XG962H parameters

FeaturesRegulated Converter• 4:1 wide input range• 3kVAC reinforced insulation for 110Vin 2.25kVDC basic insulation for 24Vin & 48Vin • Efficiency up to 93%• No minimum load required• EN50155, IEC/EN60950-1 & UL60950-1 certifiedDescriptionThe half-brick RP100H series DC/DC converters are designed for railway rolling stock and high voltage battery applications. Each series has three 4:1 input voltage range options to cover all input voltages from 9VDC up to 160VDC with isolated and regulated 5V to 48VDC outputs. The converters have high efficiencies and metal base-RP100H-RW DC/DC Converter100 Watt Half BrickEN50155 certifiedIEC/EN60950-1 certified UL60950-1 certifiedE196683RP100H-2415SRW 9-36 15 6700 4601 100 91 4460RP100H-2424SRW 9-36 24 4200 4666 101 90 1750RP100H-2448SRW 9-36 48 2100 4666 101 90 430RP100H-4805SRW 16.5-75 5 20000 2240 100 93 40000RP100H-4812SRW 16.5-75 12 8400 2333 101 90 7000RP100H-4815SRW 16.5-75 15 6700 2300 100 91 4460RP100H-4824SRW 16.5-75 24 4200 2333 101 90 1750RP100H-4848SRW 16.5-75 48 2100 2307 101 90 430RP100H-11005SRW 43-160 5 20000 1010 100 93 40000RP100H-11012SRW 43-160 12 8400 1018 101 90 7000RP100H-11015SRW 43-160 15 6700 1015 100 91 4460RP100H-11024SRW 43-160 24 4200 1018 101 90 1750RP100H-11048SRW 43-160 48 2100 1007 101 90 430Ordering ExamplesRP100H-2405SRW/N = 24V Input, 5V Output, Single, Neg. CTRL function RP100H-11012SRW/P = 110V Input, 12V Output, Single, Pos. CTRL functionRP100H-2405SRW/N-HC = 24V Input, 5V Output, Single, Neg. CTRL function, premounted Heat-sinkModel NumberingInput Voltage Output VoltageS ingleRP100H-__ __SRW/_ _Notes:Note2: standard part is with suffix “P” for positive logic (1=ON, 0=OFF) or add suffix “N” instead for negative logic (0=ON, 1=OFF) Note3: add suffix “-HC” for premounted Heat-sink CTRL Logic (2)Package (3)Notes:Note1:Efficiency is tested by nominal Vin, full load and at 25°Chttps:///pdf/Powerline_DC-DC/RSPxxx-168.pdf/eval-ref-boardsSpecifications (measured @Ta = 25°C, resistive load, nominal Vin and rated Iout unless otherwise noted)Specifications (measured @Ta = 25°C, resistive load, nominal Vin and rated Iout unless otherwise noted)RP100H-4805SRW708090100Efficiency vs. Output CurrentPower up Start-up CharacteristicON/OFF Control Start-up Rise CharacteristicSpecifications (measured @Ta = 25°C, resistive load, nominal Vin and rated Iout unless otherwise noted)Efficiency vs. Input Voltage60708090100708010090RP100H-11005SRWEfficiency vs. Output CurrentPower up Start-up CharacteristicSpecifications (measured @Ta = 25°C, resistive load, nominal Vin and rated Iout unless otherwise noted)OUTPUT TRIM Typical Output Ripple and NoisePower up Start-up CharacteristicOutput Voltage TrimmingRP100H-RW converters offer the feature of trimming the output voltage over a certain range around the nominal value by using external trim resistors. The values for trim resistors shown in trim tables below are according to standard E96 values; therefore, the specified voltage may slightly vary; they also can be calculated with below shown equation.TRIM DOWNTRIM UPTRIM-Sense+SenseSpecifications (measured @Ta = 25°C, resistive load, nominal Vin and rated Iout unless otherwise noted)OUTPUT TRIMRP100H-xx05SRWRP100H-xx12SRWRP100H-xx15SRWRP100H-xx24SRWRP100H-xx48SRWTrim Down all Vout‘sTrim up 12345678910%Vout = 5.05 5.10 5.15 5.20 5.25 5.30 5.35 5.4 5.45 5.50Volts R 1 = 30915810578.763.453.646.440.236.533.2kOhms Trim up 12345678910%Vout =12.1212.2412.3612.4812.6012.7212.8412.9613.0813.20Volts R 1 = 88745330122618215413311810595.3kOhms Trim up 12345678910%Vout =15.1515.3015.4515.6015.7515.9016.0516.2016.3516.50Volts R 1 = 1130576383294237196169150137124kOhms Trim up 12345678910%Vout =24.2424.4824.7224.9625.2025.4425.6825.9226.1626.40Volts R U = 1870953634487392324280249226205kOhms Trim up 12345678910%Vout =48.4848.9649.4449.9250.4050.8851.3651.8452.3252.80Volts R 1 = 3830196013001000806681576511464422kOhms Trim down 12345678910%R 2 = 97.647.531.623.217.814.712.110.59.098.06kOhms Trim down 11121314151617181920%R 2 =7.156.345.765.114.644.223.923.573.243.01kOhmsTrim CalculationVout = Output VoltageR 1 =100*Vout+D Vout * Vout)- (100+2D Vout) k Ω D Vout = Output Voltage Trim in %1.225*D Vout D VoutR1 =trim up resistorR2 = trim down resistor R 2 = 100 - 2 k ΩD Vout Practical Example:Trim Up:Vout = 5V, D Vout = 10% (5.5V)R 1 =100*Vout+D Vout * Vout) - (100+2D Vout) k Ω = 100*5 +10*5 - 100+2*10= 44.89 - 12 = 32.9k Ω 1.225*D Vout D Vout 1.225*10 10Trim down:Vout = 5V, D Vout = -10% (4.5V)R 2 = 100 - 2 k Ω = 100 - 2 = 8.06k ΩD Vout 10Specifications (measured @Ta = 25°C, resistive load, nominal Vin and rated Iout unless otherwise noted)REGULATIONSParameter Condition ValueOutput Accuracy±1.0%Line Regulation low line to high line at full load±0.1% Load Regulation0% to 100% load0.1% Transient Response25% load step change200µs typ.; 250µs max.Transient Response to Dynamic Load Change from 100% to 75% to 100% of Full Load at nom.VinRP100H-4805SRWRP100H-2405SRWRP100H-11005SRWSpecifications (measured @Ta = 25°C, resistive load, nominal Vin and rated Iout unless otherwise noted)ENVIRONMENTALParameterCondition ValueOperating Case Temperature Range refer to derating graphMaximum Case Temperature 105°CTemperature Coefficient ±0.02%/°C max.Thermal Impedance vertical direction by natural convection (0.1m/s) without Heat-sink vertical direction by natural convection (0.1m/s) with Heat-sink6.7°C/W 4.7°C/W Operating Humidity 5% - 95% RHPollution Degree PD2Shock according to EN61373 standard Thermal Shock according to MIL-STD-810F standardVibrationaccording to EN61373 standardFire protection on railway vehicles according to EN45545-2, 2013 standardMTBFaccording to MIL-HDBK-217F standard, 25°C408.7 x 103 hoursPROTECTIONSParameterConditionValueShort Circuit Protection (SCP)below 100m Ωcontinuous, automatic recovery Over Voltage Protection (OVP)% of nom. Vout115%-130%, Hiccup Mode Over Load Protection (OLP)% Iout rated24Vin, 48Vin 110Vin120%-150%, Hiccup Mode 150% typ., Hiccup ModeOver Temperature Protection (OTP)+110°C to +120°C Isolation Voltage110VinI/P to O/P I/P or O/P to Case 3kVAC/1minute 1.5kVAC/1minute 24Vin, 48VinI/P to O/P I/P or O/P to Case2.25kVDC/1minute 1.6kVDC/1minuteIsolation Resistance 500 VDC1G Ω min.Isolation Capacitance 2500pF max.Isolation Grade110 Vin 24Vin, 48Vin reinforced insulationbasic insulationThermal CalculationNotes:Note4: Refer to local wiring regulations if input over-current protection is also required. Recommended fuse: T35A slow blow.R thcase-ambient = 6.7°C/W (vertical) T case = Case Temperature R thcase-ambientHC = 4.7°C/W (vertical) T ambient = Environment Temperature P dissipation = Internal lossesR thcase-ambient = T case - T ambientP IN = Input PowerP dissipationP OUT = Output Power h = Efficiency under given Operating ConditionsP dissipation = P IN - P OUT = P OUTapp- P OUTapp R thcase-ambient = Thermal Impedance h Practical Example:Take the RP100H-2405SRW with 9V input Voltage and 50% load. What is the maximum ambient operating temperature? Use converter vertical in application without airflow.Eff min = 91% @ V nomP OUT = 100W P OUTapp = 100 x 0.5 = 50W h = 91% (Efficiency vs. Load Graph)without Heat-sink with Heat-sinkR th = T casemax - T amb --> 6.7°C/W = 105-T amb R thHC = T casemax - T amb--> 4.7°C/W = 105-T amb P dissipation 4.95W P dissipation4.95W T amb = 72°C T ambHC = 82°CSpecifications (measured @Ta = 25°C, resistive load, nominal Vin and rated Iout unless otherwise noted)Specifications (measured @Ta = 25°C, resistive load, nominal Vin and rated Iout unless otherwise noted)DC/DC ConverterSpecifications (measured @Ta = 25°C, resistive load, nominal Vin and rated Iout unless otherwise noted)RP100H-RWSeriesConducted Emission EN55022 Class AConducted Emission EN55022 Class AC4C5C6C7C8Shield PlaneL1C18+V INEMI Filtering according to EN55022/11 Class A and EN50121-1 (110Vin)DC/DC ConverterSpecifications (measured @Ta = 25°C, resistive load, nominal Vin and rated Iout unless otherwise noted)RP100H-RWSeriescontinued on next pageEMI Filtering according to EN55022/11 Class B (24Vin and 48Vin)Shield Plane100-110xxSRW, Class BNNC6C9C8C3C4CaseL2C7C19C20Shield PlaneC12C13C14C10C11C16C2C4L1L2C5C8C6C7C11C3Conducted Emission EN55022 Class ADC/DC ConverterSpecifications (measured @Ta = 25°C, resistive load, nominal Vin and rated Iout unless otherwise noted)RP100H-RWSeriesEMI Filtering according to EN55022/11 Class B (110Vin)C8Shield PlaneShield PlaneC9C1C2C3C11C12C10CaseL1C4C5C8C13C14C17C9C19C3C4L1L2C12C10C11C15C15Shield PlaneC9C10C12Conducted Emission EN55022 Class BSpecifications (measured @Ta = 25°C, resistive load, nominal Vin and rated Iout unless otherwise noted)Specifications (measured @Ta = 25°C, resistive load, nominal Vin and rated Iout unless otherwise noted)The product information and specifications may be subject to changes even without prior written notice.The product has been designed for various applications; its suitability lies in the responsibility of each customer. The products are not authorized for use in safety-critical applications without RECOM’s explicit written consent. A safety-critical application is an application where a failure may reasonably be expected to endanger or cause loss of life, inflict bodily harm or damage property. The applicant shall indemnify and hold harmless RECOM, its affiliated companies and its representatives against any damage claims in connection with the unauthorizeduse of RECOM products in such safety-critical applications.PACKAGING INFORMATIONParameterTypeValuePackaging Dimension traywithout Heat-sink with Heat-sink157.0 x 88.0 x 12.8mm 157.0 x 88.0 x 24.8mmPackaging Quantity 2pcs.Storage Temperature Range -55°C to +125°C Storage Humidity5% - 95% RH。

