LM6364MX中文资料

LM6164/LM6264/LM6364High Speed Operational AmplifierGeneral DescriptionThe LM6164family of high-speed amplifiers exhibits an ex-cellent speed-power product in delivering 300V per µs and 175MHz GBW (stable down to gains as low as +5)with only 5mA of supply current.Further power savings and applica-tion convenience are possible by taking advantage of the wide dynamic range in operating supply voltage which ex-tends all the way down to +5V.These amplifiers are built with National’s VIP ™(Vertically In-tegrated PNP)process which produces fast PNP transistors that are true complements to the already fast NPN devices.This advanced junction-isolated process delivers high speed performance without the need for complex and expensive di-electric isolation.Featuresn High slew rate:300V/µs n High GBW product:175MHz n Low supply current:5mA n Fast settling:100ns to 0.1%n Low differential gain:<0.1%n Low differential phase:<0.1˚n Wide supply range: 4.75V to 32V nStable with unlimited capacitive loadApplicationsn Video amplifiern Wide-bandwidth signal conditioning n Radar nSonarConnection DiagramsVIP ™is a trademark of National Semiconductor Corporation.DS009153-8NS Package Number J08A,M08A or N08E10-Lead FlatpakDS009153-15Top ViewNS Package Number W10AMay 1999LM6164/LM6264/LM6364High Speed Operational Amplifier©1999National Semiconductor Corporation Connection Diagrams(Continued)Temperature Range Package NSCDrawing Military Industrial Commercial−55˚C≤T A≤+125˚C−25˚C≤T A≤+85˚C0˚C≤T A≤+70˚CLM6264N LM6364N8-Pin Molded DIP N08E LM6164J/8838-Pin Ceramic DIP J08A5962-8962401PALM6364M8-Pin Molded Surface Mt.M08A LM6164WG/88310-Lead Ceramic SOIC WG10A 5962-8962401XALM6164W/88310-Pin W10A5962-8962401HA Ceramic Flatpak2Absolute Maximum Ratings(Note1)If Military/Aerospace specified devices are required, please contact the National Semiconductor Sales Office/ Distributors for availability and specifications.Supply Voltage(V+−V−)36V Differential Input Voltage(Note7)±8V Common-Mode Input Voltage(Note11)(V+−0.7V)to(V−+0.7V) Output Short Circuit to Gnd(Note2)Continuous Soldering InformationDual-In-Line Package(N,J)Soldering(10sec.)260˚C Small Outline Package(M)Vapor Phase(60sec.)215˚C Infrared(15sec.)220˚CSee AN-450“Surface Mounting Methods and Their Effect on Product Reliability”for other methods of soldering surface mount devices.Storage Temperature Range−65˚C to+150˚C Max Junction Temperature(Note3)150˚C ESD Tolerance(Notes7,8)±700V Operating RatingsTemperature Range(Note3)LM6164−55˚C≤T J≤+125˚C LM6264−25˚C≤T J≤+85˚C LM63640˚C≤T J≤+70˚C Supply Voltage Range 4.75V to32V Note1:“Absolute Maximum Ratings”indicate limits beyond which damage to the device may occur.Operating Ratings indicate conditions for which the device is functional,but do not guarantee specific performance limits.DC Electrical CharacteristicsThe following specifications apply for Supply Voltage=±15V,V CM=0,R L≥100kΩand R S=50Ωunless otherwise noted. Boldface limits apply for T A=T J=T MIN to T MAX;all other limits T A=T J=25˚C.LM6164LM6264LM6364Symbol Parameter Conditions Typ Limit Limit Limit Units(Notes4,12)(Note4)(Note4)V OS Input Offset Voltage2449mV6611maxV OS Input Offset Voltage6µV/˚C Drift Average DriftI b Input Bias Current 2.5335µA656maxI OS Input Offset Current1503503501500nA8006001900maxI OS Input Offset Current0.3nA/˚C Drift Average DriftR IN Input Resistance Differential100kΩC IN Input Capacitance 3.0pFA VOL Large Signal V OUT=±10V,R L=2kΩ 2.5 1.8 1.8 1.3V/mVVoltage Gain(Note10)0.9 1.2 1.1minR L=10kΩ9V CM Input Common-Mode Supply=±15V+14.0+13.9+13.9+13.8V Voltage Range+13.8+13.8+13.7min−13.5−13.3−13.3−13.2V−13.1−13.1−13.1minSupply=+5V 4.0 3.9 3.9 3.8V(Note5) 3.8 3.8 3.7min1.5 1.7 1.7 1.8V1.9 1.9 1.9max CMRR Common-Mode−10V≤V CM≤+10V105868680dB Rejection Ratio808278min PSRR Power Supply±10V≤V±≤±16V96868680dB Rejection Ratio808278min3DC Electrical Characteristics(Continued)The following specifications apply for Supply Voltage=±15V,V CM=0,R L≥100kΩand R S=50Ωunless otherwise noted.Boldface limits apply for T A=T J=T MIN to T MAX;all other limits T A=T J=25˚C.LM6164LM6264LM6364Symbol Parameter Conditions Typ Limit Limit Limit Units(Notes4,12)(Note4)(Note4)V O Output Voltage Supply=+5V+14.2+13.5+13.5+13.4V Swing and R L=2kΩ+13.3+13.3+13.3min−13.4−13.0−13.0−12.9V−12.7−12.8−12.8minSupply=+5V 4.2 3.5 3.5 3.4Vand R L=2kΩ 3.3 3.3 3.3min(Note10) 1.3 1.7 1.7 1.8V2.0 1.9 1.9maxOutput Short Source65303030mA Circuit Current202525minSink65303030mA202525minI S Supply Current 5.0 6.5 6.5 6.8mA6.8 6.7 6.9min AC Electrical CharacteristicsThe following specifications apply for Supply Voltage=±15V,V CM=0,R L≥100kΩand R S=50Ωunless otherwise noted.Boldface limits apply for T A=T J=T MIN to T MAX;all other limits T A=T J=25˚C.LM6164LM6264LM6364Symbol Parameter Conditions Typ Limit Limit Limit Units(Notes4,12)(Note4)(Note4)GBW Gain-Bandwidth F=20MHz175140140120MHzmin Product100120100Supply=±5V120SR Slew Rate A V=+5(Note9)300200200200V/µsmin180180180Supply=±5V200PBW Power Bandwidth V OUT=20V PP 4.5MHzT S Settling Time10V Step to0.1%100nsA V=−4,R L=2kΩφm Phase Margin A V=+545DegA D Differential Gain NTSC,A V=+10<0.1%φD Differential Phase NTSC,A V=+10<0.1Dege np-p Input Noise F=10kHz8Voltagei np-p Input Noise F=10kHz 1.5CurrentNote2:Continuous short-circuit operation at elevated ambient temperature can result in exceeding the maximum allowed junction temperature of150˚C.Note3:The typical junction-to-ambient thermal resistance of the molded plastic DIP(N)is105˚C/Watt,the molded plastic SO(M)package is155˚C/Watt,and the cerdip(J)package is125˚C/Watt.All numbers apply for packages soldered directly into a printed circuit board.Note4:Limits are guaranteed by testing or correlation.Note5:For single supply operation,the following conditions apply:V+=5V,V−=0V,V CM=2.5V,V OUT=2.5V.Pin1&Pin8(V OS Adjust)are each connected to Pin4(V−)to realize maximum output swing.This connection will degrade V OS.Note6:C L≤5pF.Note7:In order to achieve optimum AC performance,the input stage was designed without protective clamps.Exceeding the maximum differential input voltage re-sults in reverse breakdown of the base-emitter junction of one of the input transistors and probable degradation of the input parameters(especially V OS,I OS,and Noise).Note8:The average voltage that the weakest pin combinations(those involving Pin2or Pin3)can withstand and still conform to the datasheet limits.The test circuit used consists of the human body model of100pF in series with1500Ω.4AC Electrical Characteristics(Continued)Note9:V IN=4V step.For supply=±5V,V IN=1V step.Note10:Voltage Gain is the total output swing(20V)divided by the input signal required to produce that swing.Note11:The voltage between V+and either input pin must not exceed36V.Note12:A military RETS electrical test specification is available on request.At the time of printing,the LM6164J/883RETS spec complied with the Boldface limits in this column.The LM6164J/883may also be procured as Standard Military Drawing#5962-8962401PA.Typical Performance Characteristics(RL =10kΩ,TA=25˚C unless otherwise specified)Supply Current vsSupply VoltageDS009153-16Common-ModeRejection RatioDS009153-17Power SupplyRejection RatioDS009153-18Gain-BandwidthProductDS009153-19Propagation DelayRise and Fall TimeDS009153-20Gain-Bandwidth Productvs Load CapacitanceDS009153-21Slew Rate vsLoad CapacitanceDS009153-22Overshoot vsLoad CapacitanceDS009153-23Slew RateDS009153-24 5Typical Performance Characteristics(R L =10k Ω,T A =25˚C unless otherwisespecified)(Continued)Voltage Gain vs Load ResistanceDS009153-25Gain vs Supply VoltageDS009153-26Differential Gain (Note 13)DS009153-6Differential Phase (Note 13)DS009153-7Note 13:Differential gain and differential phase measured for four series LM6364op amps in series with an LM6321buffer.Error added by LM6321is negligible.Test performed using Tektronix Type 520NTSC test system.Configured with a gain of +5(each output attenuated by 80%)Step Response;Av =+5TIME (50 ns /div)I n p u t (1v /d i v ) O u t p u t (5v /d i v )DS009153-1 6Typical Performance Characteristics(RL =10kΩ,TA=25˚C unless otherwisespecified)(Continued)Input Noise VoltageDS009153-27Input Noise CurrentDS009153-28Power BandwidthDS009153-29Open-LoopFrequency ResponseDS009153-30Open-LoopFrequency ResponseDS009153-31Output ResistanceOpen-LoopDS009153-32Common-Mode InputSaturation VoltageDS009153-33Output Saturation VoltageDS009153-34Bias Current vsCommon-Mode VoltageDS009153-35 7Simplified Schematic Applications TipsThe LM6364has been compensated for gains of5or greater (over specified ranges of temperature,power supply voltage, and load).Since this compensation involved adding emitter-degeneration resistors in the op amp’s input stage, the open-loop gain was reduced as the stability increased. Gain error due to reduced A VOL is most apparent at high gains;thus,the uncompensated LM6365is appropriate for gains of25or more.If unity-gain operation is desired,the LM6361should be used.The LM6361,LM6364,and LM6365have the same high slew rate(typically300V/µs), regardless of their compensation.The LM6364is unusually tolerant of capacitive loads.Most op amps tend to oscillate when their load capacitance is greater than about200pF(in low-gain circuits).However, load capacitance on the LM6364effectively increases its compensation capacitance,thus slowing the op amp’s re-sponse and reducing its bandwidth.The compensation is not ideal,though,and ringing or oscillation may occur in low-gain circuits with large capacitive loads.To overcompen-sate the LM6364for operation at gains less than5,a series resistor-capacitor network should be added between the in-put pins(as shown in the Typical Applications,Noise Gain Compensation)so that the high-frequency noise gain rises to at least5.Power supply bypassing will improve the stability and tran-sient response of the LM6364,and is recommended for ev-ery design.0.01µF to0.1µF ceramic capacitors should be used(from each supply“rail”to ground);if the device is far away from its power supply source,an additional2.2µF to 10µF(tantalum)may be required for extra noise reduction. Keep all leads short to reduce stray capacitance and lead in-ductance,and make sure ground paths are low-impedance, especially where heavier currents will be flowing.Stray ca-pacitance in the circuit layout can cause signal coupling be-tween adjacent nodes,so that circuit gain unintentionally varies with frequency.Breadboarded circuits will work best if they are built using generic PC boards with a good ground plane.If the op amps are used with sockets,as opposed to being soldered into the circuit,the additional input capacitance may degrade circuit performance.DS009153-38Typical ApplicationsOffset Voltage AdjustmentDS009153-10Video-Bandwidth AmplifierDS009153-12Noise-Gain Compensation for Gains ≤5DS009153-11R X C X ≥(2π•25MHz)−15R X =R 1+R F (1+R 1/R 2)9Physical Dimensions inches(millimeters)unless otherwise notedCeramic Dual-In-Line Package(J)Order Number LM6164J/883NS Package Number J08AMolded Package SO(M)Order Number LM6364MNS Package Number M08A 10Physical Dimensions inches(millimeters)unless otherwise noted(Continued)Molded Dual-In-Line Package(N)Order Number LM6264N or LM6364NNS Package Number N08E10-Pin Ceramic FlatpakOrder Number LM6164W/883NS Package Number W10A11NotesLIFE SUPPORT POLICYNATIONAL’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT AND GENERAL COUNSEL OF NATIONAL SEMICONDUCTOR CORPORATION.As used herein:1.Life support devices or systems are devices or systems which,(a)are intended for surgical implant into the body,or (b)support or sustain life,and whose failure to perform when properly used in accordance with instructions for use provided in the labeling,can be reasonably expected to result in a significant injury to the user.2.A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system,or to affect its safety or effectiveness.National Semiconductor Corporation AmericasTel:1-800-272-9959Fax:1-800-737-7018Email:support@National Semiconductor EuropeFax:+49(0)180-5308586Email:europe.support@Deutsch Tel:+49(0)180-5308585English Tel:+49(0)180-5327832Français Tel:+49(0)180-5329358Italiano Tel:+49(0)180-5341680National Semiconductor Asia Pacific Customer Response Group Tel:65-2544466Fax:65-2504466Email:sea.support@National Semiconductor Japan Ltd.Tel:81-3-5639-7560Fax:81-3-5639-7507L M 6164/L M 6264/L M 6364H i g h S p e e d O p e r a t i o n a l A m p l i f i e rNational does not assume any responsibility for use of any circuitry described,no circuit patent licenses are implied and National reserves the right at any time without notice to change said circuitry and specifications.。

