ES6425AV中文资料

Product information is current as of publication date. The product conforms Copyright © 2007, Pletronics Inc.SM44T Series 3.3 VCMOS Clock Oscillators September 2008•Pletronics’ SM44 Series is a quartz crystalcontrolled precision square wave generator with a CMOS output.•The package is designed for high density surface mount designs.•This is a low cost mass produced oscillator.•Tape and Reel or cut tape packaging is available.•0.8 to 180 MHZ• 2.5 x 3.2 mm LCC Ceramic Package •Enable/Disable Function •Disable functionincludes low standby power mode•Low JitterPletronics Inc. certifies this device is in accordance with the RoHS 6/6 (2002/95/EC) and WEEE (2002/96/EC) directives.Pletronics Inc. guarantees the device does not contain the following:Cadmium, Hexavalent Chromium, Lead, Mercury, PBB’s, PBDE’s Weight of the Device: 0.041 gramsMoisture Sensitivity Level: 1 As defined in J-STD-020C Second Level Interconnect code: e4Absolute Maximum Ratings:ParameterUnitV CC Supply Voltage -0.5V to +7.0V Vi Input Voltage -0.5V to V CC + 0.5V Vo Output Voltage -0.5V to V CC + 0.5V Io Output Current+25 mA to -25 mAThermal CharacteristicsThe maximum die or junction temperature is 155o CThe thermal resistance junction to board is 40 to 60o C/Watt depending on the solder pads, ground plane and construction of the PCB.September 2008 Part Number:SM4445T E V-75.0M-XX Part Marking:Packaging code or blankT250 = 250 per Tape and Reel T500 = 500 per Tape and Reel T1K = 1000 per Tape and Reel P FF.FFF C YMDxxFrequency in MHzSupply Voltage VCCV = 3.3V +_ 10%Temperature RangeBlank = Temp. range -10 to +70o CE = Temp. range -40 to +85o CSeries ModelFrequency Stability45 = +_ 50 ppm44 = +_ 25 ppm20 = +_ 20 ppmSeries ModelMarking Legend:P= PletronicsFF.FFF= Frequency in MHZYMD = Date of Manufacture (year and week, or year-month-day)All other marking is internal factory codesSpecifications such as frequency stability, supply voltage and operating temperature range, etc. are not identified from the marking. External packaging labels and packing list will correctly identify the ordered Pletronics part number.Codes for Date Code YMDCode6789012Year2006200720082009201020112012Code A B C D E F G H J K L M Month JAN FEB MAR APR MAY JUN JUL AUG SEP OCT NOV DEC Code123456789A B C Day123456789101112 Code D E F G H J K L M N P R Day131415161718192021222324 Code T U V W X Y ZDay25262728293031September 2008-180-160-140-120-100-80-60-40-200101,000100,00010,000,000Frequency (Hz)d B c /H zElectrical Specification for 3.30V +_10% over the specified temperature rangeItemMin Max Unit ConditionFrequency Range0.8180MHZ Frequency Accuracy “45"-50+50ppmFor all supply voltages, load changes, aging for 1year, shock, vibration and temperatures“44"-25+25Output Waveform CMOS Output High Level 90-%of V CC (See load circuit)Output Low Level -10%Output Symmetry 4555%at 50% point of V CCJitter-0.6pS RMS 12 KHz to 20 MHZ from the output frequency - 2.5pS RMS 10 Hz to 1 MHZ from the output frequency Enable/Disable Internal Pull-up 50-Kohm to V CCV disable -30%of V CC applied to pad 1V enable70-%Output leakage V OUT = V CC -10+10uA Pad 1 low, device disabledV OUT = 0V -10+10uA Standby Current I CC -3uA Enable time -100nS Time for output to reach a logic state Disable time -100nS Time for output to reach a high Z state Start up time-3mSTime for output to reach specified frequency Operating Temperature Range -10+70o C Standard Temperature Range-40+85o C Extended Temperature Range “E ” OptionStorage Temperature Range-55+125oCTypical phase noise plot for 5 oscillators at different output frequencies.September 2008Electrical Specification for 3.30V +_10% over the specified temperature rangeItemTyp Max Unit Condition Output T RISE and T FALL2.55nS < 35 MHZC LOAD = 15 pF10% to 90% of V CC See Load Circuit1.53nS > 35 MHZ and < 70MHz 