© 1996 IXYS All rights reservedSymbol Test Conditions Maximum RatingsV CES T J = 25°C to 150°C1000V V CGR T J = 25°C to 150°C; R GE = 1 M Ω1000V V GES Continuous ±20V V GEM Transient ±30V I C25T C = 25°C 50A I C90T C = 90°C 25A I CMT C = 25°C, 1 ms100A SSOA V GE = 15 V, T VJ = 125°C, R G = 33 Ω I CM = 50A (RBSOA)Clamped inductive load, L = 100 µH @ 0.8 V CESP C T C = 25°C200W T J -55 ... +150°C T JM 150°C T stg -55 ... +150°CM d Mounting torque (M3) 1.13/10Nm/lb.in.WeightTO-204 = 18 g, TO-247 = 6 gMaximum lead temperature for soldering 300°C1.6 mm (0.062 in.) from case for 10 sSymbol Test ConditionsCharacteristic Values(T J = 25°C, unless otherwise specified)min.typ.max.BV CES I C = 3 mA, VGE = 0 V 1000V V GE(th)I C= 250 µA, V CE = V GE2.55V I CES V CE = 0.8 • V CES T J = 25°C 250µA V GE = 0 VT J = 125°C1mA I GES V CE = 0 V, V GE = ±20 V ±100nA V CE(sat)I C= I C90, V GE = 15 V25N100 3.5V 25N100A4.0VTO-247 AD (IXGH)GCETO-204 AE (IXGM)CG = Gate, C = Collector,E = Emitter,TAB = CollectorV CESI C25V CE(sat)Low V CE(sat)IXGH/IXGM 25 N1001000 V 50 A 3.5 V High speed IGBTIXGH/IXGM 25 N100A 1000 V50 A4.0 VFeaturesl International standard packages l 2nd generation HDMOS TM process l Low V CE(sat)-for low on-state conduction losses l High current handling capability l MOS Gate turn-on -drive simplicitylVoltage rating guaranteed at high temperature (125°C)Applicationsl AC motor speed control l DC servo and robot drives l DC choppersl Uninterruptible power supplies (UPS)lSwitch-mode and resonant-mode power suppliesAdvantageslEasy to mount with 1 screw (TO-247)(isolated mounting screw hole)lHigh power density91516E (3/96)查询IXGH25N100供应商IXYS MOSFETS and IGBTs are covered by one or more of the following U.S. patents:4,835,5924,881,1065,017,5085,049,9615,187,1175,486,7154,850,0724,931,8445,034,7965,063,3075,237,4815,381,025IXYS reserves the right to change limits, test conditions, and dimensions.SymbolTest ConditionsCharacteristic Values(TJ = 25°C, unless otherwise specified)min.typ.max.g fs I C = I C90; V CE = 10 V,815S Pulse test, t ≤ 300 µs, duty cycle ≤ 2 %C ies 2750pF C oes V CE = 25 V, V GE = 0 V, f = 1 MHz200pF C res 50pF Q g 130180nC Q ge I C = I C90, V GE = 15 V, V CE = 0.5 V CES2560nC Q gc 5590nC t d(on)100ns t ri 200ns t d(off)500ns t fi 25N100A500ns E off 25N100A 5mJ t d(on)100ns t ri 250ns E on 3.5mJ t d(off)7201000ns t fi 25N1009503000ns 25N100A 8001500ns E off 25N10010mJ 25N100A8mJ R thJC 0.62K/WR thCK0.25K/WInductive load, T J = 25°CI C = I C90, V GE = 15 V, L = 300 µH,V CE = 0.8 V CES , R G = R off = 33 ΩRemarks: Switching times may increasefor V CE (Clamp) > 0.8 • V CES ,higher T J or increased R G Inductive load, T J = 125°C I C = I C90, V GE = 15 V, L = 300 µH V CE = 0.8 V CES , R G = R off = 33 ΩRemarks: Switching timesmay increasefor V CE (Clamp) > 0.8 • V CES ,higher T J or increased R GFig. 1Saturation CharacteristicsFig.7Gate ChargeIXYS MOSFETS and IGBTs are covered by one or more of the following U.S. patents:4,835,5924,881,1065,017,5085,049,9615,187,1175,486,7154,850,0724,931,8445,034,7965,063,3075,237,4815,381,025。

Basic GTS Enterprise Device Communication Server Xirgo TechnologiesXT-2000-G-X001Copyright © 2007-2011 GeoTelematic Solutions, Inc.All rights reserved*************************Device Communication Server – XirgoContents:1 Introduction2 Configuring the Server2.1 Changing the Server "Listen" Ports2.2 Setting the "Unique-ID" Prefix Characters2.3 Setting the Xirgo Properties2.4 Changing the Default Alarm Code to StatusCode Mapping3 Running the Server3.1 Manually Starting the Server3.2 Automatically Starting the Server on System Reboot3.3 Monitoring the Log File4 Adding Devices to an Account4.1 Creating a New Device Record4.2 The "Server ID" Field.5 Testing a New Configured Device5.1 Monitoring the Log Files5.2 Viewing the Unassigned Devices ReportAppendix:A) Troubleshooting Device Connection Issues1) IntroductionThis manual describes how to configure and run the GTS Enterprise device communication server (DCS) for the Xirgo Technologies hardware GPS tracking/telematic devices. This server supports the following devices:–XT-2000-G-X001The following features are supported for the Xirgo DCS:–Receive incoming data packets via UDP/TCP.–Estimated GPS-based Odometer.–Simulated Geozone Arrival/Departure.2) Configuring the ServerThe following section refers to the runtime configuration file for the Xirgo device communication server, which can be found in the GTS Installation directory at "dcservers/dcserver_xirgo.xml".2.1) Changing the Server "Listen" Ports.The ports on which the Xirgo DCS listens for incoming data packets is specified on the "ListenPorts" tag:<ListenPortstcpPort="37690"udpPort="37690"/>If required, the "listen" port can be changed to fit the requirements of your runtime environment. The script programmed into the Xirgo device will also need to be configured to transmit data to the same port as the server used to listen for incoming data packets.The "listen" ports must be open through the firewall in order for the remote device to send data to the Xirgo server.If packet acknowledgment is required, any acknowledgments sent by the server back to the remote device must be sent from the same IP address to which the remote device sent it's data packet. If your server responds to more than one IP address, then the Xirgo server listener must be bound to the same IP address/interface used by the remote tracking devices. This is set in the top-level "dcservers.xml" file, on the "DCServerConfig" tag, "bindAddress" attribute.2.2) Setting the "Unique-ID" Prefix Characters.The Unique-ID prefix characters can be set in the "UniqueIDPrefix" tag section:<UniqueIDPrefix><![CDATA[xg_xirgo_imei_*]]></UniqueIDPrefix>These prefix characters are used to 'prepend' to the IMEI number, or other custom ID, as reported by the device to look-up the owning Account/Device record for this device. For instance, if the Xirgo ID number is "123456789012345", then the system will search for the owning Device using the following Unique-ID keys, in the order specified:xg_123456789012345xirgo_123456789012345imei_123456789012345123456789012345Note that the '*' character by itself indicates that the system should look up the Xirgo ID number without any prefixing characters.To bind a Xirgo device to a specified Account/Device record, set the "Unique ID:" field on the Device Admin page to the appropriate prefixed unique-id value. For example:Unique ID: xirgo_1234567890123452.3) Setting the Xirgo PropertiesProperties which effect the behavior of the server are set in the "Properties" tag section. The following properties may be set:<Property key="minimumSpeedKPH">3.0</Property>This is the minimum acceptable speed value, below which the device will considered not moving, and the speed will be explicityly set to "0.0".<Property key="statusLocationInMotion">true</Property>If "true", the DCS will replace an event which otherwise is defined to be a general STATUS_LOCATION status code instead with a STATUS_MOTION_IN_MOTION status code, if the indicated speed of the vehicle is greater than zero.<Property key="minimumMovedMeters">0</Property>If the specified value is greater than '0', then subsequent received events will be omitted if they are within the specified number of meters to the previous event. Useful for eliminating multiple events at the same location, when the device continues to periodically report a location even if the device is stopped.<Property key="estimateOdometer">true</Property>If "true", the DCS will calculate the current event odometer based on the distance traveled since the last valid GPS location.<Property key="simulateGeozones">true</Property>If "true", the DCS will check for geozone arrivals/departures and insert the appropriate arrive/depart events.2.4) Changing the Default Alarm Code to StatusCode Mapping.The Alarm Code to StatusCode mapping is specified in the "EventCodeMap" and "Code" tag sections:<EventCodeMap enabled="true"><!-- default generated status codes --><Code key="4001">0xF020</Code> <!-- STATUS_LOCATION --></EventCodeMap>The "key" attribute represents the default status code generated by the Xirgo server for the indicated Alarm Code. The hex value indicated within the commented section following the "Code" definition is the value of the actual received Alarm Code.The text value of the "Code" tag should be the status-code to which the Alarm Code should be mapped. The special value "ignore" can be used to cause events which specify this Alarm Code to be ignored. The special value "default" indicates that the status code on the generated event will be STATUS_LOCATION if the vehicle is not moving, and STATUS_MOTION_IN_MOTION if the vehicle is moving. The numeric values, specified as either decimal or hexidecimal will be used as the status code on the generated event.If an event arrives with a Alarm Code which is not specified in the "EventCodeMap" tag section, then it will be used unchanged as the status-code for the generated event.Refer to the "Status Codes and Description" documentation for a list of currently defined status codes.3) Running the ServerTo begin listening for incoming events the server must be started. This section describes the process for manually starting the Xirgo server, and how to set up the system to have is automatically start the Xirgo server on system reboot.3.1) Manually Starting the ServerThe command for manually starting the Xirgo server is as follows:> cd $GTS_HOME> bin/runserver.pl -s xirgoTo start the Xirgo server with debug logging (useful when testing or debugging), the option "-debug" may be added to the command line.The server will start, and logging information will be sent to the file "$GTS_HOME/logs/xirgo.log".For debug purposes, it is sometimes useful to have the logging output sent directly to the console, instead of the log file. In this case the option "-i" can also be added to the command-line. When logging to the console, hit control-C to stop the server.To view the running server, you can use the "bin/psjava" command:> $GTS_HOME/bin/psjavaPID Parent L User Java class/jar------ ------ - -------- --------------------------------------------------54639( 1) 1 opengts org.apache.catalina.startup.Bootstrap68936( 1) 1 opengts /usr/local/GTS_2.2.4-B23/build/lib/xirgo.jarTo stop the running Xirgo server, enter the following command:> cd $GTS_HOME> bin/runserver.pl -s xirgo -killThis will stop the running Xirgo server.3.2) Automatically Starting the Server on System RebootThe auto-start script for Fedora is located at "$GTS_HOME/bin/onboot/fedora/opengts", and should have been installed into the system directory "/etc/init.d" when the GTS was installed.This startup script uses the configuration specified in the file "$GTS_HOME/bin/serverList" to determine which device communication servers to start up when the system is rebooted. The line in this file that refers to the Xirgo DCS should appear similar to the following:execServer "Xirgo" "xirgo" "${option}" ""The first quoted string contains the DCS description. The second quoted string contains the ID of the device communication server and must match a library jar file with the same name at"$GTS_HOME/build/lib/xirgo.jar". The third quoted string must contain the exact value "${option}", which is used within the startup script to pass command-line arguments to the DCS startup code. The forth quoted string is used to pass other optional default or constant arguments to the DCS startup code.3.3) Monitoring the Log FilesWhen started, the Xirgo DCS will create the following output log files:$GTS_HOME/logs/xirgo.pidThis file contains the process-id (PID) of the Xirgo DCS execution process. This PID is used by the "-kill" option to terminate the running Xirgo DCS.$GTS_HOME/logs/xirgo.logThis log file is where all other logging information is placed regarding the receipt and parsing of data from the remote Xirgo tracking devices. As this file grows, it will be "rotated" into other log files timestamped as follows:xirgo.log.YYYYMMDDHHMMSS.logWhere "YYYYMMDDHHMMSS" represents the Year/Month/Day/Hour/Minutes/Seconds time that the file was trimmed and rotated.The "xirgo.log" file will reflect any current connection attempts from remote Xirgo tracking devices. As devices send their data to the server, the receipt of the incoming data packets, along with parsing results, will be displayed in this log file.4) Adding Devices to an AccountWhen data is received from a remote Xirgo tracking device, the Xirgo server looks up the IMEI number in the Device table to determine which Account/Device owns this device. This section describes how to create a Device record and associate an Xirgo tracking device with the Device record.4.1) Creating a New Device RecordUsing the web-interface, log in to the appropriate Account which should own the Xirgo tracking device, then traverse to the "Device Admin" page (or "Vehicle Admin", etc, if so named). Create a new Device as indicated in the GTS Enterprise Tutorial documentation, then "Edit" the newly created Device record.On the Edit page, there will be a field described as follows:Unique ID: [ ]In this field enter the value "xirgo_<IMEI_Number>", replacing "<IMEI_Number>" with the device IMEI number. For instance, if the IMEI number is "123456789012345", then enter the value "xirgo_123456789012345" in this "Unique ID:" field.After making changes to the Device record, click the "Change" button.4.2) The "Server ID" FieldThe "Server ID" field displayed as a column title on the Device list page, and as a read-only field on the Device Edit page, is assigned a value when the Xirgo device sends its first data packet to the server. Until then, this value will remain blank.When viewing a list of created Device records with assigned Xirgo devices, records which still have blank "Server ID" fields indicate that no incoming data packet has been received for this particular Device.5) Testing a New Configured DeviceThis section describes the process for monitoring newly configured Xirgo devices that have been assigned to an Account/Device record.5.1) Monitoring for Incoming ConnectionsThe Account report "Last Known Device Location" can be used to display the last know location of a given device, which can also be used to determine whether any events have been received from a specific Xirgo device.The "Server ID" field on the Device record will also indicate if a data packet has arrived from a specific Xirgo device and successfully assigned to the Device record.If no indication on the Device reports, or "Server ID" field is evident, then the log file itself can be consulted for indications of incoming data packets from the Xirgo device. The information in the log file can indicate whether an IMEI number may not have been properly assigned, so the Xirgo DCS is unable to determine whichAccount/Device the incoming data packet belongs to.5.2) Viewing the Unassigned Device ReportIn the case where an Xirgo device is put into service without having been assigned to an Account/Device record, or where the IMEI number was incorrectly entered in to the Device record, the Xirgo DCS may not know to which Account/Device the incoming data packet belongs.When the Xirgo DCS cannot determine the ownership of an incoming data packet, it will place the IMEI and currently GPS location into the "UnassignedDevices" table. The "Unassigned Devices" report can be selected from the System Administrator login panel ("System Admin" tab, "SysAdmin Reports" menu option, "Unassigned Devices" report). This report will show the "Server ID" (Xirgo), "Unique ID" (IMEI number), and the last time data was received from this device. This information can be used to determine whether an IMEI number was ever assigned to an Account/Device record, or if an IMEI number was incorrection assigned to an Account/Device (ie. transposed digits, etc).Appendix)A) Troubleshooting Device Connection IssuesThe following are fequently-asked-questions regarding commonly occurring connection issues.Q: I've configured an Xirgo device to send data to the server, but have not received any data.A: Monitor the "xirgo.log" file for possible incoming connections from the device. If there is no indication that the server is receiving any communication from the remote device, the most common reasons to check include:• Make sure device has a valid/active SIM card.• Make sure the device has been programmed with the proper APN ("Access Point Name") configuration as specified by your wireless service provider.• Make sure the device has been programmed with the proper host and port of your server.• Make sure the server firewall allows incoming UDP/TCP connections on the specified port. If the server itself provides its own firewall, then check the firewall settings. On Linux, this is usually controlled by "iptables".The command to display the current iptables configuration is "iptables-save" (must be run as "root").See "/docs/iptables/iptables-save.html" for more information.Q: I see data arriving for my device in the "xirgo.log" file, but it is always the same event that is being sent over and over.A: If this occurs for all configured/connected Xirgo devices, the problem is likely that returned UDP acknowledgments are not being returned properly to the device. The most likely reason for this is that your computer responds to more than one IP address, and the returned UDP packets are being sent from a different IP address than the one that the device is configured to send data to. This can be fixed by setting the "bindAddress" attribute in the "dcservers.xml" file in the GTS installation directory (then restart the Xirgo DCS). In some cases, the SIM card wireless service provider does not allow returned UDP packets to be sent from the server back to a device. In this case, it may be necessary to program the Xirgo devices to not require a return acknowledgment.A: If this occurs for only one device (ie. other devices are reporting as expected), this this is likely due to the GPS receiver's inability to obtain a new GPS fix, and the previous GPS fix is being resent. This usually means that the device is simply in an area where the GPS satellites cannot be seen (ie. Indoors, etc). On rare occasions, this can mean that the GPS antenna has become unplugged, or has been damaged.Q: The received events have a valid latitude/longitude, but do not have an odometer value.A: The Xirgo DCS property "estimateOdometer" allows enabling a calculated odometer value, based on the distance traveled between successive GPS points. To enable a calculated estimated odometer value, make sure this property is set to "true".。