6N134中⽂资料FeaturesDual Marked with Device Part Number and DSCC Drawing NumberManufactured and Tested on a MIL-PRF-38534 Certified LineQML-38534, Class H and K Five Hermetically Sealed Package Configurations Performance Guaranteed over -55°C to +125°C ? High Speed: 10 M Bit/sCMR: > 10,000 V/µs Typical 1500 Vdc Withstand Test Voltage2500 Vdc Withstand Test Voltage for HCPL-565X High Radiation Immunity 6N137, HCPL-2601, HCPL-2630/-31 Function Compatibility ? Reliability DataTTL Circuit CompatibilityApplicationsMilitary and SpaceHigh Reliability SystemsTransportation, Medical, and Life Critical SystemsLine ReceiverVoltage Level ShiftingIsolated Input Line Receiver Isolated Output Line Driver Logic Ground Isolation Harsh Industrial EnvironmentsIsolation for Computer,Communication, and Test Equipment SystemsDescriptionThese units are single, dual and quad channel, hermetically sealed optocouplers. The products are capable of operation and storage over the full military temperature range and can be purchased as either standard product or with full MIL-PRF-38534 Class Level H or K testing or from the appropri-ate DSCC Drawing. All devices are manufactured and tested on a MIL-PRF-38534 certified line and are included in the DSCC Quali-fied Manufacturers List QML-38534 for Hybrid Microcircuits.Quad channel devices areavailable by special order in the 16 pin DIP through hole packages.Truth Table(Positive Logic)Multichannel DevicesInput Output On (H)L Off (L)HFunctional DiagramMultiple Channel Devices AvailableSingle Channel DIP Input Enable Output On (H)H L Off (L)H H On (H)L H Off (L)LH*See matrix for available extensions.Hermetically Sealed, High Speed,High CMR, Logic Gate Optocouplers Technical Data6N134*81028HCPL-563X HCPL-663X HCPL-565X 5962-98001HCPL-268K HCPL-665X 5962-90855HCPL-560XCAUTION: It is advised that normal static precautions be taken in handling and assembly of this component to prevent damage and/or degradation which may be induced by ESD.V CC V OUTV E GNDThe connection of a 0.1 µF bypass capacitor between V CC and GND is recommended.Selection Guide–Package Styles and Lead Configuration OptionsPackage16 Pin DIP 8 Pin DIP 8 Pin DIP 8 Pin DIP 16 Pin Flat Pack 20 Pad LCCC Lead Style Through Hole Through Hole Through Hole Through Hole Unformed Leads Surface MountChannels 212242Common Channel V CC , GND None V CC , GND V CC , GND V CC , GND None WiringWithstand Test Voltage 1500 Vdc 1500 Vdc 1500 Vdc 2500 Vdc 1500 Vdc 1500 Vdc Agilent Part # & Options Commercial6N134*HCPL-5600HCPL-5630HCPL-5650HCPL-6650HCPL-6630MIL-PRF-38534, Class H 6N134/883BHCPL-5601HCPL-5631HCPL-5651HCPL-6651HCPL-6631MIL-PRF-38534, Class K HCPL-268K HCPL-560K HCPL-563K HCPL-665K HCPL-663K Standard Lead Finish Gold Plate Gold Plate Gold Plate Gold Plate Gold PlateSolder PadsSolder Dipped Option #200Option #200Option #200Option #200Butt Cut/Gold Plate Option #100Option #100Option #100Gull Wing/Soldered Option #300Option #300Option #300Class H SMD Part #Prescript for all below None 5962-None None None None Either Gold or Solder 8102801EX 9085501HPX 8102802PX 8102805PX 8102804FX 81028032XGold Plate 8102801EC 9085501HPC 8102802PC 8102805PC 8102804FCSolder Dipped 8102801EA 9085501HPA 8102802PA 8102805PA81028032A Butt Cut/Gold Plate 8102801UC 9085501HYC 8102802YC Butt Cut/Soldered 8102801UA 9085501HYA 8102802YA Gull Wing/Soldered 8102801TA 9085501HXA8102802ZA Class K SMD Part #Prescript for all below 5962-5962-5962-5962-5962-Either Gold or Solder 9800101KEX 9085501KPX 9800102KPX 9800104KFX 9800103K2XGold Plate 9800101KEC 9085501KPC 9800102KPC 9800104KFCSolder Dipped 9800101KEA 9085501KPA 9800102KPA 9800103K2AButt Cut/Gold Plate 9800101KUC 9085501KYC 9800102KYC Butt Cut/Soldered 9800101KUA 9085501KYA 9800102KYA Gull Wing/Soldered9800101KTA 9085501KXA 9800102KZA*JEDEC registered part.Each channel contains a GaAsP light emitting diode which isoptically coupled to an integrated high speed photon detector. The output of the detector is an open collector Schottky clamped transistor. Internal shields provide a guaranteed common mode transient immunityspecification of 1000 V/µs. For Isolation Voltage applications requiring up to 2500 Vdc, the HCPL-5650 family is also available. Package styles for these parts are 8 and 16 pin DIP through hole (case outlines P andE respectively), and 16 pin surface mount DIP flat pack(case outline F), leadless ceramic chip carrier (case outline 2).Devices may be purchased with a variety of lead bend and plating options. See Selection Guide Table for details. Standard Microcircuit Drawing (SMD)parts are available for each package and lead style.Because the same electrical die (emitters and detectors) are used for each channel of each device listed in this data sheet, absolute maximum ratings, recommended operating conditions, electrical specifications, and performance characteristics shown in the figures are identical for all parts.Occasional exceptions exist due to package variations and limitations,and are as noted. Additionally, the same package assembly processes and materials are used in all devices. These similarities give justification for the use of data obtained from one part torepresent other parts’ performance for reliability and certain limited radiation test results.Outline Drawings16 Pin DIP Through Hole, 2 ChannelsFunctional DiagramsNote: All DIP and flat pack devices have common V CC and ground. Single channel DIP has an enable pin 7. LCCC (leadless ceramic chip carrier) package has isolated channels with separate VCC and ground connections. All diagrams are “top view.”Leaded Device MarkingLeadless Device MarkingNOTE: DIMENSIONS IN MILLIMETERS (INCHES).COMPLIANCE INDICATOR,*DATE CODE, SUFFIX (IF NEEDED)COUNTRY OF MFR.Agilent CAGE CODE*Agilent DESIGNATORDSCC SMD*PIN ONE/ ESD IDENTAgilent P/N DSCC SMD** QUALIFIED PARTS ONLYCOMPLIANCE INDICATOR,*DATE CODE, SUFFIX (IF NEEDED)DSCC SMD*Agilent CAGE CODE*Agilent DESIGNATORCOUNTRY OF MFR.Agilent P/N PIN ONE/ ESD IDENTDSCC SMD** QUALIFIED PARTS ONLYOutline Drawings (continued)16 Pin Flat Pack, 4 Channels8 Pin DIP Through Hole, 2 Channels 2500 Vdc Withstand Test Voltage20 Terminal LCCC Surface Mount,2Channels8 Pin DIP Through Hole, 1 and 2 Channels0.36 (0.014)NOTE: DIMENSIONS IN MILLIMETERS (INCHES).2.29 (0.090) 2.79 (0.110)NOTE: DIMENSIONS IN MILLIMETERS (INCHES).NOTE: DIMENSIONS IN MILLIMETERS (INCHES).NOTE: DIMENSIONS IN MILLIMETERS (INCHES). SOLDER THICKNESS 0.127 (0.005) MAX.Hermetic Optocoupler OptionsRecommended Operating ConditionsParameterSymbol Min.Max.Units Input Current, Low Level, Each Channel I FL 0250µA Input Current, High Level, Each Channel*I FH 1020mA Supply Voltage, OutputV CC 4.55.5VFan Out (TTL Load) Each ChannelN6*Meets or exceeds DSCC SMD and JEDEC requirements.Absolute Maximum Ratings(No derating required up to +125°C)Storage Temperature Range, T S ...................................-65°C to +150°C Operating Temperature, T A..........................................-55°C to +125°C Case Temperature, T C ................................................................+170°C Junction Temperature, T J ...........................................................+175°C Lead Solder Temperature ...............................................260°C for 10 s Peak Forward Input Current, I F PK , (each channel,≤1 ms duration)......................................................................40 mA Average Input Forward Current, I F AVG (each channel)................20 mA Input Power Dissipation (each channel).....................................35 mW Reverse Input Voltage, V R (each channel).........................................5 V Supply Voltage, V CC (1 minute maximum)........................................7 V Output Current, I O (each channel)...............................................25 mA Output Power Dissipation (each channel). (40)mW Output Voltage, V O (each channel)..................................................7 V*Package Power Dissipation, P D (each channel)........................200 mW*Selection for higher output voltages up to 20 V is available.Single Channel Product OnlyEmitter Input Voltage, V E ...............................................................5.5 VNote enable pin 7. An external 0.01 µF to 0.1 µF bypass capacitor must be connected between V CC and ground for each package type.8 Pin Ceramic DIP Single Channel SchematicESD Classification(MIL-STD-883, Method 3015)HCPL-5600/01/0K ...............................................................(?), Class 16N134, 6N134/883B, HCPL-5630/31/3K, HCPL-5650/51, HCPL-6630/31/3K and HCPL-6650/51/5K.......................(Dot), Class 3Electrical Characteristics (T= -55°C to +125°C, unless otherwise specified)*Identified test parameters for JEDEC registered parts.**All typical values are at V CC = 5 V , T A = 25°C. Recommended Operating Conditions (cont’d.)Single Channel Product Only [10]ParameterSymbol Min.Max.Units High Level Enable Voltage V EH 2.0V CC V Low Level Enable VoltageV EL0.8VElectrical Characteristics, (Contd.) T= -55°C to +125°C unless otherwise specifiedSingle Channel Product Only Low Level I EL V CC = 5.5 V,1, 2, 3-1.45-2.0mA Enable Current V E = 0.5 V High Level V EH 1, 2, 3 2.0V10Enable Voltage Low Level V EL 1, 2, 30.8VEnable Voltage*Identified test parameters for JEDEC registered part.**All typical values are at V CC = 5 V , T A = 25°C.Typical Characteristics, T = 25°C, V = 5 VDual and Quad Channel Product Only Input-Input I I-I 0.5nA Relative Humidity = 45%4Leakage CurrentV I-I = 500 V, t = 5 s Resistance (Input-Input)R I-I 1012V I-I = 500 V 4Capacitance (Input-Input)C I-I0.55pF f = 1 MHz4Notes:1. Each channel.2. All devices are considered two-terminal devices; I I-O is measured between all input leads or terminals shorted together and alloutput leads or terminals shorted together.3. Measured between each input pair shorted together and all output connections for that channel shorted together.4. Measured between adjacent input pairs shorted together for each multichannel device.5. t PHL propagation delay is measured from the 50% point on the leading edge of the input pulse to the 1.5 V point on the leadingedge of the output pulse. The t PLH propagation delay is measured from the 50% point on the trailing edge of the input pulse to the1.5 V point on the trailing edge of the output pulse.6. The HCPL-6630, HCPL-6631, and HCPL-663K dual channel parts function as two independent single channel units. Use the singlechannel parameter limits for each channel.7. CM L is the maximum rate of rise of the common mode voltage that can be sustained with the output voltage in the logic low state(V O < 0.8 V). CM H is the maximum rate of fall of the common mode voltage that can be sustained with the output voltage in the logic high state (V O > 2.0 V).8. This is a momentary withstand test, not an operating condition.9. It is essential that a bypass capacitor (0.01 to 0.1 µF, ceramic) be connected from V CC to ground. Total lead length between bothends of this external capacitor and the isolator connections should not exceed 20 mm.10. No external pull up is required for a high logic state on the enable input.11. The t ELH enable propagation delay is measured from the 1.5 V point on the trailing edge of the enable input pulse to the 1.5 Vpoint on the trailing edge of the output pulse.12. The t EHL enable propagation delay is measured from the 1.5 V point on the leading edge of the enable input pulse tothe 1.5 Vpoint on the leading edge of the output pulse.13. Standard parts receive 100% testing at 25°C (Subgroups 1 and 9). SMD and 883B parts receive 100% testing at 25, 125, and-55°C (Subgroups 1 and 9, 2 and 10, 3 and 11, respectively).14. Parameters are tested as part of device initial characterization and after design and process changes. Parameters are guaranteedto limits specified for all lots not specifically tested.15. Not required for 6N134, 6N134/883B, 8102801, HCPL-268K and 5962-9800101 types.16. Required for 6N134, 6N134/883B, 8102801, HCPL-268K and 5962-9800101 types.17. Not required for HCPL-5650, HCPL-5651 and 8102805 types.18. Required for HCPL-5650, HCPL-5651 and 8102805 types only.Figure 1. High Level Output Currentvs. Temperature.5 VV O * C L INCLUDES PROBE AND STRAY WIRING CAPACITANCE. Figure 4. Test Circuit for t PHL and t PLH .*I +5 V OUTPUT V O MONITORING NODEFigure 7. Test Circuit for Common Mode Transient Immunity and Typical Waveforms.11OUTPUT V OMONITORINGNODET A = +125 °C* ALL CHANNELS TESTED SIMULTANEOUSLY.V CCI O = 25 mAFigure 10. Operating Circuit for Burn-In and Steady State Life Tests. Figure 8. Test Circuit for t EHL and t ELH.Figure 9. Enable Propagation Delayvs. Temperature.MIL-PRF-38534 Class H,Class K, and DSCC SMDTest ProgramAgilent’s Hi-Rel Optocouplers arein compliance with MIL-PRF-38534 Classes H and K. Class Hand Class K devices are also incompliance with DSCC drawings81028, 5962-90855 and 5962-98001.Testing consists of 100% screen-ing and quality conformanceinspection to MIL-PRF-38534./doc/4e2d970a03d8ce2f006623a8.htmlData subject to change.Copyright ? 1999 Agilent TechnologiesObsoletes 5968-4743E5968-9407E (10/00)。

