSFETs not included.ON < V UVLO < V ODC (2)2.V ODCR if shutdown mode or overdischarge protection have been previously activated.Not powered OFF < V UVLO > V ODC (2)V BAT (1)ON > V INOVP < V ODC (2)Not powered OFF > V INOVP> V ODC (2)V BAT (1)ONBoard layout UM182410/12DocID026978 Rev 15 Board layoutFigure 6. Assembly layerFigure 7. Top layerFigure 8. Bottom layerUM1824Revision historyhistory6 RevisionTable 4. Document revision historyDate Revision Changes11-Nov-20141Initial release.DocID026978 Rev 111/12UM1824IMPORTANT NOTICE – PLEASE READ CAREFULLYSTMicroelectronics NV and its subsidiaries (“ST”) reserve the right to make changes, corrections, enhancements, modifications, and improvements to ST products and/or to this document at any time without notice. Purchasers should obtain the latest relevant information on ST products before placing orders. ST products are sold pursuant to ST’s terms and conditions of sale in place at the time of order acknowledgement.Purchasers are solely responsible for the choice, selection, and use of ST products and ST assumes no liability for application assistance or the design of Purchasers’ products.No license, express or implied, to any intellectual property right is granted by ST herein.Resale of ST products with provisions different from the information set forth herein shall void any warranty granted by ST for such product. ST and the ST logo are trademarks of ST. All other product or service names are the property of their respective owners.Information in this document supersedes and replaces information previously supplied in any prior versions of this document.© 2015 STMicroelectronics – All rights reserved12/12DocID026978 Rev 1。

Eaton 198950Eaton Moeller® series Rapid Link - Speed controllers, 2.4 A, 0.75 kW, Sensor input 4, Actuator output 2, 230/277 V AC, PROFINET, HAN Q4/2, with manual override switchGeneral specificationsEaton Moeller® series Rapid Link Speed controller198950157 mm270 mm 220 mm 3.61 kgUL 61800-5-1 RoHS UL approval CEIEC/EN 61800-5-1RASP5-2422PNT-412R000S1Product NameCatalog NumberProduct Length/Depth Product Height Product Width Product Weight Certifications Catalog Notes Model Code3 fixed speeds and 1 potentiometer speedcan be switched over from U/f to (vector) speed control Connection of supply voltage via adapter cable on round or flexible busbar junction480 VIs the panel builder's responsibility. The specifications for the switchgear must be observed.400 V AC, 3-phase480 V AC, 3-phaseMeets the product standard's requirements.0.75 kW500 VMeets the product standard's requirements.-40 °C380 VSelector switch (Positions: REV - OFF - FWD)Thermo-click with safe isolationKey switch position AUTOKey switch position OFF/RESETControl unitInternal DC linkPTC thermistor monitoringTwo sensor inputs through M12 sockets (max. 150 mA) for quick stop and interlocked manual operationManual override switchKey switch position HANDPC connectionIGBT inverter2 Actuator outputs0 Hz200 %, IH, max. starting current (High Overload), For 2 seconds Generation change from RA-MO to RAMO 4.0Generation Change RASP4 to RASP5Generation change RAMO4 to RAMO5Generation change from RA-SP to RASP 4.0Configuration to Rockwell PLC for Rapid LinkGeneration Change RA-SP to RASP5Rapid Link 5 - brochureDA-SW-drivesConnect - InstallationshilfeDA-SW-Driver DX-CBL-PC-3M0DA-SW-USB Driver PC Cable DX-CBL-PC-1M5DA-SW-drivesConnect - installation helpDA-SW-USB Driver DX-COM-STICK3-KITDA-SW-drivesConnectMaterial handling applications - airports, warehouses and intra-logistics ETN.RASP5-2422PNT-412R000S1.edzIL034093ZUramo5_v31.dwgrasp5_v31.stpDA-DC-00004184.pdfDA-DC-00004514.pdfDA-DC-00003964.pdfDA-DC-00004508.pdfeaton-bus-adapter-rapidlink-speed-controller-dimensions-005.eps eaton-bus-adapter-rapidlink-speed-controller-dimensions-002.eps eaton-bus-adapter-rapidlink-speed-controller-dimensions-004.eps eaton-bus-adapter-rapidlink-speed-controller-dimensions-003.epsMains voltage - max10.11 Short-circuit ratingRated operational voltage10.4 Clearances and creepage distancesOutput at quadratic load at rated output voltage - max Output voltage - max10.2.3.1 Verification of thermal stability of enclosures Ambient storage temperature - minMains voltage - minFitted with:Output frequency - minStarting current - max Applikasjonsmerknader BrosjyrereCAD model Installeringsinstruksjoner mCAD model SertifiseringsrapporterTegningerevery 20 seconds, Power sectionRated conditional short-circuit current (Iq)10 kAAmbient operating temperature - max40 °CCommunication interfacePROFINET, optionalAssigned motor power at 115/120 V, 60 Hz, 1-phase1 HPOutput frequency - max500 HzSwitching frequency8 kHz, 4 - 32 kHz adjustable, fPWM, Power section, Main circuitFeaturesParameterization: drivesConnectParameterization: drivesConnect mobile (App) Parameterization: FieldbusParameterization: KeypadAmbient operating temperature - min-10 °CBraking current≤ 0.6 A (max. 6 A for 120 ms), Actuator for external motor brakeNumber of HW-interfaces (serial TTY)10.6 Incorporation of switching devices and componentsDoes not apply, since the entire switchgear needs to be evaluated.Nominal output current I2N2.4 A10.2.6 Mechanical impactDoes not apply, since the entire switchgear needs to be evaluated.10.3 Degree of protection of assembliesDoes not apply, since the entire switchgear needs to be evaluated.Product categorySpeed controllerRadio interference classC2, C3: depending on the motor cable length, the connected load, and ambient conditions. External radio interference suppression filters (optional) may be necessary.C1: for conducted emissions onlyHeat dissipation capacity Pdiss0 WRated