12nS > 70 MHZ 48nS < 35 MHZC LOAD =30 pF10% to 90% of V CC See Load Circuit 35nS > 35 MHZ and < 70MHz 23nS > 70 MHZ V CC Supply Current (I CC )24mA < 8 MHZC LOAD = 15 pF 35mA > 8 MHZ and < 16 MHZ 46mA > 16 MHZ and < 35 MHZ 1218mA > 35 MHZ and < 70MHz 2336mA> 70 MHZ and < 110MHz4570mA > 110 MHZ 35mA < 8 MHZ C LOAD = 30 pF 46mA > 8 MHZ and < 16 MHZ 68mA > 16 MHZ and < 35 MHZ 1622mA > 35 MHZ and < 70MHz 3043mA> 70 MHZ and < 120MHzSpecifications with Pad 1 E/D open circuitLoad Circuit and Test WaveformSeptember 2008Reliability:Environmental ComplianceParameter ConditionMechanical Shock MIL-STD-883 Method 2002, Condition BVibration MIL-STD-883 Method 2007, Condition ASolderability MIL-STD-883 Method 2003Thermal Shock MIL-STD-883 Method 1011, Condition AESD RatingModel Minimum Voltage ConditionsHuman Body Model1500MIL-STD-883 Method 3115Charged Device Model1000JESD 22-C101Package LabelingLabel is 1" x 2.6" (25.4mm x 66.7mm)Label is 1" x 2.6" (25.4mm x 66.7mm)Font is Courier New Font is ArialBar code is 39-Full ASCIISeptember 2008Not to Scale1 Typical dimensionsContacts :Gold 11.8 µinches 0.3 µm minimum over Nickel 50 to 350 µinches 1.27 to 8.89 µmPad Function Note1OutputEnable/Disable When this pad is not connected the oscillator shall operate.When this pad is logic low the output will be inhibited (high impedance state.)Recommend connecting this pad to V CC if the oscillator is to be always on.2Ground (GND)3Output 4Supply Voltage (V CC )Recommend connecting appropriate power supply bypass capacitors as close as possible.Layout and application informationFor Optimum Jitter Performance, Pletronics recommends:• a ground plane under the device •no large transient signals (both current and voltage) should be routed under the device •do not layout near a large magnetic field such as a high frequency switching power supply •do not place near piezoelectric buzzers or mechanical fans.September 2008Tape and Reel: available for quantities of 250 to 1000 per reel, cut tape for < 250September 2008IMPORTANT NOTICEPletronics Incorporated (PLE) reserves the right to make corrections, improvements, modifications and other changes to this product at anytime. PLE reserves the right to discontinue any product or service without notice. Customers are responsible for obtaining the latest relevant information before placing orders and should verify that such information is current and complete. All products are sold subject to PLE’s terms and conditions of sale supplied at the time of order acknowledgment.PLE warrants performance of this product to the specifications applicable at the time of sale in accordance with PLE’s limited warranty. Testing and other quality control techniques are used to the extent PLE deems necessary to support this warranty. Except where mandated by specific contractual documents, testing of all parameters of each product is not necessarily performed.PLE assumes no liability for application assistance or customer product design. Customers are responsible for their products and applications using PLE components. To minimize the risks associated with the customer products and applications, customers should provide adequate design and operating safeguards.PLE products are not designed, intended, authorized or warranted to be suitable for use in life support applications, devices or systems or other critical applications that may involve potential risks of death, personal injury or severe property or environmental damage. Inclusion of PLE products in such applications is understood to be fully at the risk of the customer. Use of PLE products in such applications requires the written approval of an appropriate PLE officer. Questions concerning potential risk applications should be directed to PLE.PLE does not warrant or represent that any license, either express or implied, is