MXview SeriesIndustrial network management software designed for converged automation networks, supports an optional wireless add-on moduleFeatures and Benefits•Discovers and visualizes network devices and physical connectionsautomatically•Central management of configurations and firmware for Moxa devices•Multiple options for events and notifications with self-defined threshold andduration•Comprehensive reports,including inventory,traffic,and availability reports•Provides RESTful API and web widget to embed MXview into industrialapplications•Supports third-party Ethernet switches through SNMP MIB files•Generates OPC2.0compliant tags automatically to integrate with SCADA/HMI applications•Dynamic topology view shows the status of wireless links and connectionchanges at a glance1•Visual,interactive roaming playback function to review the roaming history ofclients1•Detailed device information and performance indicator charts for individualAP and client devices1IntroductionMoxa’s MXview network management software is designed for configuring,monitoring,and diagnosing networking devices in industrial networks. MXview provides an integrated management platform that can discover networking devices and SNMP/IP devices installed on subnets.All selected network components can be managed via a web browser from both local and remote sites—anytime and anywhere.In addition,MXview supports the optional MXview Wireless add-on module1.MXview Wireless provides additional advanced functions for wireless applications to monitor and troubleshoot your network,and help you minimize downtime.Experience1Year of MXview Wireless For FreeFrom now until Dec31,2021,you can try the MXview Wireless module for free for one year by simply activating the MXview Wireless add-on promotional license for your MXview instance.2Download the Promotional License Activation Guide at /wirelessguide.1.This feature requires the MXview Wireless add-on license(LIC-MXview-ADD-WIRELESS-MR),which can be purchased separately.An active MXview license isrequired in order to activate the add-on license.2.The1–year promotional license term begins the moment the license is activated.If you wish to continue using MXview Wireless after the promotional license hasexpired,you will need to purchase the MXview Wireless add-on perpetual license(LIC-MXview-ADD-WIRELESS-MR).Visualization•Discovers up to2,000Moxa devices and SNMP/ICMP devices within scan range•Visualization of redundant link status and device roles of network redundancy protocols•Visualization of graphic VLAN groups•Security view for the security status of network devices with industrial security standard•Displays third-party device icons•A network management dashboard to view the network status quickly •Visualization of network traffic loading with color-coded links •Device front panel visualization,including ports and LED indicators •Visualization of managed PoE device power consumption •Wireless device dashboard that shows dynamic AP-client relationships and performance indicator charts for wireless devices3•Roaming playback to review a client's roaming status33.This feature requires the MXview Wireless add-on license(LIC-MXview-ADD-WIRELESS-MR),which can be purchased separately.An active MXview license isrequired in order to activate the add-on license.Network Diagnostics and Event Notification•Detect problems in real-time with SNMP trap/inform,or periodic polling•Generate trend graphs to track bandwidth utilization and error packet rate statistics,accurate to four decimal places•Supports Syslog server for centralized message management •Configurable event notification alarms sent through email,Microsoft Teams,Slack,MXview ToGo.and SNMP trap,or locally through program notification,message box,and audio alerts•Multiple options for events and notifications with self-defined threshold and duration •Generate OPC2.0compliant tags automatically to integrate with SCADA/HMI applications•Group health OPC tag represents entire network status•Real-time device availability monitoring•Supports third-party Ethernet switches through MIB files •Collaborate with third-party NMS through SNMP traps•Provides RESTful API and web widget for integrating MXview into the existing systemComprehensive Reports•Maintain device availability reports and record for up to90days •Generate an inventory report for each device on the network •Compile comprehensive device properties report •Generate network traffic trend reportsCentralized Configuration and Firmware Management•Bulk deployment of device configurations and firmware •In one click,back up the entire MXview database,including topology,job scheduling,events,and device properties •Scheduling for periodic configuration backup•Save history of configuration changes•Comparison tool for checking differences between2configurationsMobile App for Network Monitoring•MXview ToGo mobile app for remote monitoring andnotification—anytime,anywhere•Smart Device Identification with QR Code enhances operationalefficiency•Device Locator with mobile app reduces searching time at fieldsitesSpecificationsHardware RequirementsCPU2GHz or faster dual-core CPU RAM8GB or higherHardware Disk Space MXview only:10GBWith MXview Wireless module:20to30GB4OS Windows7Service Pack1(64-bit)Windows10(64-bit)Windows Server2012R2(64-bit)Windows Server2016(64-bit)Windows Server2019(64-bit)ManagementSupported Interfaces SNMPv1/v2c/v3and ICMPSupported DevicesAWK Products AWK-1121Series(v1.4or higher)AWK-1127Series(v1.4or higher)AWK-1131A Series(v1.11or higher)AWK-1137C Series(v1.1or higher)AWK-3121Series(v1.6or higher)AWK-3131Series(v1.1or higher)AWK-3131A Series(v1.3or higher)AWK-3131A-M12-RTG Series(v1.8or higher)AWK-4121Series(v1.6or higher)AWK-4131Series(v1.1or higher)AWK-4131A Series(v1.3or higher)DA Products DA-820C Series(v1.0or higher)DA-682C Series(v1.0or higher)DA-681C Series(v1.0or higher)DA-720Series(v1.0or higher)EDR Products EDR-G903Series(v2.1or higher)EDR-G902Series(v1.0or higher)EDR-810Series(v3.2or higher)EDR-G9010Series(v1.0or higher)EDS Products EDS-405A/408A Series(v2.6or higher)EDS-405A/408A-EIP Series(v3.0or higher)EDS-405A/408A-PN Series(v3.1or higher)EDS-405A-PTP Series(v3.3or higher)EDS-505A/508A/516A Series(v2.6or higher)EDS-510A Series(v2.6or higher)EDS-518A Series(v2.6or higher)EDS-510E/518E Series(v4.0or higher)EDS-528E Series(v5.0or higher)EDS-G508E/G512E/G516E Series(v4.0or higher)EDS-G512E-8PoE Series(v4.0or higher)EDS-608/611/616/619Series(v1.1or higher)EDS-728Series(v2.6or higher)EDS-828Series(v2.6or higher)EDS-G509Series(v2.6or higher)EDS-P510Series(v2.6or higher)EDS-P510A-8PoE Series(v3.1or higher)EDS-P506A-4PoE Series(v2.6or higher)EDS-P506Series(v5.5or higher)EOM Products EOM-104/104-FO Series(v1.2or higher)ICS Products ICS-G7526/G7528Series(v1.0or higher)ICS-G7826/G7828Series(v1.1or higher)ICS-G7748/G7750/G7752Series(v1.2or higher)ICS-G7848/G7850/G7852Series(v1.2or higher)ICS-G7526A/G7528A Series(v4.0or higher)ICS-G7826A/G7828A Series(v4.0or higher)ICS-G7748A/G7750A/G7752A Series(v4.0or higher)ICS-G7848A/G7850A/G7852A Series(v4.0or higher) IEX Products IEX-402-SHDSL Series(v1.0or higher)IEX-402-VDSL2Series(v1.0or higher)4.Recommended amount to store1month of performance and event history.IEX-408E-2VDSL2Series(v4.0or higher)IKS Products IKS-6726/6728Series(v2.6or higher)IKS-6524/6526Series(v2.6or higher)IKS-G6524Series(v1.0or higher)IKS-G6824Series(v1.1or higher)IKS-6728-8PoE Series(v3.1or higher)IKS-6726A/6728A Series(v4.0or higher)IKS-G6524A Series(v4.0or higher)IKS-G6824A Series(v4.0or higher)IKS-6728A-8PoE Series(v4.0or higher)ioLogik Products ioLogik E2210Series(v3.7or higher)ioLogik E2212Series(v3.7or higher)ioLogik E2214Series(v3.7or higher)ioLogik E2240Series(v3.7or higher)ioLogik E2242Series(v3.7or higher)ioLogik E2260Series(v3.7or higher)ioLogik E2262Series(v3.7or higher)ioLogik W5312Series(v1.7or higher)ioLogik W5340Series(v1.8or higher)ioThinx Products ioThinx4510Series(v1.3or higher)MC Products MC-7400Series(v1.0or higher)MDS Products MDS-G4012Series(v1.0or higher)MDS-G4020Series(v1.0or higher)MDS-G4028Series(v1.0or higher)MDS-G4012-L3Series(v2.0or higher)MDS-G4020-L3Series(v2.0or higher)MDS-G4028-L3Series(v2.0or higher)MGate Products MGate MB3170/MB3270Series(v4.2or higher)MGate MB3180Series(v2.2or higher)MGate MB3280Series(v4.1or higher)MGate MB3480Series(v3.2or higher)MGate MB3660Series(v2.5or higher)MGate5101-PBM-MN Series(v2.2or higher)MGate5102-PBM-PN Series(v2.3or higher)MGate5103Series(v2.2or higher)MGate5105-MB-EIP Series(v4.3or higher)MGate5109Series(v2.3or higher)MGate5111Series(v1.3or higher)MGate5114Series(v1.3or higher)MGate5118Series(v2.2or higher)MGate W5108/W5208Series(v2.4or higher)MGate5217I Series(v1.0or higher)NPort Products NPort S8455Series(v1.3or higher)NPort S8458Series(v1.3or higher)NPort5110Series(v2.10or higher)NPort5130/5150Series(v3.9or higher)NPort5200Series(v2.12or higher)NPort5100A Series(v1.6or higher)NPort P5150A Series(v1.6or higher)NPort5200A Series(v1.6or higher)NPort5400Series(v3.14or higher)NPort5600Series(v3.10or higher)NPort5610-8-DT/5610-8-DT-J/5650-8-DT/5650I-8-DT/5650-8-DT-J Series(v2.7orhigher)NPort5610-8-DTL/5650-8-DTL/5650I-8-DTL Series(v1.6or higher)NPort IA5000Series(v1.7or higher)NPort IA5150A/IA5150AI/IA5250A/IA5250AI Series(v1.5or higher)NPort IA5450A/IA5450AI Series(v2.0or higher)NPort6000Series(v1.21or higher)NPort5000AI-M12Series(v1.5or higher)PT Products PT-7528Series(v3.0or higher)PT-7710Series(v1.2or higher)PT-7728Series(v2.6or higher)PT-7828Series(v2.6or higher)PT-G7509Series(v1.1or higher)PT-508/510Series(v3.0or higher)PT-G503-PHR-PTP Series(v4.0or higher)PT-G7728Series(v5.3or higher)PT-G7828Series(v5.3or higher)SDS Products SDS-3008Series(v2.1or higher)SDS-3016Series(v2.1or higher)TAP Products TAP-213Series(v1.2or higher)TAP-323Series(v1.8or higher)TAP-6226Series(v1.8or higher)TN Products TN-4516A Series(v3.6or higher)TN-4516A-POE Series(v3.6or higher)TN-4524A-POE Series(v3.6or higher)TN-4528A-POE Series(v3.8or higher)TN-G4516-POE Series(v5.0or higher)TN-G6512-POE Series(v5.2or higher)TN-5508/5510Series(v1.1or higher)TN-5516/5518Series(v1.2or higher)TN-5508-4PoE Series(v2.6or higher)TN-5516-8PoE Series(v2.6or higher)UC Products UC-2101-LX Series(v1.7or higher)UC-2102-LX Series(v1.7or higher)UC-2104-LX Series(v1.7or higher)UC-2111-LX Series(v1.7or higher)UC-2112-LX Series(v1.7or higher)UC-2112-T-LX Series(v1.7or higher)UC-2114-T-LX Series(v1.7or higher)UC-2116-T-LX Series(v1.7or higher)V Products V2406C Series(v1.0or higher)VPort Products VPort26A-1MP Series(v1.2or higher)VPort36-1MP Series(v1.1or higher)VPort P06-1MP-M12Series(v2.2or higher)WAC Products WAC-1001Series(v2.1or higher)WAC-2004Series(v1.6or higher)For MXview Wireless AWK-1131A Series(v1.22or higher)AWK-1137C Series(v1.6or higher)AWK-3131A Series(v1.16or higher)AWK-4131A Series(v1.16or higher)Note:To use advanced wireless functions in MXview Wireless,the device must be inone of the following operation modes:AP,Client,Client-Router.Package ContentsNumber of Supported Nodes Up to2000(may require purchase of expansion licenses)Ordering InformationMXview-5050––MXview-100100––MXview-250250––MXview-500500––MXview-10001000––MXview-20002000––MXview Upgrade-50050nodes–LIC-MXview-ADD-WIRELESS-MR––Wireless©Moxa Inc.All rights reserved.Updated Sep10,2021.This document and any portion thereof may not be reproduced or used in any manner whatsoever without the express written permission of Moxa Inc.Product specifications subject to change without notice.Visit our website for the most up-to-date product information.。