CONTROL RELAYSCrouzet offers several variations of Syrelec control relays.Five models for liquid level controls, 3 phase 230V, 380V, 440V and 480V for phase loss or reversal protection, current and voltage detection and control, motion detection, and alternating relays are also available.If a standard control requires modification or a special product is needed to meet your exact needs, please call us or the Crouzet Sales Representative nearest you.Crouzet has controls to meet your CE, UL, and CSA requirements.SERIES FUNCTIONFEATURES SERIES F U N C T I O N FEATURES NNR SeriesLiquid LevelControlPC Board liquid levelcontrol.Pumpup/Pump down.4.7 to47K ohm sensitivity.SPDT 10A output relay3.62˝ x 2.16˝Liquid LevelControlNR SeriesLLC PumpDownNRU SeriesLLC Pump UpPlug-in or Din-Railmount.4.7 to 100Kohm sensitivity.1.89˝H x 1.89˝W x3.9˝LLiquid LevelControl PumpDownLiquid LevelControl PumpUpEN SeriesEND SeriesLiquid LevelControlLiquid LevelControlDin-Rail/surface mount.Pump up/Pump down.5K to 100K ohm sensi-tivity.80mmH x22.5mmW x 100mmLIR.T SeriesCurrentControl RelayMonitorsCurrent withRelay OutputPlug-in or Din-Railmount.Adjustableinhibit time for start up.LED Relay output indi-cator.3mAmp to7Amps-AC, 5mA to10Amps DC.1.89˝H x1.89˝W x 3.9˝LEIL EIH EITSeriesCurrentControl RelayMonitorsCurrent withRelay OutputDin-Rail/surfacemount.Adjustable timeinhibits.2mAmp to10Amps AC/DC.forEIL/EIH .01 to100Amps for EITw/transformer.80mmHx 22.5mmW x 100mmLUR SeriesVoltageControl RelayMonitorsVoltage withRelay OutputPlug-in or Din-Railmount .1 to 400 VoltsAC/DC.With latchingfunction selectable.LED output indication.1.89˝H x 1.89˝W x3.9˝LCTD/CTHSeriesT emperatureControllersP, PI, PIDOn/OffAuto TuningHeat/CoolSingle and dual displaymodels.Thermocoupleand RTD inputs.Auto-tuning for PID mod.Soft start function.WRL SeriesPhaseMonitorPhase ControlRelayMonitors:- PhaseSequence- Loss of Phase- Under VoltagePlug-in or Din-Railmount.3 x 230 VAC, 3x 380 VAC, 3 x 480VAC, 1.89˝H x 1.89˝Wx 3.9˝LHDU SeriesVoltageControl RelayMonitorsVoltage.With RelayOutput.With LCDDisplay..2 to 600 Volt AC/DC v o l t-age monitoring ra n g e.O v er and under v o l t a g ef u n c t i o n s.With LCD dis-p l a y.S h o ws actual ands e t p o i n t s.Din-Rail mount.81mmH x 36mmW x81m m LFW SeriesPhaseMonitorMonitors:- Phase Loss- PhaseReversal- UndervoltageDin-Rail or surface mount.3 x 230 VAC, 3 x 380VAC, 3 x 480 VAC, 3 x600 VAC.45mm widee n c l o s u r e.A d j u s t a b le timei n h i b i t.LED power on andr e l a y status.79mmH x45mmW x 100mmLEUL,EUHSeriesVoltageControl RelayMonitorsVoltage withRelay OutputD i n-R a i l/s u r f ace mount.A d j u s t a b le time inhibit..2 to 600 Volts AC/D C.S e l e c t a b le latching fe a-t u r e.80mmH x22.5mmW x 100mmLJR SeriesAlternatingRelayDuplexAlternatingRelayPlug-in style.Designedfor dual pump system.Selector switch ver-sions available.1.89˝Hx 1.89˝W x 3.9˝LMCI SeriesCurrentControl RelayMonitorsCurrent.WithRelay Output.With Built-inTr ansformer1 to 20Amp AC/DC cur-rent monitoring ra n g e.Built-in tra n s f o r m e r.R e l a youtput-SPDT Over andunder current functions.81mmH x 17.5mmW x83m m LF3I SeriesMotorProtectionRelayMotorProtection forPhase LossPhaseUnbalanceCurrent Surge8 to 630Amp currentra n g e.LED diagnostics.A d j u s t a b le trip timers.Phase loss test s w i t c h.Front panel reset.79m m Hx 45mmW x 95mmLFWIT SeriesMotorProtectionRelayMotor Protectionfor Phase LossPhase UnbalancePhase Rev e r s a lCurrent SurgeO v e r h e a t i n g7 to 630Amp currentrange.LED diagnos-tics.Adjustable triptimers Phase loss testswitch.Front panelreset.80mmH x78mmW x 99mmLHDI SeriesCurrentControl RelayMonitorsCurrent.WithRelay Output.With LCDDisplay.2mA to 10Amp;AC/D Ccurrent monitoring r a n g e.O v er and under currentf u n c t i o n s.With LCD dis-p l a y.S h o ws actualand setpoints.D i n-R a i lm o u n t.81mmH x36mmW x 66mmL83311CONTROLS&SENSORS Toll Free 1-800-526-5376Fax 201-337-1862201-337-1000Control Relays845Toll Free 1-800-526-5376Fax 201-337-1862201-337-1000Protective Relays & Alternating RelaysAdjustableProduct Number Product Number Operating Voltage UndervoltagePlug-inCase Socket Surface-Mount 50/60 Hz Drop-out Range(8 pin octal socket)Case*208/240V 180-230VPMP24070169-D PMD240480V 360-460V PMP480**70175PMD480PHASE MONITOR RELAYSProvides microprocessor-based protection for 3 phase systems against phase loss, phase rever-sal, phase unbalance, and under voltage.These devices are designed to be compatible with most Wye or Delta systems.In Wye systems, a connection to a neutral is not required.Phase Monitoring Relays protect against unbalanced voltages or single phasing regardless of any regenerative voltages.The relay is energized when the phase sequence and all voltages are correct.Any one of four fault conditions will de-energize the relay.Re-energization is automatic upon correction of the fault condition.An LED indicates normal and tripped conditions.The per-cent phase unbalance is adjustable from 2-10%, and the undervoltage drop-out can be set at 75-95% of operating voltage.The adjustable time delay dropout on undervoltage (0.1-20 sec-onds) eliminates nuisance tripping caused by momentary voltage fluctuations.Output :10A SPDT (PMP) or DPDT (PMD) @ 240VAC/30VDC.Dimensions :PMP-1.7”x 2.4”x 3.5”.PMD-1.8”x 2.75”x 4.4”.PMP Plug-in PMD Surface-Mount File LR45565File LR45565File E109461Provides protection to equipment where an over or under voltage condition is potentially damaging.They monitor either AC single phase (50-400hz) or DC (independent of polarity) voltages.No supply (input) voltage is required.The pick-up voltage setting is user-adjustable from 85-115% of the nominal voltage rating.The drop-out voltage setting is fixed at 3% below the pick-up voltage setting.The relay energizes when the monitored voltage is above the pick-up setting.The relay de-energizes when the monitored voltage is below the drop-out setting.The time delay on drop-out is fixed at 50ms.Output :10A DPDT @ 240VAC/30VDC.Dimensions :1.7”x 2.4”x 2.9”.ALTERNATING R ELAYSUsed in special applications where the optimization of load usage is required by equalizing the run time of two loads.They are also used where additional capacity is required in case of excess load requirements.This alternating action is initiated by a control switch, such as a float switch, manual switch, timing relay, pressure switch, or other isolated contact.Each time the initiating switch is opened, the output relay contacts will change state, thus alternating the two loads.Tw o LED indicators show the status of the output relay.As listed, these units come with a three position selector switch.This allows the unit to alternate the two loads as normal, or lock the relay to one load or the other.By locking the Alternating Relay to one load, the other load can be removed for service without rewiring the first load for continuous operation.The selector switch has a low profile to prevent any accidental changes in status.Output :10A SPDT or DPDT Cross-Wired @ 240VAC/30VDC.Dimensions :1.7”x2.4”x 2.9”.Product NumberControlSPDT DPDT Cross-Voltage Contacts Wired Contacts Socket File E109461SPDT DPDT Cross-WiredNominalPick-up Drop-Out Product VoltageVoltage Range Voltage Range Number Socket 24V AC21-27V AC 20-26V AC VMP024A 120V AC102-138V AC 99-134V AC VMP120A 240V AC204-276V AC 198-267V AC VMP240A 12V DC10-14V DC 9-13V DC VMPO12D 24V DC 21-27V DC 20-26V DC VMP024D 8 PIN OCTAL 70169-D File E109461File LR45565**Requires 600V-rated socket* No socket required for PMD240 or PMD4801 1C O N T R O L S &S E N S OR S。

g-sensor电气参数
G-sensor（重力感应器）是一种用于测量物体加速度的传感器，通常用于智能手机、平板电脑和其他便携式设备中。

它可以检测设
备的倾斜和动作，以便自动调整屏幕方向或触发特定的动作。

在电
气参数方面，G-sensor通常具有以下几个重要的参数：
1. 灵敏度，G-sensor的灵敏度是指其对加速度变化的响应程度。

通常以mV/g（毫伏/重力加速度）或mV/m/s^2（毫伏/米每秒平方）为单位。

这个参数决定了G-sensor的测量范围和精度。

2. 频率响应，G-sensor的频率响应指其对不同频率下加速度
变化的测量能力。

它通常以Hz为单位，决定了G-sensor在不同频
率下的测量精度和稳定性。

3. 额定电压，G-sensor的额定电压是指其正常工作所需的电
压范围，通常以V（伏特）为单位。

这个参数对于G-sensor的稳定
性和可靠性至关重要。

4. 工作温度范围，G-sensor的工作温度范围指其可以正常工
作的温度范围。

这个参数对于不同应用场景下的G-sensor选择至关
重要，通常以摄氏度或华氏度表示。

5. 输出类型，G-sensor的输出类型通常有模拟输出和数字输出两种，模拟输出需要外部ADC（模数转换器）进行数字化处理，而数字输出则可以直接连接到微处理器或数字信号处理器。