control voltage (Uc)24 V DC (-15 %/+20 %, external via AS-Interface® plug) 230/277 V AC (external brake 50/60 Hz)Assigned motor power at 460/480 V, 60 Hz, 3-phase1 HPNumber of HW-interfaces (RS-422)Mains current distortion120 %ProtocolPROFINET IO10.9.2 Power-frequency electric strengthIs the panel builder's responsibility.Overvoltage categoryIIIDegree of protectionIP65NEMA 12Ambient storage temperature - max70 °CRated impulse withstand voltage (Uimp)2000 VConnectionPlug type: HAN Q4/2Overload currentAt 40 °CFor 60 s every 600 sFunctionsFor actuation of motors with mechanical brake3 fixed speeds1 potentiometer speedOutput at linear load at rated output voltage - max0.75 kWMains voltage tolerance380 - 480 V (-10 %/+10 %, at 50/60 Hz)Leakage current at ground IPE - max3.5 mAConverter typeU converter10.2.2 Corrosion resistanceMeets the product standard's requirements.Supply frequency50/60 Hz10.2.4 Resistance to ultra-violet (UV) radiationMeets the product standard's requirements.10.2.7 InscriptionsMeets the product standard's requirements.Shock resistance15 g, Mechanical, According to IEC/EN 60068-2-27, 11 ms, Half-sinusoidal shock 11 ms, 1000 shocks per shaftApplication in domestic and commercial area permittedYesNumber of inputs (analog)Number of phases (output)310.12 Electromagnetic compatibilityIs the panel builder's responsibility. The specifications for the switchgear must be observed.10.2.5 LiftingDoes not apply, since the entire switchgear needs to be evaluated.Number of HW-interfaces (RS-485)1Number of HW-interfaces (industrial ethernet)Efficiency97 % (η)System configuration typeAC voltageCenter-point earthed star network (TN-S network)Phase-earthed AC supply systems are not permitted.10.8 Connections for external conductorsIs the panel builder's responsibility.ProtectionFinger and back-of-hand proof, Protection against direct contact (BGV A3, VBG4)Braking voltage230/277 V AC -15 % / +10 %, Actuator for external motor brakeApplication in industrial area permittedYesClimatic proofingIn accordance with IEC/EN 50178< 95 %, no condensation10.9.3 Impulse withstand voltageIs the panel builder's responsibility.Overload current IL at 150% overload3.6 AInput current ILN at 150% overload2.5 ANumber of HW-interfaces (RS-232)Number of inputs (digital)4Current limitation0.2 - 2.4 A, motor, main circuitAdjustable, motor, main circuitCable lengthC2 ≤ 5 m, maximum motor cable lengthC1 ≤ 1 m, maximum motor cable lengthC3 ≤ 25 m, maximum motor cable length10.5 Protection against electric shockDoes not apply, since the entire switchgear needs to be evaluated.Mounting positionVerticalMains switch-on frequencyMaximum of one time every 60 seconds10.13 Mechanical functionThe device meets the requirements, provided the information in the instruction leaflet (IL) is observed.10.9.4 Testing of enclosures made of insulating materialIs the panel builder's responsibility.Heat dissipation per pole, current-dependent Pvid0 WElectromagnetic compatibility1st and 2nd environments (according to EN 61800-3)Resolution0.1 Hz (Frequency resolution, setpoint value)Assigned motor power at 460/480 V, 60 Hz1 HPRelative symmetric net voltage tolerance10 %Rated operational current (Ie)2.4 A at 150% overload (at an operating frequency of 8 kHz and an ambient air temperature of +40 °C)Number of outputs (analog)Rated operational power at 380/400 V, 50 Hz, 3-phase0.75 kWNumber of HW-interfaces (USB)Operating modeU/f controlBLDC motorsSynchronous reluctance motorsSensorless vector control (SLV)PM and LSPM motorsRated frequency - min45 HzDelay time< 10 ms, Off-delay< 10 ms, On-delayNumber of outputs (digital)2Power consumption32 W10.2.3.2 Verification of resistance of insulating materials to normal heatMeets the product standard's requirements.10.2.3.3 Resist. of insul. mat. to abnormal heat/fire by internal elect. effectsMeets the product standard's requirements.Number of HW-interfaces (other)Rated frequency - max66 HzVibrationResistance: 6 Hz, Amplitude 0.15 mmResistance: 10 - 150 Hz, Oscillation frequencyResistance: According to IEC/EN 60068-2-6Resistance: 57 Hz, Amplitude transition frequency on accelerationShort-circuit protection (external output circuits)Type 1 coordination via the power bus' feeder unit, Main circuit10.7 Internal electrical circuits and connectionsIs the panel builder's responsibility.Braking torqueAdjustable to 100 % (I/Ie), DC - Main circuit≤ 30 % (I/Ie)Relative symmetric net frequency tolerance10 %10.10 Temperature riseThe panel builder is responsible for the temperature rise calculation. Eaton will provide heat dissipation data for the devices.Number of HW-interfaces (parallel)Assigned motor power at 230/240 V, 60 Hz, 1-phase1 HPInterfacesNumber of slave addresses: 31 (AS-Interface®) Specification: S-7.4 (AS-Interface®)Max. total power consumption from AS-Interface® power supply unit (30 V): 250 mANumber of phases (input)3Eaton Corporation plc Eaton House30 Pembroke Road Dublin 4, Ireland © 2023 Eaton. Med enerett.Eaton is a registered trademark.All other trademarks are property of their respectiveowners./socialmedia27.5 W at 50% current and 90% speed 31.8 W at 100% current and 90% speed 33.5 W at 25% current and 50% speed 34.6 W at 50% current and 50% speed 35.1 W at 25% current and 0% speed 36.6 W at 100% current and 50% speed 36.8 W at 50% current and 0% speed 40.7 W at 100% current and 0% speed 2Max. 2000 mAbove 1000 m with 1 % performance reduction per 100 mHeat dissipation at current/speed Number of interfaces (PROFINET)Altitude。