granted under any PLE patent right, copyright, artwork or other intellectual property right relating to any combination, machine or process which PLE product or services are used. Information published by PLE regarding third-party products or services does not constitute a license from PLE to use such products or services or a warranty or endorsement thereof. Use of such information may require a license from a third party under the patents or other intellectual property of the third party, or a license from PLE under the patents or other intellectual property of PLE.Reproduction of information in PLE data sheets or web site is permissible only if the reproduction is without alteration and is accompanied by associated warranties, conditions, limitations and notices. Reproduction of this information with alteration is an unfair and deceptive business practice. PLE is not responsible or liable for such altered documents.Resale of PLE products or services with statements different from or beyond the parameters stated by PLE for that product or service voids all express and implied warranties for the associated PLE product or service and is an unfair or deceptive business practice. PLE is not responsible for any such statements.Contacting Pletronics Inc.Pletronics Inc.Tel: 425-776-188019013 36th Ave. West Fax: 425-776-2760Lynnwood, WA 98036-5761 USA E-mail: ple-sales@URL: Copyright © 2007, 2008, Pletronics Inc.。

General DescriptionThe MAX481, MAX483, MAX485, MAX487–MAX491, andMAX1487 are low-power transceivers for RS-485 and RS-422 communication. Each part contains one driver and onereceiver. The MAX483, MAX487, MAX488, and MAX489feature reduced slew-rate drivers that minimize E MI andreduce reflections caused by improperly terminated cables,thus allowing error-free data transmission up to 250kbps.The driver slew rates of the MAX481, MAX485, MAX490,MAX491, and MAX1487 are not limited, allowing them totransmit up to 2.5Mbps.These transceivers draw between 120µA and 500µA ofsupply current when unloaded or fully loaded with disableddrivers. Additionally, the MAX481, MAX483, and MAX487have a low-current shutdown mode in which they consumeonly 0.1µA. All parts operate from a single 5V supply.Drivers are short-circuit current limited and are protectedagainst excessive power dissipation by thermal shutdowncircuitry that places the driver outputs into a high-imped-ance state. The receiver input has a fail-safe feature thatguarantees a logic-high output if the input is open circuit.The MAX487 and MAX1487 feature quarter-unit-loadreceiver input impedance, allowing up to 128 MAX487/MAX1487 transceivers on the bus. Full-duplex communi-cations are obtained using the MAX488–MAX491, whilethe MAX481, MAX483, MAX485, MAX487, and MAX1487are designed for half-duplex applications.________________________Applications Low-Power RS-485 Transceivers Low-Power RS-422 Transceivers Level Translators Transceivers for EMI-Sensitive Applications Industrial-Control Local Area Networks__Next Generation Device Features o For Fault-Tolerant Applications MAX3430: ±80V Fault-Protected, Fail-Safe, 1/4Unit Load, +3.3V, RS-485 Transceiver MAX3440E–MAX3444E: ±15kV ESD-Protected,±60V Fault-Protected, 10Mbps, Fail-Safe, RS-485/J1708 Transceivers o For Space-Constrained Applications MAX3460–MAX3464: +5V, Fail-Safe, 20Mbps,Profibus RS-485/RS-422 Transceivers MAX3362: +3.3V, High-Speed, RS-485/RS-422Transceiver in a SOT23 Package MAX3280E–MAX3284E: ±15kV ESD-Protected,52Mbps, +3V to +5.5V, SOT23, RS-485/RS-422,True Fail-Safe Receivers MAX3293/MAX3294/MAX3295: 20Mbps, +3.3V,SOT23, RS-485/RS-422 Transmitters o For Multiple Transceiver Applications MAX3030E–MAX3033E: ±15kV ESD-Protected,+3.3V, Quad RS-422 Transmitters o For Fail-Safe Applications MAX3080–MAX3089: Fail-Safe, High-Speed (10Mbps), Slew-Rate-Limited RS-485/RS-422Transceiverso For Low-Voltage ApplicationsMAX3483E/MAX3485E/MAX3486E/MAX3488E/MAX3490E/MAX3491E: +3.3V Powered, ±15kVESD-Protected, 12Mbps, Slew-Rate-Limited,True RS-485/RS-422 Transceivers For pricing, delivery, and ordering information, please contact Maxim Direct at1-888-629-4642, or visit Maxim Integrated’s website at .