以上是G-sensor常见的电气参数，这些参数决定了G-sensor 在实际应用中的性能和稳定性。

在选择和应用G-sensor时，需要根据具体的需求和环境条件来综合考虑这些参数。

希望这些信息能够帮助到你。

2A Low Dropout Regulator with EnableFeaturesAdjustable Output from 1.2V to 4.8V Using Ex-ternal Resistors1.5V, 1.8V and2.5V options by Setting ADJ Pin Below 0.2VOver current and over temperature protection 500mV dropout @2A Enable pin10µA quiescent current in shutdown Output recovery mode in OTPConnect ADJ to GND for fixed output modeTO-252-5 PackageApplicationsBattery powered systems Motherboards Peripheral cards Set Top Boxes Notebook ComputersGeneral DescriptionThe G962 is a high performance positive voltage regulator designed for use in applications requiring very low dropout voltage at up to 2 Amps. Since it has superior dropout characteristics compared to regular LDOs, it can be used to supply 2.5V on motherboards or 1.5V, 1.8V on peripheral cards from the 3.3V supply thus allowing the elimination of costly heatsinks. An enable pin further reduces power dissipation while shut down. The G962 provides excellent regulation over variations in line, load and temperature.The TO-252-5 is available with 1.5V, 1.8V and 2.5V internally preset outputs that are also adjustable using external resistors.Ordering InformationORDER NUMBERORDER NUMBER(Pb free)MARKING TEMP. RANGE PACKAGEG962-15ADJTJU G962-15ADJTJUf G962-15 -40°C ~ +85°C TO-252-5 G962-18ADJTJU G962-18ADJTJUf G962-18 -40°C ~ +85°C TO-252-5 G962-25ADJTJU G962-25ADJTJUfG962-25-40°C ~ +85°CTO-252-5Note: TJ:TO-252-5U : Tape & Reele.g. 18 denotes the 1.8V output voltage.Pin Configuration Typical Application CircuitR2VEN VIN VO1.2 (R1+R2)VO =VoltsTO-252-5EN VIN GND VO ADJR2=12k Ωis recommendedR3 should be connected for current I ENH restriction as V EN > V IN +0.3VAbsolute Maximum Ratings (Note 1)Input Voltage……………………………….……………7V V EN Voltage……………………………….………V IN +0.3V Power Dissipation Internally Limited (Note 2) Maximum Junction Temperature.…..………..……150°C Storage Temperature Range…..….-65°C ≤T J ≤ +150°C Reflow Temperature (Soldering, 10 sec)……..…260°C Thermal Resistance Junction to Ambient, (θJA )TO-252-5…………………………………………95°C/W Thermal Resistance Junction to Case, (θJC )TO-252-5…………………………………………..…..8°C/W ESD Rating (Human Body Model)……….…………2kVOperation Conditions (Note 1)Input Voltage……………………………………2.2V ~7V Temperature Range……………......-40°C ≤T A ≤ +85°CElectrical CharacteristicsV EN =V IN , V IN =5V, I O = 0.5A, C IN = 4.7µF, C OUT =10µF, T A = T J = 25°C unless otherwise specified (Note 3)PARAMETER SYMBOLCONDITIONMIN TYP MAXUNITOutput Voltage V O V IN =V O +0.7V, I O =10mA -2 V O 2 %Line Regulation V O +0.7V < V IN < 5.5V, I O =10mA --- 0.2 2 %Load Regulation 10mA < I O < 2A --- 0.8 2 %V IN =3.3V,V EN =V IN --- 1.7 2.5 mAQuiescent Current I QV IN =3.3V,V EN =0V --- 16 35 µARipple Rejection fi=120Hz, 1V P-P , I O =100mA --- 55 --- dBDropout Voltage V D I O =2A --- 0.7 0.85 VShort Circuit Current --- 0.8 --- A Over Temperature (Note 4) --- 150 --- °C V EN Voltage High V ENH Output Active 1.6 --- --- VV EN Voltage Low V ENL Output Disabled --- --- 0.4 V V EN Bias Current Low I ENL V EN =0.4V --- --- 20 µA ADJ Reference Voltage V REF V IN =2.2V, V ADJ =V OUT , I O =10mA 1.176 1.2 1.224V ADJ Pin Threshold --- 0.2 --- VNote 1: Absolute Maximum Ratings are limits beyond which damage to the device may occur. Operating Con-ditions are conditions under which the device functions but the specifications might not be guaranteed. For guaranteed specifications and test conditions see the Electrical Characteristics.Note 2: The maximum power dissipation is a function of the maximum junction temperature, T Jmax ; total thermalresistance, θJA , and ambient temperature T A . The maximum allowable power dissipation at any ambient temperature is (T jmax -T A ) / θJA . If this dissipation is exceeded, the die temperature will rise above 150°C and IC will go into thermal shutdown.Note3: Low duty pulse techniques are used during test to maintain junction temperature as close to ambient as possible.Note4: The over temperature point is guarantee by design.DefinitionsDropout VoltageThe input/output voltage differential at which the regula-tor output no longer maintains regulation against further reductions in input voltage. Measured when the output drops 2% below its nominal value, dropout voltage is affected by junction temperature, load current and mini-mum input supply requirements.Line RegulationThe change in output voltage for a change in input volt-age. The measurement is made under conditions of low dissipation or by using pulse techniques such that aver-age chip temperature is not significantly affected. Load RegulationThe change in output voltage for a change in loadcurrent at constant chip temperature. The measure-ment is made under conditions of low dissipation or by using pulse techniques such that average chip tem-perature is not significantly affected.Maximum Power DissipationThe maximum total device dissipation for which the regulator will operate within specifications.Quiescent Bias CurrentCurrent which is used to operate the regulator chip and is not delivered to the load.Output Capacitor for Stable ConditionThe G962 can be stable for X5R MLCC capacitor lar-ger than 10µF or POSCAP capacitor larger than 47µF.Typical CharacteristicsV EN=V IN, =5V, I O = 0.5A, C IN = 4.7µF, C OUT =10µF, T A = T J = 25°C (V OUT=1.8V)Line Transient Load Transient Short Circuit Current Start-UP Overcurrent Protection Characteristics Ripple RejectionTypical Characteristics (continued)Max. Power Dissipation vs. T AMB (still air)Max. Power Dissipation vs.Recommend Minimum FootprintTO-252-5Package InformationTO-252-5 (TJ) PackageMILLIMETER INCHSYMBOLMIN. MAX. MIN. MAX.A 2.19 2.38 0.086 0.094 A1 0.89 1.27 0.035 0.050 b 0.64 0.89 0.025 0.035 C 0.46 0.58 0.018 0.023 D 5.36 5.61 0.211 0.221 E 6.35 6.73 0.250 0.265 E1 5.21 5.46 0.205 0.215 e 1.27BSC 0.050BSC F 0.46 0.58 0.0180.023 L 1.40 1.78 0.055 0.070 L1 2.20 2.80 0.087 0.110 L2 1.52 2.03 0.060 0.080 H 9.40 10.40 0.370 0.410 θ 0° 4° 0° 4°Taping SpecificationPACKAGE Q’TY/REELTO-252-5 2,500 eaGMT Inc. does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and GMT Inc. reserves the right at any time without notice to change said circuitry and specifications.bFeed DirectionTO-252-5 Package Orientation。

HT6X2X用户手册Tel: ************Fax*************Email:*********************Web: 版本更新说明版本号修改时间修改内容V0.1 2014-12-25 初版V1.0 2015-3-30 1.ADC管脚的输入范围和最大输入电压改为800mV2.芯片引脚结构说明图更改V1.1 2015-8-19 1.增加AES、GHASH、RAND模块概述V1.20 2015-8-29 1，电器规格：ADCBAT输入最低02，POWIN描述V1.30 2015-9-22 1. 电源框图修改，去掉VCC到VRTC之间的二极管2. 功耗参数修订：HRC、PLL增加区分所有数字模块开启和关闭的功耗数据V1.31 2015-9-28 1.RCCaliCON增加CLOCKIN说明V1.32 2016-4-6 1.删除MEMS相关内容V1.33 2016-4-21 1.增加5V tolerance IO的说明V1.4 2016-05-16 1.增加HT6027B 64PIN封装双SPI同时更改引脚定义2.增加TPS内部框图3.更改RTCRSTFLAG定义的POR复位为VRTC电源域2016-05-24 1.LCD章节添加1/4bias的COM/SEG 波形说明，LCDCON_VRSEL[3：0]]更新。

V1.5 2016-08-09 1. 修改ADCIN、ADCBAT、VCC计算公式2.ADCBA T pin输入范围统一到5.5V，公式修改；3.INT \RX Sleep唤醒状态描述修改；4.PIN脚描述修改，增加复用功能数字IO和模拟IO说明，以及OD和上拉的应用说明；5.寄存器默认值修正及说明；6.7816时序图及说明；7.14.4章节HRC频率描述笔误，更改为11MHz8.时钟单元增加时钟源的起振时间描述9.Sleep唤醒增加UART唤醒描述10.外部数字滤波增加说明11.Toff寄存器增加说明。

servo motor英语翻译2010-12-07sm26-cnc自动测量、自动上下料研磨机:*本机床适用于胶辊、海绵辊、轴类工件的磨削。

为两轴两联动数控机床即砂轮架进给x轴、工作台纵向移动z轴,且x、z轴可实现数控联动,采用交流伺服电机、滚珠丝杠带动。

配置fanuc~0it系列磨床专用系统,数控插补砂轮修整,可很好保证磨削状态的一致性。

*主轴系统采用液体动静压混合轴承。

尾架主轴采用套筒式结构,头架交流变频,可实现一定范围无级变速。

*机床配置意大利marposs公司在线自动测量系统(轴向定位、外圆),实现加工――测量闭环控制。

*机床采用全封闭防护装置(后床身顶面敞开),控制面板及操纵台设在机床右侧,符合人机工程学要求。

*机床一次装夹可完成工件的自动磨削循环,整个磨削过程由cnc控制、crt 显示、菜单式编程、砂轮过载保护、卡盘禁区保护等功能。

由量仪在线检测,磨削循环与修整砂轮循环依靠程序可自动转换。

sm25橡胶滚轮数控研磨机功能及特点:sm25本机适用于磨砺打印机胶辊、纺机胶辊。

配置自动上下料可大规模批量生产实现一人多机操作。

可实现自动微量进刀,所需加工参数可在触摸屏上任意设定。

从服务、精度、效率完全可替代进口机器。

1.该设备采用人机对话界面、交流伺服电机、crt显示、变频器、plc控制、操作极其安全。

2.砂轮磨头主轴采用液体动静压混合轴承,具独特长期免维护的设计理念,配置独立闭循环润滑、冷却机构,属液浮主轴,主轴无论是静态与动态均是悬浮状态,达到高精度、平稳、高速、无振动的效果。