]Delta SW LE910-EU1 and LE910 EU V2 Products80519DSW10146A Rev. 3 – 2019-12-201 6SPECIFICATIONS ARE SUBJECT TO CHANGE WITHOUT NOTICENOTICEWhile reasonable efforts have been made to assure the accuracy of this document, Telit assumes no liability resulting from any inaccuracies or omissions in this document, or from use of the information obtained herein. The information in this document has been carefully checked and is believed to be reliable. However, no responsibility is assumed for inaccuracies or omissions. Telit reserves the right to make changes to any products described herein and reserves the right to revise this document and to make changes from time to time in content hereof with no obligation to notify any person of revisions or changes. Telit does not assume any liability arising out of the application or use of any product, software, or circuit described herein; neither does it convey license under its patent rights or the rights of others.It is possible that this publication may contain references to, or information about Telit products (machines and programs), programming, or services that are not announced in your country. Such references or information must not be construed to mean that Telit intends to announce such Telit products, programming, or services in your country. COPYRIGHTSThis instruction manual and the Telit products described in this instruction manual may be, include or describe copyrighted Telit material, such as computer programs stored in semiconductor memories or other media. Laws in the Italy and other countries preserve for Telit and its licensors certain exclusive rights for copyrighted material, including the exclusive right to copy, reproduce in any form, distribute and make derivative works of the copyrighted material. Accordingly, any copyrighted material of Telit and its licensors contained herein or in the Telit products described in this instruction manual may not be copied, reproduced, distributed, merged or modified in any manner without the express written permission of Telit. Furthermore, the purchase of Telit products shall not be deemed to grant either directly or by implication, estoppel, or otherwise, any license under the copyrights, patents or patent applications of Telit, as arises by operation of law in the sale of a product.COMPUTER SOFTWARE COPYRIGHTSThe Telit and 3rd Party supplied Software (SW) products described in this instruction manual may include copyrighted Telit and other 3rd Party supplied computer programs stored in semiconductor memories or other media. Laws in the Italy and other countries preserve for Telit and other 3rd Party supplied SW certain exclusive rights for copyrighted computer programs, including the exclusive right to copy or reproduce in any form the copyrighted computer program. Accordingly, any copyrighted Telit or other 3rd Party supplied SW computer programs contained in the Telit products described in this instruction manual may not be copied (reverse engineered) or reproduced in any manner without the express written permission of Telit or the 3rd Party SW supplier. Furthermore, the purchase of Telit products shall not be deemed to grant either directly or by implication, estoppel, or otherwise, any license under the copyrights, patents or patent applications of Telit or other 3rd Party supplied SW, except for the normal non-exclusive, royalty free license to use that arises by operation of law in the sale of a product.USAGE AND DISCLOSURE RESTRICTIONSI. License AgreementsThe software described in this document is the property of Telit and its licensors. It is furnished by express license agreement only and may be used only in accordance with the terms of such an agreement.II. Copyrighted MaterialsSoftware and documentation are copyrighted materials. Making unauthorized copies is prohibited by law. No part of the software or documentation may be reproduced, transmitted, transcribed, stored in a retrieval system, or translated into any language or computer language, in any form or by any means, without prior written permission of Telit III. High Risk MaterialsComponents, units, or third-party products used in the product described herein are NOT fault-tolerant and are NOT designed, manufactured, or intended for use as on-line control equipment in the following hazardous environments requiring fail-safe controls: the operation of Nuclear Facilities, Aircraft Navigation or Aircraft Communication Systems, Air Traffic Control, Life Support, or Weapons Systems (High Risk Activities"). Telit and its supplier(s) specifically disclaim any expressed or implied warranty of fitness for such High Risk Activities.IV. TrademarksTELIT and the Stylized T Logo are registered in Trademark Office. All other product or service names are the property of their respective owners.V. Third Party RightsThe software may include Third Party Right software. In this case you agree to comply with all terms and conditions imposed on you in respect of such separate software. In addition to Third Party Terms, the disclaimer of warranty and limitation of liability provisions in this License shall apply to the Third Party Right software.TELIT HEREBY DISCLAIMS ANY AND ALL WARRANTIES EXPRESS OR IMPLIED FROM ANY THIRD PARTIES REGARDING ANY SEPARATE FILES, ANY THIRD PARTY MATERIALS INCLUDED IN THE SOFTWARE, ANY THIRD PARTY MATERIALS FROM WHICH THE SOFTWARE IS DERIVED (COLLECTIVELY “OTHER CODE”), AND THE USE OF ANY OR ALL THE OTHER CODE IN CONNECTION WITH THE SOFTWARE, INCLUDING (WITHOUT LIMITATION) ANY WARRANTIES OF SATISFACTORY QUALITY OR FITNESS FOR A PARTICULAR PURPOSE.NO THIRD PARTY LICENSORS OF OTHER CODE SHALL HAVE ANY LIABILITY FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING WITHOUT LIMITATION LOST PROFITS), HOWEVER