MXview Plugin for MGate Series Release NotesSupported Operating SystemsNotesChangesApplicable ProductsBugs FixedN/AN/AEnhancementsWindows 10, Windows 7, Windows 8, Windows Server 2008, Windows Server 2012, Windows Server 2012 R2MGate W5108, MGate W5108-T, MGate W5208, MGate W5208-T, MGate 5109, MGate 5109-T, MGate 5118, MGate 5118-T, MGate MB3180, MGate MB3280, MGate MB3480, MGate MB3170, MGate MB3170I, MGate MB3270, MGate MB3270I, MGate MB3170-T, MGate MB3170I-T, MGate MB3270-T,MGate MB3270I-T, MGate MB3170-M-SC, MGate MB3170-M-ST, MGate MB3170-S-SC, MGate MB3170I-M-SC, MGate MB3170I-S-SC, MGate MB3170-M-SC-T, MGate MB3170-M-ST-T, MGate MB3170-S-SC-T, MGate MB3170I-M-SC-T, MGate MB3170I-S-SC-T, MGate MB3660-8-J-2AC,MGate MB3660I-16-2AC, MGate MB3660-16-J-2AC, MGate MB3660-8-2AC, MGate MB3660-8-2DC,MGate MB3660I-8-2AC, MGate MB3660-16-2AC, MGate MB3660-16-2DC, MGate 5101-PBM-MN,MGate 5101-PBM-MN-T, MGate 5105-MB-EIP, MGate 5105-MB-EIP-T, MGate 5103, MGate 5103-T,MGate 5102-PBM-PN, MGate 5102-PBM-PN-T, MGate EIP3170, MGate EIP3170I, MGate EIP3270,MGate EIP3270I, MGate EIP3170-T, MGate EIP3170I-T, MGate EIP3270-T, MGate 5111, MGate 5111-T, MGate 5114, MGate 5114-T• Supports MGate 5114.• Added security view for MB3170, MB3170I, MB3170 fiber series, MB3270, MB3270I, MB3180,MB3280, MB3480, MB3660, MGate 5114.New FeaturesN/A• This version supports MXview v2.9.Supported Operating SystemsNotesChangesApplicable ProductsBugs Fixed• Supports MGate 5103, MGate 5111, MGate MB3660I-16-2AC, MGate MB3660-8-J-2AC, MGate MB3660-16-J-2AC.• Added security view for MGate 5101-PBM-MN, MGate 5102-PBM-PN, MGate 5105-MB-EIP, MGate W5108, MGate W5208, MGate 5103, MGate 5111.N/AEnhancementsWindows 7, Windows 8, Windows Server 2008, Windows Server 2012, Windows XPMGate W5108, MGate W5108-T, MGate W5208, MGate W5208-T, MGate 5109, MGate 5109-T, MGate 5118, MGate 5118-T, MGate MB3180, MGate MB3280, MGate MB3480, MGate MB3170, MGate MB3170I, MGate MB3270, MGate MB3270I, MGate MB3170-T, MGate MB3170I-T, MGate MB3270-T,MGate MB3270I-T, MGate MB3170-M-SC, MGate MB3170-M-ST, MGate MB3170-S-SC, MGate MB3170I-M-SC, MGate MB3170I-S-SC, MGate MB3170-M-SC-T, MGate MB3170-M-ST-T, MGate MB3170-S-SC-T, MGate MB3170I-M-SC-T, MGate MB3170I-S-SC-T, MGate MB3660-8-J-2AC,MGate MB3660I-16-2AC, MGate MB3660-16-J-2AC, MGate MB3660-8-2AC, MGate MB3660-8-2DC,MGate MB3660I-8-2AC, MGate MB3660-16-2AC, MGate MB3660-16-2DC, MGate 5101-PBM-MN,MGate 5101-PBM-MN-T, MGate 5105-MB-EIP, MGate 5105-MB-EIP-T, MGate 5103, MGate 5103-T,MGate 5102-PBM-PN, MGate 5102-PBM-PN-T, MGate EIP3170, MGate EIP3170I, MGate EIP3270,MGate EIP3270I, MGate EIP3170-T, MGate EIP3170I-T, MGate EIP3270-T, MGate 5111, MGate 5111-TN/ANew FeaturesN/A• This version supports MXview v2.9.Supported Operating SystemsNotesChangesApplicable ProductsBugs Fixed• Supports MGate 5118.• Added security view for MGate 5109, MGate 5118.• Added userid login for MGate 5109, MGate 5118.N/AEnhancementsWindows 7, Windows 8, Windows Server 2008, Windows Server 2012, Windows XPMGate MB3660I-16-2AC, MGate MB3660-16-J-2AC, MGate MB3660-8-2AC, MGate MB3660-8-2DC,MGate MB3660I-8-2AC, MGate MB3660-16-2AC, MGate MB3660-16-2DC, MGate 5101-PBM-MN,MGate 5101-PBM-MN-T, MGate 5105-MB-EIP, MGate 5105-MB-EIP-T, MGate 5102-PBM-PN, MGate 5102-PBM-PN-T, MGate EIP3170, MGate EIP3170I, MGate EIP3270, MGate EIP3270I, MGate EIP3170-T, MGate EIP3170I-T, MGate EIP3270-T, MGate W5108, MGate W5108-T, MGate W5208,MGate W5208-T, MGate 5109, MGate 5109-T, MGate 5118, MGate 5118-T, MGate MB3180, MGate MB3280, MGate MB3480, MGate MB3170, MGate MB3170I, MGate MB3270, MGate MB3270I,MGate MB3170-T, MGate MB3170I-T, MGate MB3270-T, MGate MB3270I-T, MGate MB3170-M-SC,MGate MB3170-M-ST, MGate MB3170-S-SC, MGate MB3170I-M-SC, MGate MB3170I-S-SC, MGate MB3170-M-SC-T, MGate MB3170-M-ST-T, MGate MB3170-S-SC-T, MGate MB3170I-M-SC-T, MGate MB3170I-S-SC-T, MGate MB3660-8-J-2ACN/ANew FeaturesN/A• This version supports MXview v2.8.Supported Operating SystemsNotesChangesApplicable ProductsBugs Fixed• Supports MGate 5109.N/AEnhancementsWindows 7, Windows 8, Windows Server 2008, Windows Server 2012, Windows XPMGate W5108, MGate W5108-T, MGate W5208, MGate W5208-T, MGate 5109, MGate 5109-T, MGate MB3180, MGate MB3280, MGate MB3480, MGate MB3170, MGate MB3170I, MGate MB3270, MGate MB3270I, MGate MB3170-T, MGate MB3170I-T, MGate MB3270-T, MGate MB3270I-T, MGate MB3170-M-SC, MGate MB3170-M-ST, MGate MB3170-S-SC, MGate MB3170I-M-SC, MGate MB3170I-S-SC, MGate MB3170-M-SC-T, MGate MB3170-M-ST-T, MGate MB3170-S-SC-T, MGate MB3170I-M-SC-T, MGate MB3170I-S-SC-T, MGate MB3660-8-J-2AC, MGate MB3660I-16-2AC,MGate MB3660-16-J-2AC, MGate MB3660-8-2AC, MGate MB3660-8-2DC, MGate MB3660I-8-2AC,MGate MB3660-16-2AC, MGate MB3660-16-2DC, MGate 5101-PBM-MN, MGate 5101-PBM-MN-T,MGate 5105-MB-EIP, MGate 5105-MB-EIP-T, MGate 5102-PBM-PN, MGate 5102-PBM-PN-T, MGate EIP3170, MGate EIP3170I, MGate EIP3270, MGate EIP3270I, MGate EIP3170-T, MGate EIP3170I-T,MGate EIP3270-TN/ANew FeaturesN/A• This version supports MXview v2.7.Supported Operating SystemsNotesChangesApplicable ProductsBugs Fixed• Supports MGate W5108/W5208, MGate MB3170 Fiber Series, MGate MB3660 Series.N/AEnhancementsWindows 7, Windows 8, Windows Server 2008, Windows Server 2012, Windows XPMGate W5108, MGate W5108-T, MGate W5208, MGate W5208-T, MGate MB3180, MGate MB3280,MGate MB3480, MGate MB3170, MGate MB3170I, MGate MB3270, MGate MB3270I, MGate MB3170-T, MGate MB3170I-T, MGate MB3270-T, MGate MB3270I-T, MGate MB3170-M-SC, MGate MB3170-M-ST, MGate MB3170-S-SC, MGate MB3170I-M-SC, MGate MB3170I-S-SC, MGate MB3170-M-SC-T, MGate MB3170-M-ST-T, MGate MB3170-S-SC-T, MGate MB3170I-M-SC-T, MGate MB3170I-S-SC-T, MGate MB3660-8-J-2AC, MGate MB3660I-16-2AC, MGate MB3660-16-J-2AC,MGate MB3660-8-2AC, MGate MB3660-8-2DC, MGate MB3660I-8-2AC, MGate MB3660-16-2AC,MGate MB3660-16-2DC, MGate 5101-PBM-MN, MGate 5101-PBM-MN-T, MGate 5105-MB-EIP,MGate 5105-MB-EIP-T, MGate 5102-PBM-PN, MGate 5102-PBM-PN-T, MGate EIP3170, MGate EIP3170I, MGate EIP3270, MGate EIP3270I, MGate EIP3170-T, MGate EIP3170I-T, MGate EIP3270-T N/ANew FeaturesN/A• This version supports MXview v2.6.Supported Operating SystemsNotesChangesApplicable ProductsBugs FixedN/AN/AEnhancementsWindows 7, Windows 8, Windows Server 2008, Windows Server 2012, Windows XPMGate MB3180, MGate MB3280, MGate MB3480, MGate MB3170, MGate MB3170I, MGate MB3270,MGate MB3270I, MGate MB3170-T, MGate MB3170I-T, MGate MB3270-T, MGate MB3270I-T, MGate 5101-PBM-MN, MGate 5101-PBM-MN-T, MGate 5105-MB-EIP, MGate 5105-MB-EIP-T, MGate 5102-PBM-PN, MGate 5102-PBM-PN-T, MGate EIP3170, MGate EIP3170I, MGate EIP3270, MGate EIP3270I, MGate EIP3170-T, MGate EIP3170I-T, MGate EIP3270-TN/ANew FeaturesN/A• This version supports MXview v2.4.Supported Operating SystemsNotesChangesApplicable ProductsBugs FixedN/AN/AEnhancementsWindows 7, Windows 8, Windows Server 2008, Windows Server 2012, Windows XPMGate MB3180, MGate MB3280, MGate MB3480, MGate MB3170, MGate MB3170I, MGate MB3270,MGate MB3270I, MGate MB3170-T, MGate MB3170I-T, MGate MB3270-T, MGate MB3270I-T, MGate 5101-PBM-MN, MGate 5101-PBM-MN-T, MGate 5105-MB-EIP, MGate 5105-MB-EIP-T, MGate 5102-PBM-PN, MGate 5102-PBM-PN-T, MGate EIP3170, MGate EIP3170I, MGate EIP3270, MGate EIP3270I, MGate EIP3170-T, MGate EIP3170I-T, MGate EIP3270-T• First release.New FeaturesN/AN/A。