______________________________________________________________Selection Table19-0122; Rev 10; 9/14PARTNUMBERHALF/FULL DUPLEX DATA RATE (Mbps) SLEW-RATE LIMITED LOW-POWER SHUTDOWN RECEIVER/DRIVER ENABLE QUIESCENT CURRENT (μA) NUMBER OF RECEIVERS ON BUS PIN COUNT MAX481Half 2.5No Yes Yes 300328MAX483Half 0.25Yes Yes Yes 120328MAX485Half 2.5No No Yes 300328MAX487Half 0.25Yes Yes Yes 1201288MAX488Full 0.25Yes No No 120328MAX489Full 0.25Yes No Yes 1203214MAX490Full 2.5No No No 300328MAX491Full 2.5No No Yes 3003214MAX1487 Half 2.5No No Yes 2301288Ordering Information appears at end of data sheet.找电子元器件上宇航军工MAX481/MAX483/MAX485/MAX487–MAX491/MAX1487Low-Power, Slew-Rate-LimitedRS-485/RS-422 TransceiversPackage Information For the latest package outline information and land patterns, go to . Note that a “+”, “#”, or “-”in the package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing pertains to the package regardless of RoHS status.16Low-Power, Slew-Rate-Limited RS-485/RS-422 TransceiversMAX481/MAX483/MAX485/MAX487–MAX491/MAX1487Maxim Integrated cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim Integrated product. No circuit patent licenses are implied. Maxim Integrated reserves the right to change the circuitry and specifications without notice at any time. The parametric values (min and max limits) shown in the Electrical Characteristics table are guaranteed. Other parametric values quoted in this data sheet are provided for guidance.Maxim Integrated 160 Rio Robles, San Jose, CA 95134 USA 1-408-601-100017©2014 Maxim Integrated Products, Inc.Maxim Integrated and the Maxim Integrated logo are trademarks of Maxim Integrated Products, Inc.。

General DescriptionThe MAX6340/MAX6421–MAX6426 low-power micro-processor supervisor circuits monitor system voltages from 1.6V to 5V. These devices perform a single function:they assert a reset signal whenever the V CC supply volt-age falls below its reset threshold. The reset output remains asserted for the reset timeout period after V CC rises above the reset threshold. The reset timeout is exter-nally set by a capacitor to provide more flexibility.The MAX6421/MAX6424 have an active-low, push-pull reset output. The MAX6422 has an active-high,push-pull reset output and the MAX6340/MAX6423/MAX6425/MAX6426 have an active-low, open-drain reset output. The MAX6421/MAX6422/MAX6423 are offered in 4-pin SC70 or SOT143 packages. The MAX6340/MAX6424/MAX6425/MAX6426 are available in 5-pin SOT23-5 packages.ApplicationsPortable EquipmentBattery-Powered Computers/Controllers Automotive Medical Equipment Intelligent Instruments Embedded Controllers Critical µP Monitoring Set-Top Boxes ComputersFeatureso Monitor System Voltages from 1.6V to 5V o Capacitor-Adjustable Reset Timeout Period o Low Quiescent Current (1.6µA typ)o Three RESET Output OptionsPush-Pull RESET Push-Pull RESET Open-Drain RESET o Guaranteed Reset Valid to V CC = 1V o Immune to Short V CC Transientso Small 4-Pin SC70, 4-Pin SOT143, and 5-Pin SOT23Packages o MAX6340 Pin Compatible with LP3470o MAX6424/MAX6425 Pin Compatible with NCP300–NCP303, MC33464/MC33465,S807/S808/S809, and RN5VD o MAX6426 Pin Compatible with PST92XXMAX6340/MAX6421–MAX6426Low-Power, SC70/SOT µP Reset Circuits with Capacitor-Adjustable Reset Timeout Delay________________________________________________________________Maxim Integrated Products1Ordering InformationPin Configurations19-2440; Rev 2; 10/02For pricing, delivery, and ordering information,please contact Maxim/Dallas Direct!at 