CAUSED AND WHETHER MADE UNDER CONTRACT, TORT OR OTHER LEGAL THEORY, ARISING IN ANY WAY OUT OF THE USE OR DISTRIBUTION OF THE OTHER CODE OR THE EXERCISE OF ANY RIGHTS GRANTED UNDER EITHER OR BOTH THIS LICENSE AND THE LEGAL TERMS APPLICABLE TO ANY SEPARATE FILES, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGES.APPLICABILITY TABLE PRODUCTSLE910-EU1LE910-EU V2CONTENTSNOTICE 2COPYRIGHTS (2)COMPUTER SOFTWARE COPYRIGHTS (2)USAGE AND DISCLOSURE RESTRICTIONS (3)I.License Agreements (3)II.Copyrighted Materials (3)III.High Risk Materials (3)IV.Trademarks (3)V.Third Party Rights (3)APPLICABILITY TABLE (4)CONTENTS (5)1.INTRODUCTION (6)2.DELTA SW 20.00.XX5 – 20.00.XX6 (8)General Enhancements (8)3.DELTA SW 20.00.XX4 – 20.00.XX5 (9)General Enhancements (9)4.DELTA SW 20.00.XX3 – 20.00.XX4 (15)General Enhancements (15)5.DELTA SW 20.00.XX2 – 20.00.XX3 (16)New Features (16)General Enhancements (18)6.DOCUMENT HISTORY (21)1. INTRODUCTION1.1. ScopeScope of this document is to detail the corrections, changes or enhancements made to the software of Telit modules.1.2. AudienceThis document is intended for Telit customers.1.3. Contact Information, SupportFor general contact, technical support services, technical questions and report documentation errors contact Telit Technical Support at:•*****************•*********************•*****************Alternatively, use:/supportFor detailed information about where you can buy the Telit modules or for recommendations on accessories and components visit:Our aim is to make this guide as helpful as possible. Keep us informed of your comments and suggestions for improvements.Telit appreciates feedback from the users of our information.1.4. Related Documents•Telit LE910-V2 Modules AT Commands Reference Guide, 80446ST10707A •Telit's Modules Software User Guide, 1vv03007842. DELTA SW 20.00.XX5 – 20.00.XX6General EnhancementsType Description SW 20.00.xx6 ID#46567 Enhancement to AT+CGCONTRDP to provide 2nd DNSID#37286 Enhancement to AT#QDNS with IPV4V6 PDP typeID#43540 Enhancement to DNS resolution with IPV4V6 dual stack3.DELTA SW 20.00.XX4 – 20.00.XX5General Enhancements Type Description SW 20.00.xx5 ID#44635 Fixed APDU command that was not working properly ID#45060 Fixed AT+CSIM wrong response if size is greater than 255 bytesID#40690 ERRC fix to handle UE receives RRCConnectionReconfiguration message from NWwith list of GSM arfcns, band indicatorBandIndicatorGERAN_pcs1900 and arfcn list1,3,5,7,8,11,13,15,17 scenarioID#42968 2G Thermal/Vbatt mitigation ID#43819 Fixed AT#RXTOGGLE default value ID#39795 Fixed USB cable disconnect handling ID#40663 Fix of missing CONNECT 9600 in the following scenario: - AT&D2 - close CS data call with DTR OFFID#43188 Changed the way to identify the callback which returns the response of AT+CRSM.ID#39743 Corrected test command response format; removed "hidden" attribute; mapped values from 1 to 67, thatwere causing malfunctioning in subsequentcommands, to value 0.ID#40545 Check bin integrity fix ID#41318 Added a missing check to avoid using GSM not meaningful data. In #WS46=22 AT#MONI=5 andMONI=6 return wronglyID#41867 Fixed incorrect behavior after "AT+CPBW=5" commandID#42323 Fix of AT#IREG? wrongly returning #IREG: 1 in case of Intel state UTA_IMS_STATE_DEREGISTERING.ID#42559 Fix of issue with NCM first activation fails afterCFUN=4/CFUN=1.ID#42862 Fixed AppZone: m2m_hw_get_ms_count() -unexpected <m_secs> parameter value after counterstop and resetID#43071 Fixed App binary incorrect behavior after app startID#40290 Correct scanning of available mobile networks fixID#41428 Fix of VSD1 voltage issueID#41907 Azl memory alignment after CRC ( axf aligned ) on LTEID#39361 Fix of module incorrect behavior in 2G after border crossingID#39797 Fix of watchdog behaviorID#36032 Fixed problem AT#TESTMODE="RL" in 2G network ID#36225 +CLAC : removed AT#SECKEY from listID#38422 Fix of bug: AT+CSIM wrong response if size is greater than 255 bytesID#40383 AT#SIMINCFG was wrongly hiddenID#41233 It is now possible to write an additional telephonenumber (ANR) even if the USIM does not support itID#40420 Fixed +CGDCONT sometimes saving wrongparametersID#37546 Fixed module remaining in search mode with CREG?after changing from 4G to 3GID#37829 Module was unable to receive the paging for MTdata/sms for a period of timeID#38304 Fixed CGATT 0-1 cycles activation wrong behaviorID#39609 Fixed SIM behavior in QSS:2,2 after SIM OTAID#37370 Added a missing check for MMS on incoming WAP Push SMS to verify if it is a concatenated one, or asingle message.ID#38875 Fixed CMUX DLCI 1 activation after timeoutID#39111 Corrected Erase File System HCC commandimplementationID#39430 Fixed AT+CPBW not updating the entry name.ID#34132 Supplementary Services are sent via PS domaininstead of CS domain after a IMS log offID#35574 UTA _MM_AUDIO enabledID#36515 Appzone: ms counter updating after deep sleepID#37551 Added a control to correctly handle the response to SST file properties request when received during SIMservices checkID#37649 Fixed AT+CGCLASS="CC" detach behavior fromGPRS serviceID#37879 Fixed IMS registering after REFRESH type 0ID#38206 Fixed a check on the DUALAPN CIDS duringdeactivationID#38216 Fixed AT#MONI sometimes showing wrong <RSRQ> valueID#38249 Fixed AppZone aux UART callbackID#38321 Fixed IP format when type is set as IPV4V6ID#38638 Fixed NCM not working with PORTCFG=3ID#38843 Band20 ACLR improvementID#25106 Fixed "+CGPADDR=" IPV6 AddressID#34643 Improved +CFUN: 7 cyclic sleep modeID#36032 Fixed problem AT#TESTMODE="RL" in 2G network ID#36417 Fixed RAT changing (3g -> 4G) module notregisteringID#36807 Fixed +CGATT=0 behaviorID#36906 