For free samples and the latest literature, visit or phone 1-800-998-8800.For small orders, phone 1-800-835-8769.General DescriptionThe MAX6361–MAX6364 supervisory circuits reduce the complexity and number of components required for power-supply monitoring and battery control functions in microprocessor (µP) systems. The circuits significantly improve system reliability and accuracy compared to that obtainable with separate ICs or discrete components.Their functions include µP reset, backup battery switchover, and power failure warning.The MAX6361–MAX6364 operate from supply voltages as low as +1.2V. The factory-preset reset threshold voltage ranges from 2.32V to 4.63V (see Ordering Information ).These devices provide a manual reset input (MAX6361),watchdog timer input (MAX6362), battery-on output (MAX6363), and an auxiliary adjustable reset input (MAX6364). In addition, each part type is offered in three reset output versions: an active-low open-drain reset, an active-low open-drain reset, and an active-high open-drain reset (see Selector Guide at end of data sheet).ApplicationsFeatures♦Low +1.2V Operating Supply Voltage (V CC or V BATT )♦Precision Monitoring of +5.0V, +3.3V, +3.0V, and +2.5V Power-Supply Voltages♦Debounced Manual Reset Input (MAX6361)♦Watchdog Timer with 1.6s Timeout Period (MAX6362)♦Battery-On Output Indicator (MAX6363)♦Auxiliary User-Adjustable RESET IN (MAX6364)♦Three Available Output StructuresPush-Pull RESET , Open-Drain RESET , Open-Drain RESET♦RESET/RESET Valid Down to 1.2V Guaranteed (V CC or V BATT )♦Power-Supply Transient Immunity ♦150ms (min) Reset Timeout Period ♦Small 6-Pin SOT23 PackageMAX6361–MAX6364SOT23, Low-Power µP Supervisory Circuitswith Battery Backup________________________________________________________________Maxim Integrated Products119-1615; Rev 3; 11/05Ordering InformationPin ConfigurationsFrom the table below, select the suffix corresponding to the desired threshold voltage and insert it into the part number to complete it. When ordering from the factory, there is a 2500-piece minimum on the SOT package (tape-and-reel only).Devices are available in both leaded and lead-free packaging.Specify lead-free by replacing "-T" with "+T" when ordering.Computers ControllersIntelligent Instruments Critical µP/µC Power MonitoringFax Machines Industrial Control POS EquipmentPortable/Battery-Powered EquipmentSelector Guide appears at end of data sheet.Typical Operating Circuit appears at end of data sheet.M A X 6361–M A X 6364SOT23, Low-Power µP Supervisory Circuits with Battery BackupABSOLUTE MAXIMUM RATINGSELECTRICAL CHARACTERISTICS(V CC = +2.4V to +5.5V, V BATT = 3V, T A = -40°C to +85°C, reset not asserted. Typical values are at T A = +25°C, unless otherwise noted.) (Note 1)Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.Terminal Voltages (with respect to GND)V CC , BATT, OUT.......................................................-0.3V to +6V RESET (open drain), RESET (open drain)................-0.3V to +6V BATT ON, RESET (push-pull), RESET IN,WDI.......................................................-0.3V to (V OUT + 0.3V)MR .............................................................-0.3V to (V CC + 0.3V)Input CurrentV CC Peak ............................................................................1A V CC Continuous............................................................250mA BATT Peak....................................................................250mA BATT Continuous............................................................40mAGND................................................................................75mA Output CurrentOUT................................Short-Circuit Protection for up to 10s RESET, RESET , BATT ON ..............................................20mA Continuous Power Dissipation (T A = +70°C)6-Pin SOT23 (derate 8.70mW/°C above +70°C) .........696mW Operating Temperature Range ...........................-40°C to +85°C Junction Temperature......................................................+150°C Storage Temperature Range.............................-65°C to +150°C Lead Temperature (soldering, 10s).................................+300°CMAX6361–MAX6364SOT23, Low-Power µP Supervisory Circuitswith Battery Backup_______________________________________________________________________________________3ELECTRICAL CHARACTERISTICS (continued)(V CC = +2.4V to +5.5V, V BATT = 3V, T A = -40°C to +85°C, reset not asserted. Typical values are at T A = +25°C, unless otherwise noted.) (Note 1)Note 1:All devices are 100% production tested at T A = +25°C. Limits over temperature are guaranteed by design.Note 2:V BATT can be 0 anytime or V CC can go down to 0 if V BATT is active (except at startup).M A X 6361–M A X 6364SOT23, Low-Power µP Supervisory Circuits with Battery Backup 4_______________________________________________________________________________________Typical Operating Characteristics(T A = +25°C, unless otherwise noted.)1214161820SUPPLY CURRENT vs. TEMPERATURE(NO LOAD)TEMPERATURE (°C)S U P P L Y C U R R E N T (µA )-402040-2060800.20.60.40.81.01.2BATTERY SUPPLY CURRENT (BACKUP MODE) vs. TEMPERATURETEMPERATURE (°C)B A T T E R Y S U P P L Y C U R R E N T (µA )-402040-20060801432567BATTERY TO OUT ON-RESISTANCEvs. TEMPERATURETEMPERATURE (°C)B A T T T O O U T O N -R E S I S T A NC E (Ω)-402040-20608000.30.90.61.2V CC TO OUT ON-RESISTANCEvs. TEMPERATURETEMPERATURE (°C)V O U T T O O U T O N -R E S I S T A N C E (Ω)-402040-206080190195205200210RESET TIMEOUT PERIOD vs. TEMPERATUREM A X 6361 t o c 05TEMPERATURE (°C)R E S E T T I M E O U T P E R I O D (m s )-402040-206080301575604513512010590V CC TO RESET PROPAGATION DELAYvs. TEMPERATURETEMPERATURE (°C)P R O P A G A T I O N D E LA Y (µs )-402040-2060802.03.02.55.04.54.03.5RESET THRESHOLD vs. TEMPERATURETEMPERATURE (°C)T H R E S H O L D (V )-402040-2060801.21.41.31.61.51.91.81.72.0-40-2020406080MAX6362WATCHDOG TIMEOUT PERIODvs. TEMPERATUREM A X 6361t o c 06aTEMPERATURE (°C)W A T C H D O G T I M E O U T P E R I O D (s )1100101k10kMAXIMUM TRANSIENT DURATION vs. RESET THRESHOLD OVERDRIVERESET THRESHOLD OVERDRIVE V TH - V CC (mV)M A X I M U M T R A N S I E N T D U R A T I O N (µs )400300350250200050150100MAX6361–MAX6364SOT23, Low-Power µP Supervisory Circuitswith Battery Backup1.2341.2351.236MAX6364RESET IN THRESHOLD vs. TEMPERATUREM A X 6361 t o c 10TEMPERATURE (°C)T H R E S H O L D (V )-402040-206080Typical Operating Characteristics (continued)(T A = +25°C, unless otherwise noted.)1.01.91.61.32.82.52.2MAX6364RESET IN TO RESET PROPAGATION DELAYvs. TEMPERATURETEMPERATURE (°C)P R O P A G A T I O N D E L A Y (µs )-402040-206080Pin Description0321456789101234BATTERY SUPPLY CURRENT vs. SUPPLY VOLTAGEV CC (V)B A T T E R Y S U P P L YC U R R E N T (µA )M A X 6361–M A X 6364Detailed DescriptionThe Typical Operating Circuit shows a typical connection for the MAX6361–MAX6364 family. OUT powers the stat-ic random-access memory (SRAM). OUT is internally connected to V CC if V CC is greater than the reset thresh-old, or to the greater of V CC or V BATT when V CC is less than the reset threshold. OUT can supply up to 150mA from V CC . When V CC is higher than V BATT , the BATT ON (MAX6363) output is low. When V CC is lower than V BATT ,an internal MOSF ET connects the backup battery to OUT. The on-resistance of the MOSFET is a function of backup-battery voltage and is shown in the Battery to Out On-Resistance vs. Temperature graph in the Typical Operating Characteristics section.Backup-Battery SwitchoverIn a brownout or power failure, it may be necessary to preserve the contents of the RAM. With a backup bat-tery installed at BATT, the MAX6361–MAX6364 auto-matically switch the RAM to backup power when V CC falls. The MAX6363 has a BATT ON output that goes high when in battery-backup mode. These devices require two conditions before switching to battery-backup mode:1)V CC must be below the reset threshold.2)V CC must be below V BATT .Table 1 lists the status of the inputs and outputs in bat-tery-backup mode. The device will not power up if the only voltage source is on BATT. OUT will only power up from V CC at startup.Manual Reset Input (MAX6361 Only)Many µP-based products require manual reset capabili-ty, allowing the operator, a test technician, or external logic circuitry to initiate a reset. For the MAX6361, a logic low on MR asserts reset. Reset remains asserted while MR is low, and for a minimum of 150ms (t RP ) after it returns high. MR has an internal 20k Ωpull-up resistor to V CC . This input can be driven with TTL/CMOS logic lev-els or with open-drain/collector outputs. Connect a nor-mally open momentary switch from MR to GND to create a manual reset function; external debounce circuitry is not required. If MR is driven from long cables or the device is used in a noisy environment, connect a 0.1µF capacitor from MR to GND to provide additional noise immunity.Watchdog Input (MAX6362 Only)The watchdog monitors µP activity through the input WDI. If the µP becomes inactive, the reset output is asserted in pulses. To use the watchdog function, con-nect WDI to a bus line or µP I/O line. A change of state(high to low or low to high) within the watchdog timeout period (t WD ) with a 100ns minimum pulse width clears the watchdog timer. If WDI remains high or low for longer than the watchdog timeout period, the internal watchdog timer runs out and a reset pulse is triggered for the reset timeout period (t RP ). The internal watchdog timer clears whenever reset asserts or the WDI sees a rising or falling edge within the watchdog timeout period. If WDI remains in a high or low state for an extended period of time, a reset pulse asserts after every watchdog timeout period (t WD ) (Figure 1).Reset In (MAX6364 Only)RESET IN is compared to an internal 1.235V reference.If the voltage at RESET IN is less than 1.235V, reset is asserted. The RESET IN comparator may be used as an undervoltage detector to signal a failing power sup-ply. It can also be used as a secondary power-supply reset monitor.To program the reset threshold (V RTH ) of the secondary power supply, use the following equation (see Typical Operating Circuit ):where V REF = 1.235V. To simplify the resistor selection,choose a value for R2 and calculate R1:Since the input current at RESET IN is 25nA (max), large values (up to 1M Ω) can be used for R2 with no signifi-cant loss in accuracy. F or example, in the TypicalSOT23, Low-Power µP Supervisory Circuits with Battery Backup 6_______________________________________________________________________________________R R V V RTH REF 121 /=()−[]MAX6361–MAX6364SOT23, Low-Power µP Supervisory Circuitswith Battery Backup_______________________________________________________________________________________7Operating Circuit,the MAX6362 monitors two supply voltages. To monitor the secondary 5V logic or analog supply with a 4.60V nominal programmed reset thresh-old, choose R2 = 100k Ω, and calculate R1 = 273k Ω.Reset OutputA µP’s reset input starts the µP in a known state. The MAX6361–MAX6364 µP supervisory circuits assert a reset to prevent code-execution errors during power-up, power-down, and brownout conditions. RESET is guaranteed to be a logic low or high depending on the device chosen (see Ordering Information ). RESET or RESET asserts when V CC is below the reset threshold and for at least 150ms (t RP ) after V CC rises above the reset threshold. RESET or RESET also asserts when MR is low (MAX6361) and when RESET IN is less than 1.235V (MAX6364). The MAX6362 watchdog function will cause RESET (or RESET ) to assert in pulses follow-ing a watchdog timeout (Figure 1).Applications InformationOperation Without a BackupPower SourceThe MAX6361–MAX6364 were designed for battery-backed applications. If a backup battery is not used,connect V CC to OUT and connect BATT to GND.Replacing the Backup BatteryIf BATT is decoupled with a 0.1µF capacitor to ground,the backup power source can be removed while V CC remains valid without danger of triggering a reset pulse.The device does not enter battery-backup mode when V CC stays above the reset threshold voltage.Negative-Going V CC TransientsThese supervisors are relatively immune to short-dura-tion, negative-going V CC transients. Resetting the µPwhen V CC experiences only small glitches is usually not desirable.The Typical Operating Characteristics section shows a graph of Maximum Transient Duration vs. Reset Threshold Overdrive for which reset is not asserted.The graph was produced using negative-going V CC pulses, starting at V CC and ending below the reset threshold by the magnitude indicated (reset threshold overdrive). The graph shows the maximum pulse width that a negative-going V CC transient can typically have without triggering a reset pulse. As the amplitude of the transient increases (i.e., goes further below the reset threshold), the maximum allowable pulse width decreases. Typically, a V CC transient that goes 100mV below the reset threshold and lasts for 30µs will not trigger a reset pulse.A 0.1µF bypass capacitor mounted close to the V CC pin provides additional transient immunity.Figure 1. MAX6362 Watchdog Timeout Period and Reset Active TimeM A X 6361–M A X 6364Watchdog Software Considerations(MAX6362 Only)To help the watchdog timer monitor software execution more closely, set and reset the watchdog input at dif-ferent points in the program, rather than “pulsing” the watchdog input low-high-low. This technique avoids a “stuck” loop, in which the watchdog timer would contin-ue to be reset within the loop, keeping the watchdog from timing out. F igure 2 shows an example of a flow diagram where the I/O driving the WDI is set low at the beginning of the program, set high at the beginning of every subroutine or loop, then set low again when the program returns to the beginning. If the program should “hang” in any subroutine, the problem would quickly be corrected, since the I/O is continually set low and the watchdog timer is allowed to time out, trigger-ing a reset.SOT23, Low-Power µP Supervisory Circuits with Battery Backup 8_______________________________________________________________________________________Figure 2. Watchdog Flow DiagramMAX6361–MAX6364SOT23, Low-Power µP Supervisory Circuitswith Battery Backup_______________________________________________________________________________________9*Sample stock generally held on standard versions only. Contact factory for availability of nonstandard versions.Device Marking CodesSelector GuideM A X 6361–M A X 6364SOT23, Low-Power µP Supervisory Circuits with Battery Backup 10______________________________________________________________________________________Pin Configurations (continued)Typical Operating CircuitChip InformationTRANSISTOR COUNT: 720MAX6361–MAX6364SOT23, Low-Power µP Supervisory Circuits with Battery Backup______________________________________________________________________________________11Package InformationM A X 6361–M A X 6364SOT23, Low-Power µP Supervisory Circuits with Battery BackupMaxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.12____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600©2005 Maxim Integrated Products Printed USA is a registered trademark of Maxim Integrated Products, Inc.NOTES。