3.工作台往复机构、砂轮架进退采用德国交叉滚珠直线滚动导轨,终身免维护,往复移动伺服电机驱动无级调速,保证往返精确、灵敏。

4.头架电机采用交流变频装置,实现无级调速。

5.磨削时采用气动保持架,可达到极其精确几何尺寸及表面粗糙度,尾架套筒具有气动伸缩功能,自动精确握持胶辊芯辊。

6.配置双层工作台面,很方便调节胶辊的磨砺锥度。

2A Low Dropout Regulator with EnableFeaturesAdjustable Output from 1.2V to 4.8V Using Ex-ternal Resistors1.5V, 1.8V and2.5V options by Setting ADJ Pin Below 0.2VOver current and over temperature protection 500mV dropout @2A Enable pin10µA quiescent current in shutdown Output recovery mode in OTPConnect ADJ to GND for fixed output modeTO-252-5 PackageApplicationsBattery powered systems Motherboards Peripheral cards Set Top Boxes Notebook ComputersGeneral DescriptionThe G962 is a high performance positive voltage regulator designed for use in applications requiring very low dropout voltage at up to 2 Amps. Since it has superior dropout characteristics compared to regular LDOs, it can be used to supply 2.5V on motherboards or 1.5V, 1.8V on peripheral cards from the 3.3V supply thus allowing the elimination of costly heatsinks. An enable pin further reduces power dissipation while shut down. The G962 provides excellent regulation over variations in line, load and temperature.The TO-252-5 is available with 1.5V, 1.8V and 2.5V internally preset outputs that are also adjustable using external resistors.Ordering InformationORDER NUMBERORDER NUMBER(Pb free)MARKING TEMP. RANGE PACKAGEG962-15ADJTJU G962-15ADJTJUf G962-15 -40°C ~ +85°C TO-252-5 G962-18ADJTJU G962-18ADJTJUf G962-18 -40°C ~ +85°C TO-252-5 G962-25ADJTJU G962-25ADJTJUfG962-25-40°C ~ +85°CTO-252-5Note: TJ:TO-252-5U : Tape & Reele.g. 18 denotes the 1.8V output voltage.Pin Configuration Typical Application CircuitR2VEN VIN VO1.2 (R1+R2)VO =VoltsTO-252-5EN VIN GND VO ADJR2=12k Ωis recommendedR3 should be connected for current I ENH restriction as V EN > V IN +0.3VAbsolute Maximum Ratings (Note 1)Input Voltage……………………………….……………7V V EN Voltage……………………………….………V IN +0.3V Power Dissipation Internally Limited (Note 2) Maximum Junction Temperature.…..………..……150°C Storage Temperature Range…..….-65°C ≤T J ≤ +150°C Reflow Temperature (Soldering, 10 sec)……..…260°C Thermal Resistance Junction to Ambient, (θJA )TO-252-5…………………………………………95°C/W Thermal Resistance Junction to Case, (θJC )TO-252-5…………………………………………..…..8°C/W ESD Rating (Human Body Model)……….…………2kVOperation Conditions (Note 1)Input Voltage……………………………………2.2V ~7V Temperature Range……………......-40°C ≤T A ≤ +85°CElectrical CharacteristicsV EN =V IN , V IN =5V, I O = 0.5A, C IN = 4.7µF, C OUT =10µF, T A = T J = 25°C unless otherwise specified (Note 3)PARAMETER SYMBOLCONDITIONMIN TYP MAXUNITOutput Voltage V O V IN =V O +0.7V, I O =10mA -2 V O 2 %Line Regulation V O +0.7V < V IN < 5.5V, I O =10mA --- 0.2 2 %Load Regulation 10mA < I O < 2A --- 0.8 2 %V IN =3.3V,V EN =V IN --- 1.7 2.5 mAQuiescent Current I QV IN =3.3V,V EN =0V --- 16 35 µARipple Rejection fi=120Hz, 1V P-P , I O =100mA --- 55 --- dBDropout Voltage V D I O =2A --- 0.7 0.85 VShort Circuit Current --- 0.8 --- A Over Temperature (Note 4) --- 150 --- °C V EN Voltage High V ENH Output Active 1.6 --- --- VV EN Voltage Low V ENL Output Disabled --- --- 0.4 V V EN Bias Current Low I ENL V EN =0.4V --- --- 20 µA ADJ Reference Voltage V REF V IN =2.2V, V ADJ =V OUT , I O =10mA 1.176 1.2 1.224V ADJ Pin Threshold --- 0.2 --- VNote 1: Absolute Maximum Ratings are limits beyond which damage to the device may occur. Operating Con-ditions are conditions under which the device functions but the specifications might not be guaranteed. For guaranteed specifications and test conditions see the Electrical Characteristics.Note 2: The maximum power dissipation is a function of the maximum junction temperature, T Jmax ; total thermalresistance, θJA , and ambient temperature T A . The maximum allowable power dissipation at any ambient temperature is (T jmax -T A ) / θJA . If this dissipation is exceeded, the die temperature will rise above 150°C and IC will go into thermal shutdown.Note3: Low duty pulse techniques are used during test to maintain junction temperature as close to ambient as possible.Note4: The over temperature point is guarantee by design.DefinitionsDropout VoltageThe input/output voltage differential at which the regula-tor output no longer maintains regulation against further reductions in input voltage. Measured when the output drops 2% below its nominal value, dropout voltage is affected by junction temperature, load current and mini-mum input supply requirements.Line RegulationThe change in output voltage for a change in input volt-age. The measurement is made under conditions of low dissipation or by using pulse techniques such that aver-age chip temperature is not significantly affected. Load RegulationThe change in output voltage for a change in loadcurrent at constant chip temperature. The measure-ment is made under conditions of low dissipation or by using pulse techniques such that average chip tem-perature is not significantly affected.Maximum Power DissipationThe maximum total device dissipation for which the regulator will operate within specifications.Quiescent Bias CurrentCurrent which is used to operate the regulator chip and is not delivered to the load.Output Capacitor for Stable ConditionThe G962 can be stable for X5R MLCC capacitor lar-ger than 10µF or POSCAP capacitor larger than 47µF.Typical CharacteristicsV EN=V IN, =5V, I O = 0.5A, C IN = 4.7µF, C OUT =10µF, T A = T J = 25°C (V OUT=1.8V)Line Transient Load Transient Short Circuit Current Start-UP Overcurrent Protection Characteristics Ripple RejectionTypical Characteristics (continued)Max. Power Dissipation vs. T AMB (still air)Max. Power Dissipation vs.Recommend Minimum FootprintTO-252-5Package InformationTO-252-5 (TJ) PackageMILLIMETER INCHSYMBOLMIN. MAX. MIN. MAX.A 2.19 2.38 0.086 0.094 A1 0.89 1.27 0.035 0.050 b 0.64 0.89 0.025 0.035 C 0.46 0.58 0.018 0.023 D 5.36 5.61 0.211 0.221 E 6.35 6.73 0.250 0.265 E1 5.21 5.46 0.205 0.215 e 1.27BSC 0.050BSC F 0.46 0.58 0.0180.023 L 1.40 1.78 0.055 0.070 L1 2.20 2.80 0.087 0.110 L2 1.52 2.03 0.060 0.080 H 9.40 10.40 0.370 0.410 θ 0° 4° 0° 4°Taping SpecificationPACKAGE Q’TY/REELTO-252-5 2,500 eaGMT Inc. does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and GMT Inc. reserves the right at any time without notice to change said circuitry and specifications.bFeed DirectionTO-252-5 Package Orientation。

1/12Information on available spare parts: /spc4/2 and 4/3 directional shut-off valves, internally pilot operated, externally pilot operatedTypes Z4WEH and Z4WHSize 10Component series 4XMaximum operating pressure 315 bar Maximum flow 160 l/minRE 24753/08.08Replaces: 04.93Table of contentsFeaturesContent PageFeatures 1Ordering code 2, 3Mating connectors 3Symbols 4, 5Function, section 6, 7Technical data 8Characteristic curves 9Unit dimensions10, 11Stroke adjustment, attachment options12– Directional spool valve, pilot operated – 2 types of actuation:• Electrohydraulic (type WEH) • Hydraulic (type WH)– Function as shut-off through-valve or shut-off/through valve/short-circuit valve– Free flow in P and T in every spool position – Porting pattern to ISO 4401-05-04-0-05– Wet-pin DC or AC voltage solenoids, optional – Manual override, optional– Electrical connection as individual or central connection, see RE 23178 and RE 08010– Switching time adjustment, optional – Stroke adjustment of main spool, optional– Inductive position switch and proximity sensors (contact-less), see RE 24830tb0255o u r t e s y o f C M A /F l o d y n e /H y d r a d y n e ▪ M o t i o n C o n t r o l ▪ H y d r a u l i c ▪ P n e u m a t i c ▪ E l e c t r i c a l ▪ M e c h a n i c a l ▪ (800) 426-5480 ▪ w w w .c m a f h .c o mOrdering codeTypes of actuation Electrohydraulic = WEH Hydraulic = WHSize NG10= 10Spool symbols, see pages 4 and 5Component series 40 to 49= 4X(40 to 49: unchanged installation and connection dimensions)Pilot valveHigh-performance valve (RE 23178)= 6E 1)DC voltage 24 V= G24 1) AC voltage 230 V 50/60 Hz = W230 1)DC voltage 205 V 50/60 Hz= G205 1; 2)For further voltages, frequencies and electrical data, see data sheet RE 23178Without manual override = No codeWith manual override= N 1)With concealed manual override (standard)= N9 1)External pilot oil supply, external pilot oil drain= No codeInternal pilot oil supply, internal pilot oil drain (standard) = ET External pilot oil supply, internal pilot oil drain = T(with type Z4WH… only “No code“ possible!) Without switching time adjustment= No codeSwitching time adjustment as meter-in control = S Switching time adjustment as meter-out control= S21) Only with electrohydraulic actuation, version “WEH“2) For connection to the AC voltage mains, a DC voltage sole -noid must be used, which is to be controlled via a rectifier (see table on the right-hand side).In the case of individual connection, a mating connector with integrated rectifier can be used (separate order, see page 3).3) Mating connectors, separate order, see page 3.4) On version “D3“, a throttle insert “B08“ must be installed inport P of the pilot valve!Z4104XAC voltage mains (permissible voltage tolerance ±10%)Nominal voltage of the DC voltage solenoid when operated with AC voltageO r d e r i n g c o d e 110 V - 50/60 Hz 120 V - 60 Hz 96 V G96230 V - 50/60 Hz205 VG205o u r t e s y o f C M A /F l o d y n e /H y d r a d y n e ▪ M o t i o n C o n t r o l ▪ H y d r a u l i c ▪ P n e u m a t i c ▪ E l e c t r i c a l ▪ M e c h a n i c a l ▪ (800) 426-5480 ▪ w w w .c m a f h .c o mMating connectors to DIN EN 175301-803For detailsand further mating connectors, see RE 08006Valve side Color Material no.Without circuitry With indicator lamp12 … 240 VWith rectifier 12 … 240 VWith indicator lamp and Zener-diode suppressorcircuit 24 Va Gray R901017010–––b Black R901017011–––a/bBlack–R901017022R901017025R901017026o u r t e s y o f C M A /F l o d y n e /H y d r a d y n e ▪ M o t i o n C o n t r o l ▪ H y d r a u l i c ▪ P n e u m a t i c ▪ E l e c t r i c a l ▪ M e c h a n i c a l ▪ (800) 426-5480 ▪ w w w .c m a f h .c o mSymbols: Type Z4WEH (① = component side, ② = plate side)1) Opening cross-section in spool position “a” (A2 → B2)= 50 mm 22) Opening cross-section in spool position “b” (A2 → B2)= 35 mm 2o u r t e s y o f C M A /F l o d y n e /H y d r a d y n e ▪ M o t i o n C o n t r o l ▪ H y d r a u l i c ▪ P n e u m a t i c ▪ E l e c t r i c a l ▪ M e c h a n i c a l ▪ (800) 426-5480 ▪ w w w .c m a f h .c o mSymbols: Type Z4WH (① = component side, ② = plate side)1) Opening cross-section in spool position “a” (A2 → B2)= 50 mm 22) Opening cross-section in spool position “b” (A2 → B2)= 35 mm 2o u r t e s y o f C M A /F l o d y n e /H y d r a d y n e ▪ M o t i o n C o n t r o l ▪ H y d r a u l i c ▪ P n e u m a t i c ▪ E l e c t r i c a l ▪ M e c h a n i c a l ▪ (800) 426-5480 ▪ w w w .c m a f h .c o mFunction, section: Type Z4WEHValves of type Z4WEH are directional spool valves with elec -trohydraulic actuation. They control the start and stop of a flow.These directional valves basically consist of the main valve with housing (1), main control spool (2), one or two return springs (3.1 and 3.2), and pilot valve (4).Main control spool (2) in the main valve is held by the springs in the zero or initial position. In the initial position, the two spring chambers (6) and (8) are connected pressureless to tank via pilot valve (4). The pilot valve is supplied with pilot oil via pilot channel (7). The pilot oil supply can be provided internally or externally (externally via port X in the sandwich plate, see page 10).When the pilot valve is operated, e.g. solenoid “a“, pilot spool (5) is pushed to the left, and consequently spring chamber (8) is pressurized to pilot pressure. Spring chamber (6) remains pressureless.The pilot pressure acts on the left side of main control spool (2) and pushes it against spring (3.1). As a result of this, the connections on the component side and on the plate side are opened according to the relevant symbols.When the solenoid is de-energized, pilot spool (5) returns to the initial position. Pressure chamber (8) is unloaded to the tank.The pilot oil is drained from spring chamber (8) internally via pilot valve (4) into channel T (Y).An optional manual override (9) allows pilot spool (5) to be moved without energization of the solenoid.Throttle insertThe use of throttle insert (11) is required, if the pilot oil supply in channel P of the pilot valve is to be limited.Throttle insert (11) is to be installed in channel P of the pilot valve.① = component side ② = plate sideo u r t e s y o f C M A /F l o d y n e /H y d r a d y n e ▪ M o t i o n C o n t r o l ▪ H y d r a u l i c ▪ P n e u m a t i c ▪ E l e c t r i c a l ▪ M e c h a n i c a l ▪ (800) 426-5480 ▪ w w w .c m a f h .c o mFunction, section: Type Z4WHValves of type Z4WH are directional spool valves with hy -draulic actuation. They control the start and stop of a flow.These directional valves basically consist of valve housing (1), main control spool (2), one or two return springs (3.1) and (3.2) in the case of valves with spring return or spring center -ing, as well as pilot oil subplate (10).Main control spool (2) is operated directly by pressurization.Main control spool (2) is held by springs in the zero or initial position. The pilot oil is supplied and drained externally (see page 12).o u r t e s y o f C M A /F l o d y n e /H y d r a d y n e ▪ M o t i o n C o n t r o l ▪ H y d r a u l i c ▪ P n e u m a t i c ▪ E l e c t r i c a l ▪ M e c h a n i c a l ▪ (800) 426-5480 ▪ w w w .c m a f h .c o mTechnical data (for applications outside these parameters, please consult us!)GeneralWeight– Valve with 1 solenoid kg 4.2– Valve with 2 solenoids kg 4.6– Valve with hydraulic actuation (type 4WH…)kg 3.5– Switching time adjustment kg 0.8– Pressure reducing valve kg 0.4– Plate for version “T“kg 0.5Installation position OptionalAmbient temperature range°C –30 to +50 (NBR seals)–20 to +50 (FKM seals)HydraulicMaximum oper-ating pressure– Ports A and B bar 315– Port PExternal pilot oil supply bar 315Internal pilot oil supply bar 250 (without pressure reducing valve)315 (with pressure reducing valve)– Port T(Pilot oil drain only internal)bar 210 (with DC solenoid)160 (with AC solenoid)Minimum pilot pressure bar 12Maximum flowl/min 160Pilot volume for operation cm 3 1.3Hydraulic fluid 1)Mineral oil (HL, HLP) to DIN 51524 2); fast bio-degradable hydraulic fluids to VDMA 24568 (see also RE 90221); HETG (rape seed oil) 2); HEPG (polyglycols) 3); HEES (synthetic esters) 3); other hydraulic fluids on request Hydraulic fluid temperature range °C –30 to +80 (NBR seals)–20 to +80 (FKM seals)Viscosity rangemm 2/s 2.8 to 500Permissible max. degree of contamination of the hydraulic fluid - cleanliness class to ISO 4406 (c)Class 20/18/15 4)ElectricalSwitching time to ISO 6403at pilot pressure bar70140210~=~=~= – ON ms 306525602055– OFFms 301) The ignition temperature of the process and operatingmedium used must be higher than the maximum solenoid surface temperature.2) Suitable for NBR and FKM seals 3) Suitable only for FKM seals4) The cleanliness classes specified for components must beadhered to in hydraulic systems. Effective filtration prevents malfunction and, at the same time, prolongs the service life of components.For the selection of filters, see data sheets RE 50070,RE 50076, RE 50081, RE 50086, RE 50087 and RE 50088.– The manual override can only be actuated up to a tank pressure of ca. 50 bar. Avoid damage to the bore for the manual override! (Special tool for operation, separate or -der, Material no. R900024943). When the manual override is blocked, operation of the solenoids must be ruled out!– The simultaneous operation of the solenoids must be ruled out!o u r t e s y o f C M A /F l o d y n e /H y d r a d y n e ▪ M o t i o n C o n t r o l ▪ H y d r a u l i c ▪ P n e u m a t i c ▪ E l e c t r i c a l ▪ M e c h a n i c a l ▪ (800) 426-5480 ▪ w w w .c m a f h .c o m15141210864202040100608012014016012345Characteristic curves (measured with HLP46, ϑoil = 40 °C ±5 °C)Flow in l/min →P r e s s u r e d i f f e r e n t i a l i n b a r →∆p -q V characteristic curves 1A1 → A2; B1 → B22A2 → A13A2 → B24B2 → B15B2 → A2o u r t e s y o f C M A /F l o d y n e /H y d r a d y n e ▪ M o t i o n C o n t r o l ▪ H y d r a u l i c ▪ P n e u m a t i c ▪ E l e c t r i c a l ▪ M e c h a n i c a l ▪ (800) 426-5480 ▪ w w w .c m a f h .c o mUnit dimensions: Type Z4WEH10 (dimensions in mm)o u r t e s y o f C M A /F l o d y n e /H y d r a d y n e ▪ M o t i o n C o n t r o l ▪ H y d r a u l i c ▪ P n e u m a t i c ▪ E l e c t r i c a l ▪ M e c h a n i c a l ▪ (800) 426-5480 ▪ w w w .c m a f h .c o m1Nameplate of complete valve 2Nameplate of pilot valve 3Main valve4Sandwich plate for external pilot control (to be used at operating pressure > 210 bar)5Pressure reducing valve “D3”(must be used in the case of pilot pressures above 250 bar; only with version “Z4WEH“)Material no.:NBR seals: R900323180 FKM seals: R9003236646Space required to remove mating connector7Switching time adjustment (for throttle check valve, see data sheet RE 27506); depending on the installation po -sition, meter-in or meter-out control (illustration: meter-in control)8R-ring plate9Pilot valve (see data sheet RE 23178)– Type 4WE 6 J .. for symbol E62– Type 4WE 6 Y .. for symbol E50, E51, E52, E63, E68Dimensions () for valve with AC solenoidUnit dimensions: Type Z4WH10 (dimensions in mm)10Dimension for valve without manual override 11Dimension for valve with manual override “N“; dimen-sions () for valve with AC solenoid 12Dimension for valve with concealed manual override“N9“; dimensions () for valve with AC solenoid without manual override 13Solenoids “a” and “b” (can be rotated 90°)14Identical seal rings for ports A, B, P, TA and TB 15Identical seal rings for ports A, B, P and T 16Pilot oil subplate 17Valve mounting boresValve mounting screws (separate order)4 hexagon socket head cap screws ISO 4762 - M6 - 10.918Valve mounting screws (separate order)4 hexagon socket head cap screws ISO 4762 - M5 - 10.9The length and tightening torque of the valve mountingscrews must be calculated taking account of the components mounted.o u r t e s y o f C M A /F l o d y n e /H y d r a d y n e ▪ M o t i o n C o n t r o l ▪ H y d r a u l i c ▪ P n e u m a t i c ▪ E l e c t r i c a l ▪ M e c h a n i c a l ▪ (800) 426-5480 ▪ w w w .c m a f h .c o mBosch Rexroth AG HydraulicsZum Eisengießer 197816 Lohr am Main, Germany Phone +49 (0) 93 52 / 18-0 Fax +49 (0) 93 52 / 18-23 58*****************************www.boschrexroth.de© This document, as well as the data, specifications and other informa-tion set forth in it, are the exclusive property of Bosch Rexroth AG. It may not be reproduced or given to third parties without its consent.The data specified above only serve to describe the product. No state-ments concerning a certain condition or suitability for a certain applica-tion can be derived from our information. The information given does not release the user from the obligation of own judgment and verifica-tion. It must be remembered that our products are subject to a natural process of wear and aging.Stroke adjustment, attachment options (dimensions in mm)The stroke adjustment feature limits the stroke of the mainspool. The spool stroke can be reduced by loosening locknut (17) and turning adjustment spindle (18) clockwise. The con -trol chamber must be pressureless during this process.Stroke 6 mm (1 turn = 1 mm stroke)17 Locknut 27 A/F18Adjustment spindle, hexagon socket 5 A/Fo u r t e s y o f C M A /F l o d y n e /H y d r a d y n e ▪ M o t i o n C o n t r o l ▪ H y d r a u l i c ▪ P n e u m a t i c ▪ E l e c t r i c a l ▪ M e c h a n i c a l ▪ (800) 426-5480 ▪ w w w .c m a f h .c o m。