Fixed AppZone SSL TLS 1.2,M2M_SSL_CONNECTION_CONTEXT that couldn’tbe used by more than a taskID#37399 Added store/restore of the APN in the file system for NVM recoveryID#37543 AppZone: m2m_fs_copy() was returningM2M_API_RESULT_FAIL if file to copy is 0 byte sized ID#37547 Added the ability to control DTMF tone volumeseparately from "master" volumeID#37621 RXToggle configuration saved in NVMID#37587 Interface was not working properly after CFUN 4 /CFUN 1 followed by CGATT 0 / CGATT 1ID#35243 Sometimes, changing RAT (3g -> 4G) first dialup was not working, while second one PASSID#33544 Fixed technology change from 3G to 4G that couldn’t register automatically to IMSID#33139 Fixed $QCAPNE wrong behavior after set command ID#26798 Fixed flow control behavior with UDP connectionID#28354 AT#STACFG: AT instanced fixed at power onID#29372 Appzone: fixed unreachableM2M_SOCKET_STATE_CONNECTED socket stateID#31406 Fixed #SWMCHKUPD interaction with outgoingconnectivity if executed multiple timesID#31731 AppZone: Fixed wrong Network APIs RAT indication ID#33039 Fixed failure on second connection with #SDID#33392 Crash with data connection FTPAPPEXT=x,1,FTPLIST, FTPGET...ID#35380 AT#EVMONI: fixed STARTUP event when SIM PIN request enabledID#36032 Fixed a problem with AT#TESTMODE="RL" in 2GnetworkID#36223 AT#SA : fixed a syntax error in socket connections rangeID#36274 Porting of AT#TEST=NVM_AUTOREPAIRID#36346 Fixed CellID missing in 2G in AT#MONIID#36455 Corrected AT#MBN incorrect responseID#36626 AppZone: fixed EasyAT release parser issueID#36723 Added a buffer size check in SYprintfID#36751 ATD range number was not aligned with HSPAID#36892 Fixed wrong value issue in +CIND caused by Call to UpdateMessageMax function in +CPMSID#36896 Fixed AT#RFSTS issueID#36911 Function and prototype m2m_uart_close_hwch added ID#37064 Skipping IPv6 connection retries if the first try failsID#37093 Fixed AppZone: m2m_os_destroy_taskID#37115 Slow net synchronization with PIN enabled & +WS46:28 - fix improvement4. DELTA SW 20.00.XX3 – 20.00.XX4General EnhancementsType Description SW 20.00.xx4ID#38505 Fix to improve ETWS information handling •ID#38450Improvement to refresh neighbors list with AT#MONI• readID#37932Fix for SIB decoding issue •5.DELTA SW 20.00.XX2 – 20.00.XX3New Features Description SW 20.00.xx3AppZone: implemented new m2m_ssl API that allow to set right TLS protocol (TLS1.0/TLS1.1 and TLS1.2)• AppZone: implemented new API m2m_ipraw_cfg for IPRAW IPV4 and IPV6• AppZone: implemented API to support AUXILIARY UART • AppZone: implemented new API for Watchdog management • AppZone: implemented new API to set context on specified CID • AppZone: implemented new API m2m_hw_sleep_mode_cfg to manage power saving mode• AppZone: support for easyAT • Support TLS1.2 • Support CFUN9 - Incoming GPRS packed wake-up the DUT • EasyIP: Increase number of sockets from 6 to 10 • AT#MTUSIZE=<mtu>: implemented new AT command in order to set the MTU size• MBIM: support multiple bearer connection in parallel • AT#APPSSLCFG implemented AT command to configure cipher suite, authentication level and TLS version for a maximum of 5applications.• Added storing of SMS in ME and SM memories • AT+CMAR/AT#CMAR: Implemented AT command to format NVM and File system•AT#IIDIPV6=<cid>,<IID>: Implemented AT command in order to• set the IID to a certain CID• AT#MBIMCFG: implemented AT command to configure CID to beused for MBIM connection• AT#PDPAUTH: implemented AT command to set theauthentication parameters for all CIDsAT#RXTOGGLE: Implemented AT command to set main or• diversity antenna, command used in test mode for certificationpurposeAT+IPR: Updated UART speed up to 3Mbps •General EnhancementsType Description SW 20.00.xx3ID#32982Improvement in the report of AT+CSQ and AT+CESQ,• adjust RSSI calculation.ID#34680 Manage properly NCM disconnection (AT#NCMD=0)•and dialup when they are used togetherID#35612 Updated the +CCLK: time zone range to “-96…+96” •ID#27164 Fix on received URL #DTMFEV with DTMF enabled •ID#32272 Support +CRSM=192,28423 with a SIM with PIN•enabledID#35240 Improvement on storing #HSMICG in the extended•profileID#30283 Restored LTE neighbor information’s in AT#MONI and•AT#MONIZIP, added <qrxlevmin> and <pci> forserving cellID#33206 restored timers T3402 and T3412 in AT#RFSTS •ID#34984 Developed standard usage of “[]:” for IPv6 address,•example AT#FTPOPEN=”[ipv6_addr]:port_numID#35119 Added timestamp on +CMT unsolicited in incoming•PDUID#35123 Added conversion table from ISO Latin 8-bit to•PCCP437ID#34464 Antenna detection: Fixed behavior of repGPIO on•AT#GSMADID#33872 STN: 254 not always received when performing a SAT•request with Vodafone: implemented a better handlingfor SIM APP END indicationID#34313 Removed SIM switch off when CFUN=4 is issued toavoid IMS registration issue once CFUN=1 is usedagain. SIM remains active•ID#34343 Fixed reply Time on AT#PING; it was not aligned totimeout configured.