1-888-629-4642, or visit Maxim’s website at .Typical Operating Circuit appears at end of data sheet.Selector Guide appears at end of data sheet.Note: The MAX6340/MAX6421–MAX6426 are available with fac-tory-trimmed reset thresholds from 1.575V to 5.0V in approxi-mately 0.1V increments. Insert the desired nominal reset threshold suffix (from Table 1) into the blanks. There are 50 stan-dard versions with a required order increment of 2500 pieces.Sample stock is generally held on standard versions only (see Standard Versions Table). Required order increment is 10,000pieces for nonstandard versions. Contact factory for availability.All devices are available in tape-and-reel only.M A X 6340/M A X 6421–M A X 6426Low-Power, SC70/SOT µP Reset Circuits with Capacitor-Adjustable Reset Timeout Delay2_______________________________________________________________________________________ABSOLUTE MAXIMUM RATINGSELECTRICAL CHARACTERISTICSStresses 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.All Voltages Referenced to GNDV CC ........................................................................-0.3V to +6.0V SRT, RESET , RESET (push-pull).................-0.3V to (V CC + 0.3V)RESET (open drain)...............................................-0.3V to +6.0V Input Current (all pins)......................................................±20mA Output Current (RESET , RESET)......................................±20mAContinuous Power Dissipation (T A = +70°C)4-Pin SC70 (derate 3.1mW/°C above +70°C)..............245mW 4-Pin SOT143 (derate 4mW/°C above +70°C).............320mW 5-Pin SOT23 (derate 7.1mW/°C above +70°C)............571mW Operating Temperature Range .........................-40°C to +125°C Storage Temperature Range.............................-65°C to +150°C Junction Temperature......................................................+150°C Lead Temperature (soldering, 10s).................................+300°CMAX6340/MAX6421–MAX6426Low-Power, SC70/SOT µP Reset Circuits with Capacitor-Adjustable Reset Timeout Delay_______________________________________________________________________________________300.51.01.52.02.53.03.54.00213456SUPPLY CURRENT vs. SUPPLY VOLTAGESUPPLY VOLTAGE (V)S U P P L Y C U R R E N T (µA )0.1110010100010,0000.0010.10.011101001000RESET TIMEOUT PERIOD vs. C SRTM A X 6421/26 t o c 02C SRT (nF)R E S E T T I M E O U T P E R I O D(m s )4.104.204.154.254.30-50-25255075100125RESET TIMEOUT PERIOD vs. TEMPERATURETEMPERATURE (°C)R E S E T T I M E O U T P E R I O D (m s )RESET TIMEOUT PERIOD vs. TEMPERATURE200250350300500550450400600R E S E T T I M E O U T P E R I O D (µs )-5025-255075100125TEMPERATURE (°C)050251007515012517504002006008001000MAXIMUM TRANSIENT DURATION vs. RESET THRESHOLD OVERDRIVERESET THRESHOLD OVERDRIVE (mV)T R A N S I E N T D U R A T I O N (µs )V CCTO RESET DELAYvs. TEMPERATURE (V CC FALLING)8090110100140150130120160V C C T O R E S E T D E L A Y (µs )-5025-255075100125TEMPERATURE (°C)POWER-UP/POWER-DOWNCHARACTERISTIC1V/div1V/div400µs/div0.9940.9980.9961.0021.0001.0041.006-502550-25075100125NORMALIZED RESET THRESHOLDvs. TEMPERATUREM A X 6421/26 t o c 08TEMPERATURE (°C)N O R M A L I Z E D R E S E T T H R E S H O L DTypical Operating Characteristics(V CC = 5V, C SRT = 1500pF, T A = +25°C, unless otherwise noted.)M A X 6340/M A X 6421–M A X 6426Low-Power, SC70/SOT µP Reset Circuits with Capacitor-Adjustable Reset Timeout Delay4_______________________________________________________________________________________Detailed DescriptionReset OutputThe reset output is typically connected to the reset input of a µP. A µP ’s reset input starts or restarts the µP in a known state. The MAX6340/MAX6421–MAX6426 µP supervisory circuits provide the reset logic to prevent code-execution errors during power-up, power-down,and brownout conditions (see Typical Operating