Our legacy is your future.Technical DataINNIO’s Waukesha* VHP* Series Four* rich-burn engines are the engines of choice for the harshest and most demanding gas compression, power generation and mechanical drive applications. The Series Four engines can reliably produce more power on hot field gases, at high altitudes, and in remote locations, all while delivering low emissions when paired with a 3-way catalyst (NSCR).ESM*2 is Waukesha’s next-generation engine controller, adding functionality and benefits to the proven ESM platform.The ESM2 customer interface is a 12” full-color touch screen display panel that allows users to see all engineparameters, trend data, view manuals, and walk through troubleshootingsteps, eliminating the need for a laptop computer.ESM2 directly reads exhaust and main bearing temperatures sensors and adds crankcase pressure, boost pressure, and an oil pressure permissive for starting the engine to the list of sensors available with the previous version of ESM.Enhanced misfire detection can capture a single misfire event and an enhanced three-dimensional timing map allows for tighter engine control over the entire range of fuels.Waukesha’s emPact Emission Control System combines an engine, catalyst, and air/fuel ratio control, factory-designed for optimal interaction and maximum performance. It consists of a factory supplied catalyst, pre- and post-catalyst oxygen sensing, and differential temperature and pressure sensors. emPact’s closed-loop control system measures the engine exhaust andautomatically adjusts the air/fuel ratio to keep the catalyst operating at maximum efficiency, even as speed, load, fuel, and ambient conditions change.CylindersV12Pistondisplacement 7,040 cu. in. (115 L)Compression ratio 8:1Bore & stroke 9.375’’ x 8.5’’ (238 x 216)Jacket water system capacity 100 gal. (379 L)Lube oil capacity 190 gal. (719 L)Starting system125 - 150 psi air/gas 24V electricDimensions l x w x h inch (mm)147 (3,734) x 85 (2,159) x 97.83 (2,485)Weights lb (kg)24,250 (11,000)VHP Series Four L7044GSIPerformance DataINNIO* is a leading solutions provider of gas engines, power equipment, a digital platform and related services for power generation and gas compression at or near the point of use. With our Jenbacher* and Waukesha* product brands, INNIO pushes beyond the possible and looks boldly toward tomorrow. Our diverse portfolio of reliable, economical and sustainable industrial gas engines generates 200 kW to 10 MW of power for numerous industries globally. We can provide life cycle support to the more than 48,000 delivered gas engines worldwide. And, backed by our service network in more than 100 countries, INNIO connects with you locally for rapid response to your service needs. Headquartered in Jenbach, Austria, the business also has primary operations in Welland, Ontario, Canada, and Waukesha, Wisconsin, US.Find your local support online:/en/company/providersIWK-119003-EN*Indicates a trademark© Copyright 2021 INNIO Waukesha Gas Engines Inc. Information provided is subject to change without notice. All values are design or typical values when measuredunder laboratory conditions.Intercooler Water Temperature 130°F (54°C)1200 RPM 1000 RPMPower bhp (kWb)1,680(1,253)1,400(1,044)BSFC (LHV) Btu/bhp-hr (kJ/kWh)7,881(11,149)7,693(10,884)Fuel Consumption Btu/hr x 1000 (kW)13,240(3,881)10,770(3,157)e m P a c t C a t a l y s t -O u t E m i s s i o n sNOx g/bhp-hr (mg/Nm 3 @ 5% O 2)0.5(185)CO g/bhp-hr (mg/Nm 3 @ 5% O 2) 1.0(370)NMHC g/bhp-hr (mg/Nm 3 @ 5% 02)0.18(67)THC g/bhp-hr (mg/Nm 3 @ 5% O 2) 1.68(626)E n g i n e -O u t E m i s s i o n sNOx g/bhp-hr (mg/Nm 3 @ 5% O 2)13.30(4,922)12.9(4,782)CO g/bhp-hr (mg/Nm 3 @ 5% O 2)11.20(4,140)9.4(3,477)NMHC g/bhp-hr (mg/Nm 3 @ 5% 02)0.35(131)0.34(127)THC g/bhp-hr (mg/Nm 3 @ 5% O 2) 2.40(873) 2.30(844)H e a t B a l a n c e Heat to Jacket Water Btu/hr x 1000 (kW)3,849(1,128)3,230(947)Heat to Lube Oil Btu/hr x 1000 (kW)567(166)463(136)Heat to Intercooler Btu/hr x 1000 (kW)179(53)119(35)Heat to Radiation Btu/hr x 1000 (kW)724(212)642(188)Total Exhaust Heat Btu/hr x 1000 (kW)3,900(1,143)2,962(868)I n t a k e /E x h a u s t S y s t e mInduction Air Flow scfm (Nm 3/hr)2,424(3,651)1,972(2,970)Exhaust Flow lb/hr (kg/hr)11,273(5,113)9,171(4,160)Exhaust Temperature °F (°C)1,179(637)1,112(600)All data according to full load and subject to technical development and modification.emPact catalyst-out emissions valid from 100% - 75% load and 1200 rpm to 900 rpm and assume proper engine/catalyst maintenance and manual adjustment as necessary.Consult your local Waukesha representative for system application assistance. The manufacturer reserves the right to change or modify without notice, the design or equipment specifications as herein set forth without incurring any obligation either with respect to equipment previously sold or in the process of construction except where otherwise specifically guaranteed by the manufacturer.。