•ID#32164 Improvement on AT#CSURV scan of 4G channelwithout SIM•ID#34236 #PSNT Corrected handling of technology indication: itreported a wrong network type when EGPRS•ID#33195 AppZone: Improvement on #HTTPRCV to reports OKif called from virtual com•ID#30588 Improvement on AT+CRSM locking up the ATinterface if SIM doesn’t include specific folder•ID#33155 MBIMCFG has been extended to allow the selectionof both CID 1 and CID 3•ID#33721 Removed DCD glitch when module received anincoming data call•ID#30330 Improvement on command AT+CMGL="ALL", it hasbeen extended to cover also the 5th AT instance thatis available only in SMSATRUN and TCPATRUN•ID#32401 #CMUXMODE=1 - CFUN=5 correctly managed onvirtual channel by DTR toggle•ID#32227 Improvement on AT#CSURV to avoid missingMCC/MNC in LTE scan response if the same cell isshared by two PLMNs (MOCN support)•ID#23686 Reduce timing to configure GPIOs status duringstartup of the system•ID#33045 DW Cloud: improvements to support Methodexecution request parameters with var in a multiselectstring•ID# 31957 FIREWALL: improvement on storing thedisable/enable setting in NVM•ID#29202 Improvement on-off procedure to make sure that 5seconds on-off are always enough to power on themodule after a FW upgrade and in all other scenarios•ID#31001 MBIM command DEVICE_CAPS reports the sameversion string as AT+CGMR•ID#30878 I2C Clock Stretching support •6. DOCUMENT HISTORYRevision Date Changes0 2018-01-10 Delta SW 20.00.xx2 - 20.00.xx31 2018-10-19 Delta SW 20.00.xx3 - 20.00.xx42 2019-07-19 Delta SW 20.00.xx4 - 20.00.xx53 2019-12-20 Delta SW 20.00.xx5 – 20.00.xx680519DSW10146A Rev. 2 Page 21 of 22 2019-12-20[04.2016] Mod. 0809 2016-08 Rev.7。

STEVAL-FKI001V1Features•WS2118-00 Sigfox™ BLE module (Jorjin):–Embedded BlueNRG-132 Bluetooth low energy SOC based on ultra-lowpower Arm ® Cortex ®-M0 (up to +8 dBm BLE RF output power, excellent receiver sensitivity -88 dBm)–Embedded S2-LPQTR ultra-low power sub-1 GHz transceiver tuned for826-958 MHz frequency bands (up to +16 dBm sub-1GHz RF output power, excellent receiver sensitivity down to -130 dBm, modulationschemes: 2-(G)FSK, 4-(G)FSK, OOK, and ASK, air data rate from 0.1 to 500 kbps, ultra-low power consumption: (7 mA RX, 10 mA TX @+10 dBm ), low duty cycle RX/TX operation mode, automatic acknowledgement, retransmission, and timeout protocol engine)–BALF-NRG-01D3 50 Ω integrated balun, matching network and harmonicsfilter companion device of BlueNRG-1–Low power and wide supply voltage range: 2.0 to 3.6 V –Dimensions: 22 mm(l) x 24 mm(w) x 2.8 mm(h)–Operating temperature range: -40 °C to +85 °C –U.FL RF interface connectors •USB interface•Arduino™ Uno V3 connectors •JTAG debug connectors•Antennas: 2.4 GHz and Sub-1 GHz •USB cable•RoHS compliant and China RoHS compliant •CE compliant •WEEE compliantDescriptionThe STEVAL-FKI001V1 development kit is a cost-effective tool to help you design solutions based on Sigfox™, Bluetooth ® low energy and sub-1GHz technologies.The kit features a fully programmable module WS2118 (by Jorjin), which embeds the BlueNRG-1 system-on-chip for Bluetooth ® low energy functionality and the S2-LP transceiver for sub-1GHz functionality such as LPWAN protocols.This development effectively combines Bluetooth low energy features with the connection capacity of Sigfox wide-area networks.It includes examples and recommendations regarding the simultaneous use of the two protocols. Very low active RF and MCU current, and low-power mode current consumption provide excellent battery lifetime, allowing operation with coin cell batteries and energy-harvesting applications.The STEVAL-FKI001V1 evaluation board uses the Arduino interface to help development, as it is compatible with ST Arduino shield boards featuring MEMS motion sensors, environmental sensors, and Time-of-Flight (ToF) ranging sensors.Summary tableDual radio BLE andSub-1GHz development kit for Sigfox™ and LPWAN protocols with BlueNRG-1 and S2-LP STEVAL-FKI001V1ultra-low power, high performance, sub-1GHz transceiverS2-LPBluetooth low energy wireless system-on-chipBlueNRG-1Dual radio BLE and Sub-1GHz development kit for Sigfox™ and LPWANprotocols with BlueNRG-1 and S2-LPSTEVAL-FKI001V1Data brief1Schematic diagramFigure 1. STEVAL-FKI001V1 board schematic (1 of 2)DIO0I/O pin FunctionDIO1SPI master CLK pin connected internally to SCLK pin of S2-LP SPI master CS pin connected internally to CS pin of S2-LP DIO2DIO3DIO4DIO5DIO6DIO7DIO8DIO9DIO10DIO11DIO12DIO13DIO14SPI master output pin connected internally to SDI pin of S2-LP SPI master input pin connected internally to SDO pin of S2-LP Connected internally to SCL pin of STSAFE-A1SX Connected internally to SDA pin of STSAFE-A1SXConnected internally to RESET pin of STSAFE-A1SX or EEPROM_CS Connected internally to GPIO3 of S2-LP for interrupt.Connected internally to SDN pin of S2-LPBootloader pin / LED driver UART TX UART RX JTCK-SWTCK JTMS-SWTDIO Switch inputScrew HoleFor AntennaSTEVAL-FKI001V1Figure 2. STEVAL-FKI001V1 board schematic (2 of 2)STEVAL-FKI001V1STEVAL-FKI001V1Revision historyTable 1. Document revision historySTEVAL-FKI001V1IMPORTANT NOTICE – PLEASE READ CAREFULLYSTMicroelectronics NV and its subsidiaries (“ST”) reserve the right to make changes, corrections, enhancements, modifications, and improvements to ST products and/or to this document at any time without notice. Purchasers should obtain the latest relevant information on ST products before placing orders. ST products are sold pursuant to ST’s terms and conditions of sale in place at the time of order acknowledgement.Purchasers are solely responsible for the choice, selection, and use of ST products and ST assumes no liability for application assistance or the design of Purchasers’ products.No license, express or implied, to any intellectual property right is granted by ST herein.Resale of ST products with provisions different from the information set forth herein shall void any warranty granted by ST for such product.ST and the ST logo are trademarks of ST. All other product or service names are the property of their respective owners.Information in this document supersedes and replaces information previously supplied in any prior versions of this document.© 2018 STMicroelectronics – All rights reservedSTEVAL-FKI001V1。