General DescriptionThe MAX6375–MAX6380 are ultra-low-power circuits used for monitoring battery, power-supply, and regulat-ed system voltages. Each detector contains a precision bandgap reference, comparator, and internally trimmed resistors that set specified trip threshold voltages.These devices provide excellent circuit reliability and low cost by eliminating external components and adjustments when monitoring nominal system voltages from 2.5V to 5V.These circuits perform a single function: they assert an output signal whenever the V CC supply voltage falls below a preset threshold. The devices are differentiated by their output logic configurations and preset thresh-old voltages. The MAX6375/MAX6378 (push-pull) and MAX6377/MAX6380 (open-drain) have an active-low output (OUT is logic low when V CC is below V TH ). The MAX6376/MAX6379 have an active-high push-pull out-put (OUT is logic high when V CC is below V TH ). All parts are guaranteed to be in the correct output logic state for V CC down to 1V. The detector is designed to ignore fast transients on V CC . The MAX6375/MAX6376/MAX6377 have voltage thresholds between 2.20V and 3.08V in approximately 100mV increments. The MAX6378/MAX6379/MAX6380 have voltage thresholds between 3.30V and 4.63V in approximately 100mV increments.Ultra-low supply current of 500nA (MAX6375/MAX6376/MAX6377) makes these parts ideal for use in portable equipment. All six devices are available in a space-sav-ing SC70 package or in a tiny SOT23 package.ApplicationsPrecision Battery Monitoring Load Switching/Power SequencingPower-Supply Monitoring in Digital/Analog Systems Portable/Battery-Powered EquipmentFeatures♦Ultra-Low 500nA Supply Current (MAX6375/MAX6376/MAX6377)♦Thresholds Available from 2.20V to 4.63V in Approximately 100mV Increments♦±2.5% Threshold Accuracy Over Temperature ♦Low Cost♦Available in Three Versions: Push-Pull OUT ,Push-Pull OUT, and Open-Drain OUT ♦Power-Supply Transient Immunity ♦No External Components♦Available in Either a 3-Pin SC70 or 3-Pin SOT23 PackageMAX6375–MAX63803-Pin, Ultra-Low-Power SC70/SOT23Voltage Detectors________________________________________________________________Maxim Integrated Products 1Pin Configuration19-1721; Rev 3; 12/05*The MAX6375/MAX6376/MAX6377 are available in factory-presetthresholds from 2.20V to 3.08V, in approximately 0.1V increments.The MAX6378/MAX6379/MAX6380 are available in factory-preset thresholds from 3.30V to 4.63V, in approximately 0.1V increments.Choose the desired threshold suffix from Table 1 and insert it in the blank spaces following R. There are 21 standard versions,with a required order increment of 2500 pieces. Sample stock is generally held on the standard versions only (see the Selector Guide). The required order increment is 10,000 pieces for non-standard versions (Table 2). Contact factory for availability. All devices available in tape-and-reel only.Devices are available in both leaded and lead-free packaging.Specify lead-free by replacing “-T” with “+T” when ordering.Selector Guide appears at end of data sheet.For pricing, delivery, and ordering information,please contact Maxim/Dallas Direct!at 1-888-629-4642, or visit Maxim’s website at .Ordering information continued at end of data sheetM A X 6375–M A X 63803-Pin, Ultra-Low-Power SC70/SOT23Voltage Detectors 2_______________________________________________________________________________________ABSOLUTE MAXIMUM RATINGSELECTRICAL CHARACTERISTICS(V CC = full range, T A = -40°C to +85°C, unless otherwise noted. Typical values are at T A = +25°C and V CC = 3V.) (Note 1)Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.Terminal Voltage (with respect to GND)V CC ...........................................................................-0.3V to +6V OUT, OUT (push-pull)................................-0.3V to (V CC + 0.3V)OUT (open-drain).....................................................-0.3V to +6V Input Current (V CC ).............................................................20mA Output Current (OUT, OUT )................................................20mAContinuous Power Dissipation (T A = +70°C)3-Pin SC70 (derate 2.17mW/°C above +70°C)...........174mW 3-Pin SOT23 (derate 4mW/°C above +70°C)..............320mW Operating Temperature Range ...........................-40°C to +85°C Storage Temperature Range.............................-65°C to +150°C Junction Temperature......................................................+150°C Lead Temperature (soldering, 10s).................................+300°CNote 1:Production tested at +25°C only. Overtemperature limits are guaranteed by design, not production tested.MAX6375–MAX63803-Pin, Ultra-Low-Power SC70/SOT23Voltage Detectors__________________________________________Typical Operating Characteristics(V CC = 5V, T A = +25°C, unless otherwise noted.)00.30.20.10.40.50.60.70.80.91.0-40-2020406080SUPPLY CURRENT vs. TEMPERATURETEMPERATURE (°C)S U P P L Y C U R R E N T (µA )050100150200-40-2020406080PROPAGATION DELAY (FALLING)vs. TEMPERATURETEMPERATURE (°C)P R O P A G A T I O N D E L A Y (µs )040208060120100140-4020-20406080PROPAGATION DELAY (RISING)vs. TEMPERATURETEMPERATURE (°C)P R O P A G A T I O N D E L A Y (µs )50011001000MAXIMUM TRANSIENT DURATION vs. THRESHOLD OVERDRIVE100300400200THRESHOLD OVERDRIVEV TH - V CC (mV)M A X I M U M T R A N S I E N T D U R A T I O N (µs )10Pin DescriptionM A X 6375–M A X 63803-Pin, Ultra-Low-Power SC70/SOT23Voltage Detectors____________Applications InformationInterfacing to Different Logic Voltage ComponentsThe MAX6377/MAX6380 have an active-low, open-drain output. This output structure sinks current when OUT is asserted. Connect a pullup resistor from OUT to any supply voltage up to 5.50V (Figure 1). Select a resistor value large enough to allow a valid logic low (see Electrical Characteristics ), and small enough to register a logic high while supplying all input current and leakage paths connected to the OUT line.Negative-Going V CC TransientsThese devices are relatively immune to short-duration,negative-going V CC transients (glitches). The Typical Operating Characteristics show the Maximum Transient Duration vs. Threshold Overdrive graph, for which out-put pulses are not generated. The graph shows the maximum pulse width that a negative-going V CC tran-sient may typically have before the devices issue out-put signals. As the amplitude of the transient increases,the maximum-allowable pulse width decreases.Figure 1. Interfacing to Different Logic Voltage ComponentsTable 1. Factory-Trimmed Reset Thresholds ‡3-Pin, Ultra-Low-Power SC70/SOT23Voltage Detectors_______________________________________________________________________________________5Table 2. Device Marking Codes and Minimum Order IncrementsMAX6375–MAX6380M A X 6375–M A X 63803-Pin, Ultra-Low-Power SC70/SOT23Voltage Detectors 6__________________________________________________________________________________________________________Chip InformationTRANSISTOR COUNT: 419Selector Guide**Sample stock is generally held on all standard versions.Contact factory for availability of nonstandard versions.*The MAX6375/MAX6376/MAX6377 are available in factory-presetthresholds from 2.20V to 3.08V, in approximately 0.1V increments.The MAX6378/MAX6379/MAX6380 are available in factory-preset thresholds from 3.30V to 4.63V, in approximately 0.1V increments.Choose the desired threshold suffix from Table 1 and insert it in the blank spaces following R. There are 21 standard versions,with a required order increment of 2500 pieces. Sample stock is generally held on the standard versions only (see the Selector Guide). The required order increment is 10,000 pieces for non-standard versions (Table 2). Contact factory for availability. All devices available in tape-and-reel only.Devices are available in both leaded and lead-free packaging.Specify lead-free by replacing “-T” with “+T” when ordering.Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600_____________________7©2005 Maxim Integrated ProductsPrinted USAis a registered trademark of Maxim Integrated Products, Inc.3-Pin, Ultra-Low-Power SC70/SOT23Voltage DetectorsMAX6375–MAX6380Package Information(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,go to /packages .)。

D D R与D D R-I IDDRSDRAMDDRSDRAM全称为DoubleDataRateSDRAM，中文名为“双倍数据流SDRAM”。

DDRSDRAM在原有的SDRAM的基础上改进而来。

图1一、DDR的基本原理以MICRON的MT46V64M16（16Megx16x4Banks）为例，其时序图如下所示：图2DDR读操作时序图从中可以发现它多了两个信号：CK#与DQS，CK#与正常CK时钟相位相反，形成差分时钟信号。

而数据的传输在CK与CK#的交叉点进行，可见在CK的上升沿与下降沿都有数据被触发，从而实现DDR。

在此，我们可以说通过差分信号达到了DDR的目的，甚至讲CK#帮助了第二个数据的触发，但这只是对表面现象的简单描述，从严格的定义上讲并不能这么说。

之所以能实现DDR，还要从其内部的改进说起。

图3DDR内部结构图从图中可以看出，其前半部分与SDRAM的结构基本相同，红色框图部分即为比SDRAM多出的部分。

首先不同之处就是内部的Bankcontrollogic规格。

SDRAM中Bankcontrollogic存储单元的容量与芯片位宽相同，但在DDR 中Bankcontrollogic存储单元的容量是芯片位宽的一倍。

也因此，真正的行、列地址数量也与同规格SDRAM不一样了。

以本芯片为例，在读取时，Bankcontrollogic在内部时钟信号的触发下一次传送32bit的数据给读取锁存器，再分成2路16bit数据传给复用器，由后者将它们合并为一路16bit数据流，然后由发送器在DQS的控制下在外部时钟上升沿与下降沿分两次传输16bit的数据给北桥。

这样，如果时钟频率为100MHz，那么在I/O端口处，由于是上下沿触发，那么就是传输频率就是200MHz。

这种内部存储单元容量（也可以称为芯片内部总线位宽）=2×芯片位宽（也可称为芯片I/O总线位宽）的设计，就是所谓的两位预取（2-bitPrefetch），有的公司则贴切的称之为2-nPrefetch（n代表芯片位宽）。