AZP92ECL/PECL ÷1, ÷2 Clock Generation Chip with Selectable EnableFEATURES• Green and RoHS Compliant / Lead (Pb) Free Package Available • 3.0V to 5.5V Operation • Selectable Divide Ratio• Selectable Enable Polarity and Threshold (CMOS/TTL or PECL) • Selectable Input Biasing • High Bandwidth for ≥1GHz• Available in a MLP 8 (2x2) Package • IBIS Model File Available on Arizona Microtek WebsiteDESCRIPTIONThe AZP92 is a specialized ÷1 or ÷2 clock generation part including an enable/reset function. The divide ratio isselected with the DIV-SEL pin/pad. When DIV-SEL is open (NC), the AZP92 functions as a standard receiver. If DIV-SEL is connected to V EE , it functions as a ÷2 divider.A selectable enable is provided which also functions as a reset when the ÷2 mode is selected. Enable (EN) functionality is selected with the EN-SEL pin/pad which has three valid states: open (NC), V EE , or connected to V EE via a 20k Ω resistor. Leaving EN-SEL open or connecting it to V EE will select the EN pin/pad to function as an active high CMOS/TTL enable. When EN-SEL is open, an internal 75k Ω pull-up resistor is selected which enables the outputs whenever EN is left open. When EN-SEL is connected to V EE , an internal 75k Ω pull-down resistor is selected which disables the outputs whenever EN is left open.Connecting the EN-SEL to V EE with a 20k Ω resistor will select the EN pin/pad to function as an active low PECL/ECL enable with an internal 75k Ω pull-down resistor. In this mode, outputs are enabled when EN is left open (NC). This default logic condition can be overridden by connecting the EN to V CC with an external resistor of ≤20k Ω. Refer to the enable truth table on the next page for detailed operation.DIE (AZP92X)The AZP92X provides a V BB and a BIAS pad with 940Ω internal resistors from D to BIAS and D¯ to BIAS. Connecting the BIAS pad to V BB allows D and D ¯ to be AC coupled with minimal external components. For single ended applications, D or D ¯ may be connected directly to V BB to form a single 1880Ω bias resistor. The V BB pin supports 1.5mA sink/source current. Whenever used, the V BB should be bypassed to ground or V CC with a 0.01 μF capacitor.MLP 8, 2x2 mm Package (AZP92NA)The AZP92NA provides a V BB with an 1880Ω internal bias resistor from D to V BB . This feature allows AC coupling with minimal external components. The V BB pin supports 1.5mA sink/source current and should be bypassed to ground or V CC with a 0.01 μF capacitor.NOTE: The specifications in the ECL/PECL tables are valid when thermal equilibrium has been established.PACKAGE AVAILABILITYPACKAGE PART NO. MARKING NOTESMLP 8 (2x2) Green/ RoHS Compliant / Lead (Pb) FreeAZP92NAG P1G<Date Code>1,2DIE AZP92X N/A 3,41Add R1 at end of part number for 7 inch (1K parts), R2 for 13 inch (2.5K parts)Tape & Reel. 2 Date code format: “Y” for year followed by “WW” for week. 3 Waffle Pack 4 Contact factory for availabilityAZP92TIMING DIAGRAMSIGNAL DESCRIPTIONPIN/PAD FUNCTIOND/D¯ DataInputsQ/Q¯ DataOutputsV BB Reference Voltage OutputBIAS Input Bias ReturnEN Enable/ResetInputEN-SEL EnableLogicSelectDIV-SEL Divide Ratio SelectV EE NegativeSupplyV CC Positive SupplyENABLE TRUTH TABLEEN-SEL EN QQ¯NCNCCMOS Low or V EECMOS High, V CC or NCLowDataHighDataV EEV EECMOS Low, V EE or NCCMOS High or V CCLowDataHighData20kΩ to V EE20kΩ to V EEPECL Low, V EE or NCPECL High or V CCDataLowDataHighQD(EN-SEL CONNECTED TOV EE VIA 20k RESISTOR)(EN-SEL OPEN ORCONNECTED TO V EE)EN(PECL)(CMOS)(DIV-SELCONNECTEDTO V EE)(DIV-SELOPEN)ENQDIVIDE TRUTH TABLEDIV-SEL DIVIDERATIONC ÷1V EE1 ÷21DIV-SEL connection mustbe ≤1Ω.AZP92DIE PAD COORDINATESNAME SIGNALX (Microns) Y(Microns)A D -342.5 312.5B D ¯ -342.5 144.5C BIAS -342.5 -87.0D V BB -342.5 -255.0E EN -33.5 -312.5F V EE 126.5 -312.5G DIV-SEL 312.5 -248.5H Q ¯ 312.5-98.5 I Q 312.5 51.5 J NC 312.5 201.5 K V CC 302.5 342.5 L V CC 142.5 342.5 M EN-SEL -140.5 342.5Notes: 1. Other die thicknesses available. Contactfactory for further information.2. The die backside may be left open or connected to V EE .A ML K JI H GFE DC B DIE SIZE: 950u X 940u BOND PAD: 85u X 85uDIE THICKNESS: 14 MILS AZP92AZP92Absolute Maximum Ratings are those values beyond which device life may be impaired.Symbol Characteristic Rating UnitV CC PECL Power Supply (V EE = 0V) 0 to +6.0 Vdc V I PECL Input Voltage (V EE = 0V) 0 to +6.0 Vdc V EE ECL Power Supply (V CC = 0V) -6.0 to 0 Vdc V I ECL Input Voltage (V CC = 0V) -6.0 to 0Vdc I HGOUTOutput Current — Continuous — Surge 50100mA T A Operating Temperature Range -40 to +85 °C T STG Storage Temperature Range -65 to +150°C100K ECL DC Characteristics (V EE = -3.0V to -5.5V, V CC = GND)-40°C 0°C 25°C 85°C SymbolCharacteristicMin Max Min Max Min Max Min MaxUnit V OH Output HIGH Voltage 1 -1085 -880 -1025 -880 -1025 -880 -1025 -880 mVV OL Output LOW Voltage 1-1900 -1555 -1900 -1620 -1900 -1620 -1900 -1620 mVV IH Input HIGH Voltage D/D ¯, EN (ECL)2 EN (CMOS)3-1165 V EE +2000 -390 V CC -1165 V EE +2000-390 V CC -1165 V EE +2000 -390 V CC -1165 V EE +2000 -390 V CC mV V IL Input LOW VoltageD/D ¯, EN (ECL)2EN (CMOS)3-2250 V EE -1475 V EE + 800 -2250 V EE -1475 V EE + 800 -2250 V EE -1475 V EE + 800 -2250 V EE -1475 V EE + 800 mV V BB Reference Voltage -1390 -1250 -1390 -1250 -1390 -1250 -1390 -1250 mVI IH Input HIGH Current EN 150 150 150 150 μAI IL Input LOW CurrentEN (ECL)2 EN (CMOS)30.5 -150 0.5 -150 0.5 -150 0.5 -150 μAI EE Power Supply Current 4 31 31 31 34 mA 1. Specified with outputs terminated through 50Ω resistors to V CC - 2V. 2. EN-SEL connected to V EE through a 20k Ω resistor. 3. EN-SEL connected V EE or left open (NC). 4. DIV-SEL left open (NC).100K LVPECL DC Characteristics (V EE = GND, V CC = +3.3V)-40°C 0°C 25°C 85°C Symbol CharacteristicMin Max Min Max Min Max Min MaxUnit V OH Output HIGH Voltage 1,2 2215 2420 2275 2420 2275 2420 2275 2420 mV V OL Output LOW Voltage 1,2 1400 1745 1400 1680 1400 1680 1400 1680 mVV IH Input HIGH Voltage 1 D/D ¯, EN (PECL)3EN (CMOS)4 2135 2000 2910 V CC 2135 2000 2910 V CC 2135 2000 2910 V CC 2135 20002910 V CCmV V IL Input LOW Voltage 1D/D ¯, EN (PECL)3EN (CMOS)41050 GND 1825 800 1050 GND 1825 800 1050 GND 1825 800 1050 GND 1825 800mV V BB Reference Voltage 1 1910 2050 1910 2050 1910 2050 1910 2050 mVI IH Input HIGH Current EN 150 150 150 150 μAI IL Input LOW CurrentEN (PECL)3EN (CMOS)40.5 -150 0.5 -150 0.5 -150 0.5 -150 μA I EE Power Supply Current 5 31 31 31 34 mA 1. For supply voltages other that 3.3V, use the ECL table values and ADD supply voltage value. 2. Specified with outputs terminated through 50Ω resistors to V CC - 2V. 3. EN-SEL connected to V EE through a 20k Ω resistor. 4. EN-SEL connected V EE or left open (NC). 5. DIV-SEL left open (NC).AZP92100K PECL DC Characteristics (V EE = GND, V CC = +5.0V)-40°C 0°C 25°C 85°C Symbol CharacteristicMin Max Min Max Min Max Min MaxUnit V OH Output HIGH Voltage 1,2 3915 4120 3975 4120 3975 4120 3975 4120 mV V OL Output LOW Voltage 1,2 3100 3445 3100 3380 3100 3380 3100 3380 mVV IH Input HIGH Voltage 1D/D ¯, EN (PECL)3EN (CMOS)4 3835 2000 4610 V CC 3835 2000 4610 V CC 3835 2000 4610 V CC 3835 2000 4610 V CCmV V IL Input LOW Voltage 1D/D ¯, EN (PECL)3EN (CMOS)42750 GND 3525 800 2750 GND 3525 800 2750 GND 3525 800 2750 GND 3525 800mV V BB Reference Voltage 1 3610 3750 3610 3750 3610 3750 3610 3750 mVI IH Input HIGH Current EN 150 150 150 150 μAI IL Input LOW CurrentEN (PECL)3EN (CMOS)40.5 -150 0.5 -150 0.5 -150 0.5 -150 μA I EE Power Supply Current 5 31 31 31 34 mA 1. For supply voltages other that 5.0V, use the ECL table values and ADD supply voltage value. 2. Specified with outputs terminated through 50Ω resistors to V CC - 2V. 3. EN-SEL connected to V EE through a 20k Ω resistor. 4. EN-SEL connected V EE or left open (NC). 5. DIV-SEL left open (NC).AC Characteristics (V EE = -3.0V to -5.5V; V CC = GND or V EE = GND; V CC = +3.0V to +5.5V)-40°C 0°C 25°C 85°C SymbolCharacteristicMin Typ Max Min Typ Max Min Typ Max Min Typ Max Unitt PLH / t PHL Propagation DelayD to Q/Q ¯ Outputs 1(SE)EN to Q/Q ¯ Outputs 1450 600 450 600 450 600 450 600 ps t SKEW Duty Cycle Skew 2 (SE) 5 20 5 20 5 20 5 20 psV PP (AC) Input Swing 3Differential (D/D ¯)Single Ended (D)4150 300 1000 2000 150 300 1000 2000 150 300 1000 2000 150 300 1000 2000 mV t r / t fOutput Rise/Fall 1(20% - 80%)80 200 80 200 80 200 80 200 ps 1. Specified with outputs terminated through 50Ω resistors to V CC - 2V.2. Duty cycle skew is the difference between a t PLH and t PHL propagation delay through a device.3. The peak-to-peak input swing is the range for which AC parameters are guaranteed.4. Range valid for AC coupled signals only.AZP92SIDE VIEW Note: All dimensions are in mmAZP92。