BYV32E-200Dual rugged ultrafast rectifier diode, 20 A, 200 VRev. 04 — 27 February 2009Product data sheet 1.Product profile1.1General descriptionUltrafast dual epitaxial rectifier diode in a SOT78 (TO-220AB) plastic package.1.2Features and benefitsHigh reverse voltage surge capability High thermal cycling performanceLow thermal resistance Soft recovery characteristic minimizes power consuming oscillationsVery low on-state loss1.3ApplicationsOutput rectifiers in high-frequencyswitched-mode power supplies1.4Quick reference dataTable 1.Quick referenceSymbol Parameter Conditions Min Typ Max Unit V RRM repetitive peakreverse voltage--200VI O(AV)average outputcurrent square-wave pulse; δ=0.5;T mb≤115°C; both diodesconducting; see Figure 1;see Figure 2--20AI RRM repetitive peakreverse currentt p=2µs; δ=0.001--0.2AV ESD electrostaticdischarge voltage HBM; C = 250 pF; R = 1.5kΩ; all pins--8kVDynamic characteristicst rr reverse recoverytime I F=1A;V R=30V;dI F/dt=100A/µs;T j=25°C; ramp recovery;see Figure 5-2025nsI R=1A;I F=0.5A;T j=25°C; step recovery;measured at reverse current= 0.25 A; see Figure 6-1020nsStatic characteristicsV F forward voltage I F=8A;T j=150°C;seeFigure 4-0.720.85V2.Pinning information3.Ordering informationTable 2.Pinning information Pin Symbol Description Simplified outline Graphic symbol1A1anode 1SOT78 (TO-220AB; S C-46)2K cathode 3A2anode 2mbKmounting base; cathode12mb3sym125Table 3.Ordering information Type number PackageName Description VersionBYV32E-200TO-220AB; SC-46plastic single-ended package; heatsink mounted; 1 mounting hole; 3-lead TO-220ABSOT784.Limiting valuesTable 4.Limiting values In accordance with the Absolute Maximum Rating System (IEC 60134).Symbol ParameterConditionsMin Max Unit V RRM repetitive peak reverse voltage-200V V RWM crest working reverse voltage -200V V R reverse voltage DC-200V I O(AV)average output currentsquare-wave pulse; δ=0.5; T mb ≤115°C; both diodes conducting; see Figure 1; see Figure 2-20A I FRM repetitive peak forward currentδ=0.5; t p =25µs; T mb ≤115°C; per diode -20A I FSMnon-repetitive peak forward currentt p =8.3ms; sine-wave pulse; T j(init)=25°C; per diode-137A t p =10ms; sine-wave pulse; T j(init)=25°C;per diode-125A I RRM repetitive peak reverse currentδ=0.001; t p =2µs -0.2A I RSM non-repetitive peak reverse current t p =100µs-0.2A T stg storage temperature -40150°C T j junction temperature-150°C V ESDelectrostatic discharge voltageHBM; C = 250 pF; R = 1.5 k Ω; all pins -8kV5.Thermal characteristics6.CharacteristicsTable 5.Thermal characteristics Symbol ParameterConditionsMin Typ Max Unit R th(j-mb)thermal resistance from junction to mounting base with heatsink compound; both diodes conducting -- 1.6K/W with heatsink compound; per diode; seeFigure 3-- 2.4K/W R th(j-a)thermal resistance from junction to ambient-60-K/WTable 6.Characteristics Symbol Parameter Conditions Min Typ Max Unit Static characteristicsV F forward voltage I F =20A; T j =25°C-1 1.15V I F =8A; T j =150°C; see Figure 4-0.720.85V I Rreverse currentV R =200V; T j =100°C -0.20.6mA V R =200V; T j =25°C-630µADynamic characteristics Q r recovered charge I F =2A; V R =30V;dI F /dt =20A/µs; T j =25°C-812.5nC t rrreverse recovery timeI F =1A; V R =30V;dI F /dt =100A/µs; ramp recovery; T j =25°C; see Figure 5-2025ns I F =0.5A; I R =1A; step recovery; measured at reverse current = 0.25 A; T j =25°C;see Figure 6-1020nsV FRforward recovery voltageI F =1A; dI F /dt =10A/µs; T j =25°C; see Figure 7--1V7.Package outlineFig 8.Package outline SOT78 (TO-220AB)8.Revision historyTable 7.Revision historyDocument ID Release date Data sheet status Change notice SupersedesBYV32E-200_420090227Product data sheet-BYV32E_SERIES_3 Modifications:•The format of this data sheet has been redesigned to comply with the new identityguidelines of NXP Semiconductors.•Legal texts have been adapted to the new company name where appropriate.•Package outline updated.•Type number BYV32E-200 separated from data sheet BYV32E_SERIES_3BYV32E_SERIES_320010301Product specification-BYV32E_SERIES_2 BYV32E_SERIES_219980701Product specification-BYV32EB_SERIES_1 BYV32EB_SERIES_119960801Product specification--9.Legal information9.1Data sheet status[1]Please consult the most recently issued document before initiating or completing a design.[2]The term 'short data sheet' is explained in section "Definitions".[3]The product status of device(s) described in this document may have changed since this document was published and may differ in case of multiple devices. The latest product status information is available on the Internet at URL .9.2DefinitionsDraft — The document is a draft version only. The content is still under internal review and subject to formal approval, which may result in modifications or additions. NXP Semiconductors does not give any representations or warranties as to the accuracy or completeness ofinformation included herein and shall have no liability for the consequences of use of such information.Short data sheet — A short data sheet is an extract from a full data sheet with the same product type number(s) and title. A short data sheet is intended for quick reference only and should not be relied upon to contain detailed and full information. For detailed and full information see the relevant full data sheet, which is available on request via the local NXP Semiconductors sales office. In case of any inconsistency or conflict with the short data sheet, the full data sheet shall prevail.9.3DisclaimersGeneral — Information in this document is believed to be accurate andreliable. However, NXP Semiconductors does not give any representations or warranties, expressed or implied, as to the accuracy or completeness of such information and