553XC6367_6368 ETR0401_001.doc◆Input Voltage Range: 0.9~10.0V ◆Output Voltage Range : 1.5~6.5V(±2.5%)◆Oscillator Frequency : 300kHz(±15%)◆PWM/PFM Switching Control (XC6368) ◆High Efficiency : 84% (TYP .) ◆SOT-25 Package■GENERAL DESCRIPTION The XC6367/68 series are multi-functional step-up DC/DC converter controllers with built-in high speed, low ON resistance drivers.Large output currents are possible using an externally connected transistor, coil, diode and capacitor.Output voltage is selectable in 100mV increments within a range of 1.5V ~ 6.5V (±2.5%). For output voltages outside this range, we recommend FB version, which has a 1.0V internal reference voltage. Using the FB version, the required output voltage can be set-up using 2 external resistors.With a 300kHz oscillation frequency, the size of the external components can be reduced.Control switches from PWM to PFM during light loads with the XC6368 (PWM/PFM switchable) and the series is highly efficient from light loads to large output currents. Soft start time of XC6367/68A, B, and C series is internally set to 10msec and XC6367/68C, D, and F series regulate soft-start time by connecting resistors and capacitors externally.During stand-by (CE pin "Low"), supply current is reduced to less than 0.5μA.■APPLICATIONS●Electronic information organizers ●Palmtops●Cellular and portable phones ●Portable audio systems●Various multi-function power supplies■TYPICAL APPLICATION CIRCUIT■ TYPICAL PERFORMANCECHARACTERISTICS■FEATURESInput Voltage Range: 0.9V ~ 10VOperating Voltage Range : 2.0V ~ 10VOutput voltage Range : 1.5V ~ 6.5V programmable in 100mV increments (±2.5%) Oscillation Frequency : 300kHz, 100kHz (±15%)Custom products for 180kHz, 500kHzOutput Current : More than 200mA (V IN =1.8V, V OUT =3.3V) High Efficiency : 84% (TYP .)Stand-by capability : ISTB =0.5μA (MAX.)Selection: Soft-start set-up externalOutput voltage set-up internal(V OUT )Output voltage set-up external(FB) Package : SOT-25☆GO-Compatible554XC6367/6368 SeriesPIN NUMBER XC6367/XC6368 A, B, C, DE, F PIN NAMEFUNCTION55EXT: External Transistor Connection 2 - V DD: Supply Voltage Input4 4 GND : Ground3 1 CE: Chip Enable(C, D, F Types: Soft Start External Set-Up, Soft Start Capacitor Connected) 1 2V OUT(FB): Output Voltage Monitor(E, F Types: Output Voltage Monitor, Power Supply) (B, D Types: Output Voltage External Set-up)■PIN CONFIGURATION■PIN ASSIGNMENT■PRODUCT CLASSIFICATION●Selection Guide（）XC6367A,XC6368A XC6367E,XC6368E XC6367B,XC6368BXC6367C,XC6368C XC6367F,XC6368F XC6367D,XC6368D555XC6367/6368SeriesDESIGNATORDESCRIPTIONSYMBOLDESCRIPTIONA : V OUT type: V OUT internally set-up, Soft-start internally set-up B: FB type: V OUT externally set-up, Soft-start internally set-up C : V OUT type: V OUT internally set-up, Soft-start externally set-up D: FB type: V OUT externally set-up, Soft-start externally set-upE : V OUT type: V OUT internally set-up, Soft-start internally set-up ①Type of DC/DC ConverterF : V OUT type: V OUT internally set-up, Soft-start externally set-up 15 ~ 65: V OUT type: 3.0V output → ②=3, ③=0② ③Output Voltage10: FB type (B, D types): 10 fixed →②=1, ③=0 fixed 3 : 300kHz1 : 100kHz2 : 180kHz (Custom) ④Oscillation Frequency5: 500kHz (Custom) ⑤ Package M : SOT-25 (SOT-23-5)R : Embossed tape, standard feed ⑥Device OrientationL: Embossed tape, reverse feed■PACKAGING INFORMATION●Ordering Information■PRODUCT CLASSIFICATION (Continued)XC6367①②③④⑤⑥ PWM ControlXC6368①②③④⑤⑥ PWM/PFM Switching Control556XC6367/6368SeriesMARKPRODUCT SERIESMARKPRODUCT SERIESA XC6367A K XC6368AB XC6367B L XC6368BC XC6367C M XC6368CD XC6367D N XC6368DE XC6367E P XC6368EF XC6367F R XC6368FOSCILLATION FREQUENCY (kHz)OUTPUT VOLTAGE (V)100180 3005001 B 1 1 B2 C 2 2 C3 D 3 3 D4 E 4 4 E5 F 5 5 F6 H 6 6 HFOR CUSTOM PRODUCT S OSCILLATION FREQUENCY (kHz)OUTPUT VOLTAGE (V)100180 3005000 0 0 A A1 1 1 B B2 2 2 C C3 3 3 D D4 4 4 E E5 5 5 F F6 6 6 H H7 7 7 K K8 8 8 L L9 9 9 M M■MARKING RULE●XC6367/6368 Series ①Represents product series②Represents integer of output voltage and oscillation frequency③Represents decimal number of output voltage and oscillation frequency ④Represents production lot number0 to 9, A to Z repeated (G, I, J, O, Q, W excepted)SOT-25 (TOP VIEW)557XC6367/6368Series■BLOCK DIAGRAMSGNDEXT V DDV OUTCEXC6367, XC6368 Series A, C, E,F types (V OUT )Note :Connecting V OUT and V DD internally with E F types.GNDEXTV DDFBCEXC6367, XC6368 Series B,D types (FB)GND558XC6367/6368 SeriesPARAMETER SYMBOL RATINGS UNITS V DD Pin Voltage V DD -0.3 ~ +12.0 V V OUT Pin Voltage V OUT -0.3 ~ +12.0 V FB Pin Voltage V FB -0.3 ~ +12.0 V CE Pin Voltage V CE -0.3 ~ +12.0 VEXT Pin Voltage V EXT -0.3 ~ V DD +0.3 V EXT Pin Current I EXT ±100mA Power Dissipation Pd 150 mW Operating Temperature Range Topr -30 ~ +80 ℃Storage Temperature Range Tstg -40 ~ +125 ℃PARAMETERSYMBOL CONDITIONS MIN. TYP . MAX.UNITS Output Voltage V OUT 3.218 3.300 3.383V Supply Voltage (* 1) V DD 2.0 - 10.0V Maximum Input Voltage V IN 10.0 - - V Oscillation Start Voltage 1 V ST1 Tr: 2SD1628, I OUT =1.0mA - - 0.9 V Oscillation Start Voltage 2 V ST2 V OUT =CE: Apply voltage - - 0.8 V Oscillation Hold VoltageV HLD Tr: Use of a 2SX1628, I OUT =1.0mA - - 0.7 V Supply Current 1 I DD1 V OUT =CE=setting output voltage x 0.95 - 130 200 μA Supply Current 2 I DD2 V OUT =CE=setting output voltage + 0.5V - 20 35 μA Stand-by Current I STB V OUT =setting output voltage x 0.95, CE=0V - - 0.5 μA Oscillator Frequency FOSC Same as I DD1 255 300 345 kHz Maximum Duty Ratio MAXDTY Same as I DD1 78 85 92 % PFM Duty Ratio (* 3) PFMDTY I OUT =0mA 15 25 35 % CE "High" Voltage V CEH V OUT =setting output voltage x0.95 0.65 - - V CE "Low" VoltageV CEL V OUT =setting output voltage x0.95 - - 0.20V EXT "High" ON Resistance R EXTH Same as I DD1, VEXT=V OUT -0.4V - 29 43 Ω EXT "Low" ON ResistanceR EXTL Same as I DD1, V EXT =0.4V - 19 27 Ω Efficiency (* 2) EFFI - 84 - % Soft-Start TimeT SS 5 10 20 msec■ABSOLUTE MAXIMUM RATINGSTa = 25℃■ELECTRICAL CHARACTERISTICSXC6367A333MR, XC6368A333MR Conditions: Unless otherwise stated, connect V DD to V OUT ; V IN =setting output voltage x 0.6, I OUT =130mANOTE:* 1: When taking V DD from another power source please ensure that V DD = 2.0V or more.Oscillation will occur with a value of V DD = 0.8V or more, but with a value of V DD = 2.0V or more, output voltage and oscillation frequency will be stable.* 2: EFFI = {[(output voltage) x (output current)]÷[(input voltage) x (input current)] x 100* 3: Applies to the XC6368 series only (duty ratio when control changes to PFM).V OUT =3.3V, FOSC=300kHz, Ta=25℃*Voltage is all ground standardized.559XC6367/6368SeriesPARAMETER SYMBOL CONDITIONS MIN. TYP . MAX.UNITSOutput Voltage V OUT 4875 5.000 5.125V Supply Voltage (* 1) V DD 2.0 - 10.0V Maximum Input Voltage V IN 10.0 - - V Oscillation Start Voltage 1 V ST1 Tr: 2SD1628, I OUT =1.0mA - - 0.9 V Oscillation Start Voltage 2 V ST2 V OUT =CE : Apply voltage - - 0.8 V Oscillation Hold Voltage V HLD Tr: 2SD1628, I OUT =1.0mA - - 0.7 VSupply Current 1 I DD1 V OUT =CE=setting output voltage x 0.95 - 180 280 μA Supply Current 2 I DD2 V OUT =CE=setting output voltage + 0.5V - 22 38 μA Stand-by Current I STB V OUT =setting output voltage x 0.95, CE=0V - - 0.5 μA Oscillation Frequency FOSC Same as I DD1 255 300 345 kHz Maximum Duty Ratio MAXDTY Same as I DD1 78 85 92 % PFM Duty Ratio (* 3) PFMDTY I OUT =0mA 15 25 35 % CE "High" Voltage V CEH V OUT =setting output voltage x0.95 0.65 - - V CE "Low" Voltage V CEL V OUT =setting output voltage x0.95 - - 0.20V EXT "High" ON Resistance R EXTH Same as I DD1, V EXT =V OUT -0.4V - 20 29 Ω EXT "Low" ON Resistance R EXTL Same as I DD1, V EXT =0.4V - 13 19 ΩEfficiency (* 2) EFFI - 87 - %Soft-Start Time T SS Connect R SS and C SS , CE:0V →3.0V(XC6367C/F and XC6368C/F series)5 10 20 msec XC6367A503MR, XC6368A503MRConditions: Unless otherwise specified, connect V DD to V OUT ; V IN =setting output voltage x 0.6, I OUT =200mA NOTE: * 1: When taking V DD from another power source please ensure that V DD = 2.0V or more.Oscillation will occur with a value of V DD = 0.8V or more, but with a value of V DD = 2.0V or more, output voltage and oscillation frequency will be stable.* 2: EFFI = {[(output voltage) x (output current)]÷[(input voltage) x (input current)] x 100* 3: Applies to the XC6368 series only (duty ratio when control changes to PFM).* 4: The values of supply voltage and NOTE *1 do not apply to XC6367E/F and XC6368E/F series. For XC6367E/F andXC6368E/F series, output voltage less than 2.0V cannot be set-up.V OUT =5.0V, FOSC=300kHz,Ta=25℃■ELECTRICAL CHARACTERISTICS (Continued)560XC6367/6368 SeriesPARAMETER SYMBOL CONDITIONS MIN. TYP . MAX.UNITS Output Voltage V OUT 2.925 3.000 3.075V Supply Voltage (* 1) V DD 2.0 - 10.0V Maximum Input Voltage V IN 10.0 - - V Oscillation Start Voltage 1 V ST1 Tr: 2SD1628, I OUT = 1.0mA - - 0.9 V Oscillation Start Voltage 2 V ST2 V DD =CE: Apply voltage, FB=0V - - 0.8 V Oscillation Hold Voltage V HLD Tr: 2SD1628, I OUT = 1.0mA - - 0.7 VSupply Current 1 I DD1 V DD =CE = 2.85V,FB =0V - 120 190 μA Supply Current 2 I DD2 V DD =CE = 3.5V,FB =1.2V - 20 34 μA Stand-by Current I STB V DD =2.85V, CE=0V, FB=0V - - 0.5 μA Oscillation Frequency FOSC Same as I DD1 255 300 345 kHz Maximum Duty Ratio MAXDTY Same as I DD1 78 85 92 % PFM Duty Ratio (* 3) PFMDTY I OUT =0mA 15 25 35 % CE "High" Voltage V CEH V DD =2.85V,FB =0V 0.65 - - V CE "Low" Voltage V CEL V DD = 2.85V,FB =0V - - 0.20V EXT "High" ON Resistance R EXTH Same as I DD1, V EXT =V DD -0.4V - 32 47 Ω EXT "Low" ON Resistance R EXTL Same as I DD1, V EXT =0.4V - 20 30 ΩEfficiency (* 2) EFFI - 84 - % Soft-Start Time T SS Connect R SS and C SS ,CE:0V →3.0V (XC6367D/68D series)5 10 20 msecXC6367B103MR, XC6368B103MRV OUT =3.0V , FOSC=300kHz, Ta=25℃Conditions: Unless otherwise stated, V IN =1.8V, I OUT =120mA External components : R FB1 = 400kΩ, R FB2 = 200k Ω, C FB = 47pF NOTE:* 1: When taking V DD from another power source please ensure that V DD = 2.0V or more.Oscillation will occur with a value of V DD = 0.8V or more, but with a value of VDD = 2.0V or more, output voltage and oscillation frequency will be stable.* 2: EFFI = {[(output voltage) x (output current)]÷[(input voltage) x (input current)] x 100* 3: Applies to the XC6368 series only (duty ratio when control changes to PFM).■ELECTRICAL CHARACTERISTICS (Continued)561XC6367/6368SeriesPARAMETER SYMBOL CONDITIONS MIN. TYP . MAX.UNITSOutput Voltage V OUT 3.218 3.300 3.383V Supply Voltage (* 1) V DD 2.0 - 10.0V Maximum Input Voltage V IN 10.0 - - V Oscillation Start Voltage 1 V ST1 Tr: 2SD1628, I OUT =1.0mA - - 0.9 V Oscillation Start Voltage 2 V ST2 V OUT =CE: Apply voltage - - 0.8 V Oscillation Hold Voltage V HLD Tr: 2SD1628, I OUT =1.0mA - - 0.7 VSupply Current 1 I DD1 V OUT =CE=setting output voltage x 0.95 - 50 100 μA Supply Current 2 I DD2 V OUT =CE=setting output voltage + 0.5V - 11 20 μA Stand-by Current I STB V OUT =setting output voltage x 0.95, CE=0V - - 0.5 μA Oscillation Frequency FOSC Same as I DD1 85 100 115 kHz Maximum Duty Ratio MAXDTY Same as I DD1 78 85 92 % PFM Duty Ratio (* 3) PFMDTY I OUT =0mA 15 25 35 % CE "High" Voltage V CEH V OUT =setting output voltage x0.95 0.65 - - V CE "Low" Voltage V CEL V OUT =setting output voltage x0.95 - - 0.20V EXT "High" ON Resistance R EXTH Same as I DD1, V EXT =V OUT -0.4V - 29 43 Ω EXT "Low" ON Resistance R EXTL Same as I DD1, V EXT =0.4V - 19 27 ΩEfficiency (* 2) EFFI - 84 - %Soft-Start Time T SS 5 10 20 msecConditions: Unless otherwise stated, connect V DD to V OUT ; V IN =setting output voltage x 0.6, I OUT =130mANOTE:* 1: When taking V DD from another power source please ensure that V DD = 2.0V or more.Oscillation will occur with a value of V DD = 0.8V or more, but with a value of V DD = 2.0V or more, output voltage and oscillation frequency will be stable. * 2: EFFI = {[(output voltage) x (output current)]÷[(input voltage) x (input current)] x 100* 3: Applies to the XC6368 series only (duty ratio when control changes to PFM).XC6367A331MR, XC6368A331MRV OUT =3.3V, FOSC=100kHz, Ta=25℃■ELECTRICAL CHARACTERISTICS (Continued)562XC6367/6368 SeriesPARAMETER SYMBOL CONDITIONS MIN. TYP . MAX.UNITSOutput Voltage V OUT 4875 5.000 5.125V Supply Voltage (* 1) V DD 2.0 - 10.0V Maximum Input Voltage V IN 10.0 - - V Oscillation Start Voltage 1 V ST1 Tr: 2SD1628, I OUT =1.0mA - - 0.9 V Oscillation Start Voltage 2 V ST2 V OUT =CE: Apply voltage - - 0.8 V Oscillation Hold Voltage V HLD Tr: 2SX1628, I OUT =1.0mA - - 0.7 VSupply Current 1 I DD1 V OUT =CE=setting output voltage x 0.95 - 70 120 μA Supply Current 2 I DD2 V OUT =CE=setting output voltage + 0.5V - 11 22 μA Stand-by Current I STB V OUT =setting output voltage x 0.95, CE=0V - - 0.5 μA Oscillation Frequency FOSC Same as I DD1 85 100 115 kHz Maximum Duty Ratio MAXDTY Same as I DD1 78 85 92 % PFM Duty Ratio (* 3) PFMDTY I OUT =0mA 15 25 35 % CE "High" Voltage V CEH V OUT =setting output voltage x0.95 0.65 - - V CE "Low" Voltage V CEL V OUT =setting output voltage x0.95 - - 0.20V EXT "High" ON Resistance R EXTH Same as I DD1, V EXT =V OUT -0.4V - 20 29 Ω EXT "Low" ON Resistance R EXTL Same as I DD1, V EXT =0.4V - 13 19 ΩEfficiency (* 2) EFFI - 87 - %Soft-Start Time T SS 5 10 20 msecConditions: Unless otherwise stated, connect V DD to V OUT ; V IN =setting output voltage x 0.6, I OUT =200mANOTE:* 1: When taking V DD from another power source please ensure that V DD = 2.0V or more.Oscillation will occur with a value of V DD= 0.8V or more, but with a value of V DD = 2.0V or more, output voltage and oscillation frequency will be stable. * 2: EFFI = {[(output voltage) x (output current)]÷[(input voltage) x (input current)] x 100* 3: Applies to the XC6368 series only (duty ratio when control changes to PFM).XC6367A501MR, XC6368A501MRV OUT =5.0V, FOSC=100kHz, Ta=25℃■ELECTRICAL CHARACTERISTICS (Continued)563PARAMETER SYMBOL CONDITIONS MIN. TYP . MAX.UNITSOutput Voltage V OUT 2.925 3.000 3.075V Supply Voltage (* 1) V DD 2.0 - 10.0V Maximum Input Voltage V IN 10.0 - - V Oscillation Start Voltage 1 V ST1 Tr: 2SD1628, I OUT =1.0mA - - 0.9 V Oscillation Start Voltage 2 V ST2 V DD =CE: Apply voltage, FB=0V - - 0.8 V Oscillation Hold Voltage V HLD Tr: 2SD1628, I OUT = 1.0mA - - 0.7 VSupply Current 1 I DD1 V DD =CE=2.85V, FB=0V - 50 90 μA Supply Current 2 I DD2 V DD =CE=3.5V, FB=1.2V - 11 20 μA Stand-by Current I STB V DD =2.85V, CE=0V, FB=0V - - 0.5 μA Oscillation Frequency FOSC Same as I DD1 85 100 115 kHz Maximum Duty Ratio MAXDTY Same as I DD1 78 85 92 % PFM Duty Ratio (*3) PFMDTY I OUT =0mA 15 25 35 % CE "High" Voltage V CEH V DD =2.85V,FB=0V 0.65 - - V CE "Low" Voltage V CEL V DD =2.85V,FB=0V - - 0.20V EXT "High" ON Resistance R EXTH Same as I DD1, V EXT =V DD -0.4V - 32 47 Ω EXT "Low" ON Resistance R EXTL Same as I DD1, V EXT =0.4V - 20 30 ΩEfficiency (* 2) EFFI - 84 - %Soft-Start Time T SS 5 10 20 msec XC6367B101MR, XC6368B101MRV OUT =3.0V, FOSC=100kHz, Ta=25℃Conditions: Unless otherwise stated, V IN =1.8V, I OUT =120mAExternal components : R FB 1 = 400k Ω, R FB 2 = 200k Ω, C FB = 47pFNOTE:* 1: When taking V DD from another power source please ensure that V DD = 2.0V or more.Oscillation will occur with a value of V DD = 0.8V or more, but with a value of VDD = 2.0V or more, output voltage and oscillation frequency will be stable.* 2: EFFI = {[(output voltage) x (output current)]÷[(input voltage) x (input current)] x 100* 3: Applies to the XC6368 series only (duty ratio when control changes to PFM).■ELECTRICAL CHARACTERISTICS (Continued)564■TEST CIRCUITS565■TEST CIRCUITS (Continued)566■TEST CIRCUITS (Continued)567■TEST CIRCUITS (Continued)568GATE PROTECTION DIODE BUILT-IN MOSFETR ds (ON)XP161A1355PR 0.15Ω@ Vgs=1.5V XP161A1265PR0.095Ω@ Vgs=2.5VTr: XP161A1355PR (N-ch Power MOSFET, TOREX)As the breakdown voltage of XP161A1355PR is 8V, take carewith the power supply voltage. With output voltages over 6V, use the XP161A1265PR with a breakdown voltage of 12V. V ST1 : XP161A1355PR = 1.2V (MAX.) XP161A1265PR = 1.5V (MAX.) L : 22μH (CR54, SUMIDA FOSC=300kHz) 47μH (CR75, SUMIDA FOSC=100, 180kHz) 10μH (CR54, SUMIDA FOSC=500kHz) SD : MA2Q735 (Schottky Diode, SUMIDA MATSUSHITA) C IN : 16V, 220μF (Aluminium Electrolytic Capacitor) CL : 16V, 47μF + 47μF (Tantalum capacitor, NICHICON MCE)NPN Tr type:Tr : 2SD1628 (SANYO) Rb : 500Ω(Adjust according to load and Tr. hFE levels) Cb : 2200pF (Ceramic Type) Set up so that CB < 1÷(2πx RB x FOSC x 0.7)C, D, F type (soft-start externally set-up):C SS :0.1μF (Ceramic Capacitor) R SS : 470k Ω(C, F Type), 220k Ω(D Type) B, D type (FB versions)R FB: Set up so that R FB1÷R FB2 = V OUT - 1 (V OUT = setting output voltage), Please use with R FB1 + R FB2 ≦2M Ω C FB : Set up so that fzfb = 1÷(2 x πx CFB x RFB1) is within the 0.1 to 20kHz range (10kHz conventional) Adjustments necessary in respect of L, C L . e.g V OUT = 3.0V R FB1 = 400k Ω, R FB2 = 200k Ω, C FB = 47pFFor using MOSFET, We recommend using TOREX MOSFETs, which has a gate protection diode built-in.■TEST CIRCUITS (Continued)●External Components569■NOTES ON USE1. Take ample care to ensure that none of the IC's, nor the external component's, absolute maximum ratings areexceeded.2. Be extremely careful when selecting parts and do not limit your reference to the specifications and characteristics for the DC/DC converter alone. The IC also depends, to a great extent, upon the external components.3. Arrange the peripherals in the environs of the IC. In order to reduce wiring impedance, use short, thick wires. In particular, wire the load capacitor as close as possible and strengthen the ground wiring sufficiently.4. Ground current during switching may cause the IC's operations to become unstable due to changes in ground voltage,so please strengthen the IC's GND pin surroundings.●External Components1.Setting soft-start timeIn oder to lengthen soft-start time we recommend that you use the C or D types of the series which have soft start time externally set-up.Soft-start time (T SS ) is between MIN & MAX, as indicated in the graphs below, so please select soft-start capacitor value (C SS ) to suit your application.2. R FB1, C FB set upfzfb = 1 ÷ ( 2πx C FB x R FB1 )In order to achieve a value for fzfb within the range of 0.1kHz to 20kHz, we recommend that values for R FB1 & C FBare selected from the area indicated within the lines of fzfb = 0.1kHz and fzfb = 20 kHz as shown on the graph below. Please select combinations of values as close to the fzfb = 10kHz line as possible.570■TYPICAL PERFORMANCE CHARACTERISTICS(1) Output Voltage vs. Output Current571■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)(1) Output Voltage vs. Output Current (Continued)572■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)(2) Efficiency vs. Output Current■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)(2) Efficiency vs. Output Current (Continued)573574(3) Ripple Voltage vs. Output Current ■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)575(3) Ripple Voltage vs. Output Current (Continued)■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)(4) Output Voltage vs. Ambient Temperature (5) Supply Current 1 vs. Ambient Temperature(6) Supply Current 2 vs. Ambient Temperature (7) Stand-by Current vs. Ambient Temperature(8) EXT "H" On Resistance vs. Ambient Temperature (9) EXT "L" On Resistance vs. Ambient Temperature 576■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)(10) Oscillation Frequency vs. Ambient Temperature (11) Maximum Duty Ratio vs. Ambient Temperature(12) PFM Duty Ratio vs. Ambient Temperature (13) Efficiency vs. Ambient Temperature(14) Operation Start Voltage vs. Ambient Temperature (15) Operation Hold Voltage vs. Ambient Temperature577■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)(16) Oscillation Start Voltage vs. Ambient Temperature (17) Soft-Start Time vs. Ambient Temperature(18) CE "L" Voltage vs. Ambient Temperature (19) CE "H" Voltage vs. Ambient Temperature 578■TYPICAL PERFORMANCE CHARACTERISTICS (Continued)(20) Load Transient Response579。