日本第一大制药公司武田制药在研产品线Takeda R&D StrategyTadataka Yamada, M.D.Chief Medical & Scientific OfficerDeborah Dunsire, M.D.President and CEO, Millennium: The Takeda Oncology CompanyNikko Hotel, , San Francisco January 8, 2019Takeda R&D ValueTakeda is a p pharmaceutical company p y committed to the discovery and development of innovative solutions addressing unmet medical needs of patients ti t through th h R&D i investment t t1 | R&D Meeting | January 8, 2019Takeda R&D MissionMeet the future promise of Takeda as a leader l d i in th the pharmaceutical h ti l industry by providing solutions to patients ti t withith unmet t medical di l needs d Transform the R&D organization to be an engine of growth that is an industry leader in R&D productivity2 | R&D Meeting | January 8, 2019Takeda R&D PrinciplesURGENCYINNOVATIONFocus on PatientsPARTNERSHIPMEASUREMENT3 R&D Meeting | January 8, 2019Takeda R&D PrinciplesURGENCY4 | R&D Meeting | January 8, 2019Takeda R&D PrinciplesINNOVATIONNew Frontier ScienceNovel New Molecular EntityTAK-875 TAK-438 438 TAK MLN0002 TAK-375SL AD-4833/TOMM404833/TOMM40 AD Lupron 6M DepotNovel Life Cycle ManagementDrug Discovery Unit CMC Center5 | R&D Meeting | January 8, 2019Takeda R&D PrinciplesMEASUREMENTPOC&C C Concept tValue CreationPOC&C: Proof of Concept & Competitiveness6 | R&D Meeting | January 8, 2019Takeda R&D PrinciplesWhy y POC&C?Valid surrogate of value - 50% success to market More proximate measure of value creation Focus measurement on peak year sales Better tool to predict future corporate performance Set targets g for therapeutic p area units7 | R&D Meeting | January 8, 2019Takeda R&D PrinciplesPARTNERSHIPIn license In-licenseDi Discovery(formerly Syrrx)Takeda CaliforniaMill Millennium iN Nycomed dAffymax, y Lundbeck, Orexigen, Novartis, Seattle Genetics, etc.• REVESTIVE • ADCETRIS • OMONTYS • RIENSO • CONTRAVE • LOTRIGA • BRINTELLIX* • Lurasidone • ATL-962 • AMG 386 • AMG 706 • TAK-816 • TAK-361S • ITI-214• Advinus • Envoy • LigoCyte • Intracellular Therapies• NESINA • SYR-472• MLN0002 • MLN9708 • MLN8237 • MLN0264• DAXAS • REVESTIVE • Veltuzumab • Namilumab • Alvesco • Omnaris*Proposed brand name of Lu AA210048| R&D Meeting | January 8, 20196 Therapeutic AreasPipeline Assets in Phase 2 or Beyond Metabolic / CV• • • • BLOPRESS EDARBI AZILVA NESINA • • • • • CONTRAVE ATL-962 TAK-875 SYR-472 TAK-428Oncology• VELCADE • LUPRON • ADCETRIS • • • • • MLN9708 MLN8237 TAK-700 AMG 706 AMG 386CNS• BRINTELLIX* • Lurasidone TAK 375SL • TAK-375SL • SOVRIMARespiratory & Inflammatory f• DAXAS • Veltuzumab • • • • • •General MedicineTAKEPRON DEXILANT REVESTIVE OMONTYS RIENSO AMITIZA • MLN0002 • TAK-438 • TAK TAK-385 385Vaccine• TAK-816 • TAK-361S • Norovirus vaccine*Proposed brand name of Lu AA210049| R&D Meeting | January 8, 2019R&D Budget in FY2019-2019 (average)Cardiovascular & Metabolic Oncology31%27%Vaccine4% 12% 14%12%Respiratory & ImmunologyGeneral Medicine Central Nervous System10| R&D Meeting | January 8, 2019NESINA / SYR-322 (alogliptin)First DPP-4 inhibitor with prospective CV outcome dataCardiovascular & Metabolic Respiratory & Inflammatory Central Nervous System General Medicine Vaccine OncologyProgram Status First DPP-4 inhibitor to have prospective CV outcome data in a high CV risk population (EXAMINE trial) Treatment as monotherapy andin fixed-dose combination with pioglitazone or metformin PDUFA dates of alogliptin and alogliptin/pioglitazone FDC in late January 2019Mechanism of Action A1 1c change fro om baseline at Wk k 260 ‐0.1 ‐0.2 ‐0.3 ‐0.4 ‐0.5 ‐0.6 ‐0.7 ‐0.8 ‐0.9Key Data – Phase 3Incretin (GLP‐1or GIP) deactivated*** ***momo therapy ‐0.02 ‐0.56 ‐0.59************Met add‐on ‐0.1 ‐0.61 ‐0.59****** ******Active sitePlacboSU add‐on 0 ‐0.38 ‐0.52TZD add‐on ‐0.19 ‐0.66 ‐0.8Ins add‐on ‐0.13 ‐0.63 ‐0.71DPP‐4enzyme y*** Pg Alo 12.5mg Alo 25mg11 | R&D Meeting | January 8, 2019ContraveFirst obesity agent with prospective CV outcome dataCardiovascular & Metabolic Respiratory & Inflammatory Central Nervous System General Medicine Vaccine OncologyProgram Status Fixed-dose, sustained-release combination of naltrexone-HCl and bupropion-HCl CV outcome “LIGHT STUDY” underway to meet FDA requirement. The first obesity agent to be supported by prospective cardiovascular outcome data Due to fast enrollment into LIGHT STUDY, accrual of events needed for interim analysis could occur as early as second quarter of calendar 2019. Partnership with Orexigen Therapeutics, Inc.Mechanism of ActionLS Mean % change fro om BLKey Data – Phase 3***p12 | R&D Meeting | January 8, 2019TAK-875First-in-class GPR40 agonist for type 2 diabetesCardiovascular & Metabolic Respiratory & Inflammatory Central Nervous System General Medicine Vaccine OncologyProgram StatusOnce-daily insulin-secretagogue with clear differentiation from competitors: In Phase 2 trials, all doses had a markedly lower incidence of hypoglycemia compared to glimepiride (TAK-875 2.0%, glimepiride 16.1%) Phase 3 studies (including CV outcome study) ongoing in the US, EU & Japan Head to head and concomitant trials with DPP4 inhibitor ongoing Projected launch in FY2019 Mechanism of ActionGl Glucose TAK-875Key Data – Phase 2Change e in HbA1c (% %)0 -0.2 02 -0.4 -0.6 -0.8 -1 -1.2 -1.4K+/ATP Channel GLUT2 GK Mitochondria↑ ATP ↓KX+Insulin Granule ExocytosisGq PLCInsulin Granules DAG PKC*#GPR40 IP3 Free Fatty Acid* **-Cell C ll↑Ca2+ EndoplasmicR ti l Reticulum**Ca2+ Channel * p p# p13 | R&D Meeting | January 8, 2019DAXAS (roflumilast)The first oral drug in new class of treatment for COPDCardiovascular & Metabolic Respiratory & Inflammatory Central Nervous System General Medicine Vaccine OncologyProgram Status Once daily oral selective phosphodiesterase 4 (PDE4) enzyme inhibitor for COPD Approved in the EU for maintenance treatment of severe COPD and currently filed or approved in several emerging markets. Out-licensed to Forest in the US. Clinical POM study ongoing for new combination with alogliptin for type 2 diabetes diabetes.Mechanism of Action IntestineDPP4Key Data - preclinicalCombination of PDE4 inhibitors and DPP4 inhibitors increases active plasma GLP-1 levels (db/db mice)Vehicle PDE4 inhibitor (10 mg/kg) Januvia (100 mg/kg) PDE4 inhibitor + Januvia Mean+SE (n=10)–DPP4‐iPancreasGLP‐1 ↑GLP‐1R↑Insulin+PDE4 – PDE4i AMPcAMP+GLP‐1↑PDE4 – PDE4icAMP+AMPBeta cellsIntestinal L cells14 | R&D Meeting | January 8, 2019BRINTELLIX* / Lu AA21004 (vortioxetine)Novel multimodal antidepressant for major depressive disorderCardiovascular & Metabolic Respiratory & Inflammatory Central Nervous System General Medicine Vaccine OncologyProgram Status The US NDA includes data from 6 global Phase 3 trials (including a study in elderly patients) that demonstrated significant efficacy in dose range of 5 to 20mg/day Potential for favorable short and long term safety and tolerability and improvement of cognitive dysfunction of depression pLower incidence of treatment emergent sexual dysfunction No impact on sleep and weight neutrality Absence of discontinuation symptomsUS NDA filed by y Takeda in October 2019, ,& Japan NDA filing expected in mid-FY2019 Partnership with H. Lundbeck A/SKey Data – Phase 30.7 06 0.6 0.5 0.4 0.3 0.2 0.1 ‐0.1 0.07 DSST RAVLT AcquisitionRAVLT Delayed Recall * 0.25 * * 0.33 0.27 * 0.24 ** 0.32Standardized d Effect Size Ve ersus Placebo PAcute Major Depression in Elderly PatientsVortioxetine Duloxetine*p6E‐16*Proposed brand name of Lu AA2100415 | R&D Meeting | January 8, 2019LurasidoneAtypical antipsychotic for schizophrenia & bipolar depressionCardiovascular & Metabolic Respiratory & Inflammatory Central Nervous System General Medicine Vaccine OncologyProgram Status Demonstrated robust schizophrenia maintenance efficacy in a 52 week study against Seroquel XR (QXR: atypical antipsychotic)27% improved reduction in relapse compared to Seroquel XR p reductionin the risk of hospitalization p compared p to Seroquel q XR 57% improvedLack of significant effects on metabolic parameters including body weight Met primary and key secondary Key Data - Phase 3 endpoints in two phase 3trials in 52 week double-blind extended study y bipolar I depression EU MAA filed by Takeda in September 2019 for schizophrenia Partnership with D i i Dainippon S Sumitomo it Ph PharmaFavorable F16 | R&D Meeting | January 8, 2019MLN0002 (vedolizumab)A precision-based strike on inflammatory bowel diseaseCardiovascular & Metabolic Respiratory & Inflammatory Central Nervous System General Medicine Vaccine OncologyProgram Status A novel class of gut-selective monoclonal antibody targets α4β7 integrin on leukocytes involved in ulcerative colitis (UC) and Crohn’s disease (CD): Phase III UC study GEMINI I met primary endpoints of response (induction) and remission (maintenance) Phase III CD study GEMINI II metprimary endpoints of remission (both induction and maintenance) MLN0002 has demonstrated efficacy in patients who are TNF naïve and those with prior anti-TNF failure in both UC and CDKey Data – Phase 2UCCD17 | R&D Meeting | January 8, 2019TAK-438 (vonoprazan)Longer, g faster, better acid suppression ppCardiovascular & Metabolic Respiratory & Inflammatory Central Nervous System General Medicine Vaccine OncologyProgram Status First-in-class potassium competitive acid blocker (PCAB) More rapid onset of action as compared with a PPI (lansoprazole) High accumulation in parietal cells – potent/prolonged acid suppression No food effect effect, a limitation of PPIs No interaction with CYP2C19 Phase III ongoing in Japan Mechanism of Action Key Data – Phase 1Intragastric pH from MRD Study (comparison with lansoprazole)18 | R&D Meeting | January 8, 2019Acquisition of LigoCyteGains First-in-Class Norovirus Vaccine Candidate & Virus-Like Particle PlatformCardiovascular & Metabolic Respiratory & Inflammatory Central Nervous System General Medicine Vaccine OncologyA major step forward in the expansion of Takeda’s global Vaccine Business Unit En hances Takeda’s R&D capacity with the acquisition of VLP* technology Expands Takeda s development Takeda’s pipeline with first-in-class norovirusvaccine (P-I/II) and pre-clinical assets , influenza and rotavirus for RS virus,19 | R&D Meeting | January 8, 2019*Virus-Like Particles (VLPs) mimic the external protein structure of a virus without including the genetic material (DNA or RNA). The human immune system responds as if encountering e cou te g a live e virus, us, a allowing o g it t to bu build d immune defensesLigoCyte’s norovirus VLP Credit: LigoCyte Ph Pharmaceuticals, ti l Inc. I40| R&D Meeting | January 8, 2019Forward-Looking StatementsThis presentation contains forward-looking statements regarding the Company's plans, outlook, strategies, and results for the future. All forward-looking statements are based on judgments derived from the information available to the Company at this time. Forward looking statements can sometimes be identified by the use of forwardlooking words such as "may," "believe," "will," "expect," "project," "estimate," "should," "anticipate," "plan," "continue," "seek," "pro forma," "potential," "target, " "forecast," or "intend" or other similar words or expressions of the negative thereof thereof. Certain risks and uncertainties could cause the Company's actual results to differ materially from any forward looking statements contained in this presentation. These risks and uncertainties include, but are not limited to, (1) the economic circumstances surrounding the Company's business, including general economic conditions in the US and worldwide; (2) competitive pressures; (3) applicable laws and regulations; (4) the success or failure of product development programs; (5) decisions of regulatory authorities and the timing thereof; (6) changes in exchange rates; (7) claims or concerns regarding the safety or efficacy of marketed products or product candidates; and (8) integration activities with acquired companies companies. We assume no obligation to update or revise any forward-looking statements or other information contained in this presentation, whether as a result of new information, future events, or otherwise.2019/1/10。

高速无砟轨道扭曲不平顺谱统计分析余翠英;向俊;陈涛;龚凯;毛建红【摘要】According to track geometry data measured from Shanghai-Beijing and Harbin-Dalian high-speed railways,the torsion irregularity spectrums of high speed railways were statistically analyzed from the perspective of power spectrum density (PSD),fitting model,simulation parameters and time domain samples.The results show that the characteristics of torsion irregularity of high-speed railway were related to the type of track slab. The simulation results in time domain of torsion irregularities agree well with the measured values as well as the simulation results infrequency domain by selecting the appropriate simulation parameters and fitting model,which can also embody the torsion irregularity character of high-speed railway ballastless track.The simulation ampli-tude of time domain samples will increase with the increasing of percentile spectrum of torsion irregularity.There-by,it can be concluded that the influence of torsion irregularity researched on high-speed train as well as track structure should based on different percentile spectrum of torsion irregularity,which was provided as the excitingvibration source for vibration analysis of high-speed train and bridge (track)time-variant system on the basis of different geometrical states of high-speed railway.%基于京沪和哈大高速铁路轨道不平顺实测数据，从扭曲不平顺功率谱密度，拟合模型和拟合参数以及时域样本角度，对高速铁路扭曲不平顺谱进行统计分析。

蛇毒血凝酶注射液对老年外科止血的临床效果探讨朱延安;金剑英;张法标;张浩【摘要】Objective To explore and evaluate the hemostatic effects of hemocoagulase in elderly surgery bleeding. Methods 150 cases (60~75 years old)admitted to Affiliated Hospital of Chuanbei Medical College for abdominal operation from June 2011 to June 2012 were used as subject. They were divided radomly into hemocoagulase group (50 cases),reptilase group (50 cases)and physiological saline solution group (50 cases). The hemostatic time,hemorrhagic volume,hemorrhagic volume per square unit,and body coagulation parameters in three groups were observed and compared. Results The hemorrhagic volume in hemocoagulase group was (9.2 ±2.7 )g,average hemostatic time was (124.5 ±45.7 )s,and hemorrhagic volume per square unit was (0.3 ±0.1 )g,which were similar with reptilase group,but significantly different with those in physiological saline solution group (P<0.05 ). In hemocoagulase and reptilase groups,the hemorrhagic and hemoagglution time decreased in 30 minutes and 1 day after operation, the differences were statistically significant when comparedwith physiological saline solution group (P <0.05 ).Conclusion Hemocoagulase has better hemostatic effect on hemorrhagic capillary in elderly surgery.%目的：探讨蛇毒血凝酶注射液对老年人外科止血的效果及评价。