shall have no liability for the consequences of use of such information.Right to make changes — NXP Semiconductors reserves the right to make changes to information published in this document, including withoutlimitation specifications and product descriptions, at any time and without notice. This document supersedes and replaces all information supplied prior to the publication hereof.Suitability for use — NXP Semiconductors products are not designed, authorized or warranted to be suitable for use in medical, military, aircraft, space or life support equipment, nor in applications where failure ormalfunction of an NXP Semiconductors product can reasonably be expected to result in personal injury, death or severe property or environmentaldamage. NXP Semiconductors accepts no liability for inclusion and/or use of NXP Semiconductors products in such equipment or applications and therefore such inclusion and/or use is at the customer’s own risk.Applications — Applications that are described herein for any of these products are for illustrative purposes only. NXP Semiconductors makes no representation or warranty that such applications will be suitable for the specified use without further testing or modification.Quick reference data — The Quick reference data is an extract of theproduct data given in the Limiting values and Characteristics sections of this document, and as such is not complete, exhaustive or legally binding. Limiting values — Stress above one or more limiting values (as defined in the Absolute Maximum Ratings System of IEC 60134) may cause permanent damage to the device. Limiting values are stress ratings only and operation of the device at these or any other conditions above those given in theCharacteristics sections of this document is not implied. Exposure to limiting values for extended periods may affect device reliability.Terms and conditions of sale — NXP Semiconductors products are sold subject to the general terms and conditions of commercial sale, as published at /profile/terms , including those pertaining to warranty, intellectual property rights infringement and limitation of liability, unlessexplicitly otherwise agreed to in writing by NXP Semiconductors. In case of any inconsistency or conflict between information in this document and such terms and conditions, the latter will prevail.No offer to sell or license — Nothing in this document may be interpreted or construed as an offer to sell products that is open for acceptance or the grant, conveyance or implication of any license under any copyrights, patents or other industrial or intellectual property rights.9.4TrademarksNotice: All referenced brands, product names, service names and trademarks are the property of their respective owners.10.Contact informationFor more information, please visit: For sales office addresses, please send an email to: salesaddresses@Document status [1][2]Product status [3]DefinitionObjective [short] data sheet Development This document contains data from the objective specification for product development.Preliminary [short] data sheet Qualification This document contains data from the preliminary specification.Product [short] data sheetProductionThis document contains the product specification.11.Contents1Product profile. . . . . . . . . . . . . . . . . . . . . . . . . . .11.1General description . . . . . . . . . . . . . . . . . . . . . .11.2Features and benefits. . . . . . . . . . . . . . . . . . . . .11.3Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . .11.4Quick reference data . . . . . . . . . . . . . . . . . . . . .12Pinning information. . . . . . . . . . . . . . . . . . . . . . .23Ordering information. . . . . . . . . . . . . . . . . . . . . .24Limiting values. . . . . . . . . . . . . . . . . . . . . . . . . . .35Thermal characteristics . . . . . . . . . . . . . . . . . . .46Characteristics. . . . . . . . . . . . . . . . . . . . . . . . . . .47Package outline. . . . . . . . . . . . . . . . . . . . . . . . . .68Revision history. . . . . . . . . . . . . . . . . . . . . . . . . .79Legal information. . . . . . . . . . . . . . . . . . . . . . . . .89.1Data sheet status . . . . . . . . . . . . . . . . . . . . . . . .89.2Definitions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . .89.3Disclaimers. . . . . . . . . . . . . . . . . . . . . . . . . . . . .89.4Trademarks. . . . . . . . . . . . . . . . . . . . . . . . . . . . .810Contact information. . . . . . . . . . . . . . . . . . . . . . .8Please be aware that important notices concerning this document and the product(s)described herein, have been included in section ‘Legal information’.© NXP B.V.2009.All rights reserved.For more information, please visit: For sales office addresses, please send an email to: salesaddresses@分销商库存信息: NXPBYV32E-200,127。

用户手册WBOX-4160/4360用户手册版本: A1.1版本信息版权声明该产品及相关文件为上海市福升威尔智能控制技术股份有限公司2019年版权发行，并保留所有版权。

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本文件以提供精准，可靠的信息为出发点。

但福升威尔对本手册的使用结果，或因本手册使用导致其他第三方权益受损，概不负责。

认可声明Award 为Award 公司的商标IBM, PC/AT, PS/2 and VGA为IBM公司的商标Intel, Skylake, Kabylake 为Intel公司的商标Microsoft Windows 和MS-DOS 为微软的商标RTL为瑞昱半导体有限公司的商标所有的产品名和商标的所有权为各自所属公司拥有。

了解更多产品信息或福升威尔其他产品，请访问福升威尔官网: 产品质保书(2年)产品保修有效期自出货之日算起，整机（如工控机，平板电脑）、板、卡保修两年，显示器保修一年，在保修期间相关配件享有免费材料和免费劳务的维修服务（限属于售后服务范围内的产品），过保修期的产品将进行收费维修，并针对更换的物品将质保三个月。

整机产品所配置的相关配件（如CPU、内存、硬盘、电源、）以及其它非整机产品，若在其正常使用过程中发生品质问题的，本公司提供产品出货日起一个月的免费更换期。

质保针对本公司销售的产品及配件，但除销售合同另有规定外，随机资料、光盘、软盘、赠送品、促销产品等不在质保范围内；对未经授权的维修人员维修过的产品，以及不正确使用、滥用、意外事故、不正确的安装等导致的其他问题，福升威尔有免责权利。

由于福升威尔产品均有严格的质量标准并且经过严格的测试，返修率很低，如果产品在质保期内有任何问题，均可提供免费的维修或更换服务。

如果您购买的的产品有故障，请按如下步骤操作：1.收集遇到的问题的信息（例如，CPU主频，使用的福升威尔产品型号，其他硬件或者软件等）。