VMC系列立式加工中心使用说明书（电器部分）中华人民共和国注意事项．．．．1：用户提供给本机床的电源：电压偏差，频率偏差，最小额定容量必须与本机床要求相符。

若不符合，用户必须对供电进行处理，机床方可投入运行。

否则因电源不符合要求所造成的损坏、故障，本公司概不负责。

2：该机床的所有参数，如PLC参数，NC参数，机床参数等用户不得随意更改。

否则因参数改变而造成的机床故障，本公司概不负责。

3：用户对本机床功能有其他特殊要求，必须在订货时说明。

4：电柜内系统的所有开关位置出厂时已调好，用户切勿调整，否则会引起机床数据丢失，机床无法正常工作由此操作引起的后果，用户必须自行负责。

5：用户使用该机床前请详细阅读《操作编程》用户手册，阅读本机床的《使用说明书》机械部分及电器部分。

6：机床开机必须先使坐标轴回参考点。

7：使用RS232通讯接口时，必须执行本说明书第6章中的技术要求，否则会造成设备损坏，严禁带电插拔．．．．．．。

．．．．．接口上的接头．．．．．．PC．．及系统．．．RS2328：使用冷却泵前，必须确保冷却箱冷却液足够。

第一次使用冷却泵时，必须给冷却泵密封盒内加冷却液。

9：转动主轴时，必须确保刀具夹紧，方可转动主轴。

10：机床润滑单元的储油罐缺润滑油，禁止机床运转。

11：机床在做定期检修时，为了使系统正常运行切记对每个电柜下方的防尘窗内的防尘网进行清尘处理。

12：将电源从控制箱底部的进线孔接入，接到R、S、T端子上，E为接地端子，机床必须接地以防止漏电而发生事故。

机床电源相序调整机床接入电源后，在第一次运行前，应进行相序的调整：1：给集中润滑单元储油罐加润滑油；2：机床上电；3：NC上电，消除机床报警；4：机床工作在JOG方式下；5：在机床未装刀库时按下冷却启动键，观察冷却泵旋向：如果冷却泵实际旋向与泵的指示旋向一致，则相序正确，不用调整；如果冷却泵实际旋向与泵的指示旋向不一致，则相序不正确，调整电源进线的相序；6：在机床装刀库时，按下刀库步进键，自机床顶端向下看，观察刀库旋向：若刀库旋向为逆时针，则相序正确，不用调整；若刀库旋向为顺时针，则相序不正确，需调整电源进线的相序；7：相序调整正确后，机床可以工作。