Characteristics ).RESET changes from high to low whenever V CC drops below the threshold voltage. Once V CC exceeds the threshold voltage, RESET remains low for the capacitor-adjustable reset timeout period.The MAX6422 active-high RESET output is the inverse logic of the active-low RESET output. All device outputs are guaranteed valid for V CC > 1V.The MAX6340/MAX6423/MAX6425/MAX6426 are open-drain RESET outputs. Connect an external pullup resis-tor to any supply from 0 to 5.5V. Select a resistor value large enough to register a logic low when RESET is asserted and small enough to register a logic high while supplying all input current and leakage paths connected to the RESET line. A 10k Ωto 100k Ωpullup is sufficient in most applications.Selecting a Reset CapacitorThe reset timeout period is adjustable to accommodate a variety of µP applications. Adjust the reset timeout period (t RP ) by connecting a capacitor (C SRT ) between SRT and ground. Calculate the reset timeout capacitor as follows:RESET Output Allows Use with Multiple SuppliesMAX6340/MAX6421–MAX6426Low-Power, SC70/SOT µP Reset Circuits with Capacitor-Adjustable Reset Timeout Delay_______________________________________________________________________________________5C SRT = (t RP - 275µs) / (2.73 ✕106)where t RP is in seconds and C SRT is in farads.The reset delay time is set by a current/capacitor-con-trolled ramp compared to an internal 0.65V reference.An internal 240nA ramp current source charges the external capacitor. The charge to the capacitor is cleared when a reset condition is detected. Once the reset condition is removed, the voltage on the capacitor ramps according to the formula: dV/dt = I/C. The C SRT capacitor must ramp to 0.65V to deassert the reset.C SRT must be a low-leakage (<10nA) type capacitor;ceramic is recommended.Operating as a Voltage DetectorThe MAX6340/MAX6421–MAX6426 can be operated in a voltage detector mode by floating the SRT pin. The reset delay times for V CC rising above or falling below the threshold are not significantly different. The reset output is deasserted smoothly without false pulses.Applications InformationInterfacing to Other Voltages for LogicCompatibilityThe open-drain outputs of the MAX6340/MAX6423/MAX6425/MAX6426 can be used to interface to µPs with other logic levels. As shown in Figure 1, the open-drain output can be connected to voltages from 0 to 5.5V. This allows for easy logic compatibility to various µPs.Wired-OR ResetTo allow auxiliary circuitry to hold the system in reset,an external open-drain logic signal can be connected to the open-drain RESET of the MAX6340/MAX6423/MAX6425/MAX6426, as shown in Figure 2. This config-uration can reset the µP, but does not provide the reset timeout when the external logic signal is released.Negative-Going V CC TransientsIn addition to issuing a reset to the µP during power-up,power-down, and brownout conditions, these supervisors are relatively immune to short-duration negative-going transients (glitches). The graph Maximum Transient Duration vs. Reset Threshold Overdrive in the Typical Operating Characteristics shows this relationship.The area below the curve of the graph is the region in which these devices typically do not generate a reset pulse. This graph was generated using a negative-going pulse applied to V CC , starting above the actual reset threshold (V TH ) and ending below it by the magni-tude indicated (reset-threshold overdrive). As the mag-nitude of the transient decreases (farther below the reset threshold), the maximum allowable pulse width decreases. Typically, a V CC transient that goes 100mV below the reset threshold and lasts 50µs or less does not cause a reset pulse to be issued.Ensuring a Valid RESET or RESETDown to V CC = 0When V CC falls below 1V, RESET /RESET current-sink-ing (sourcing) capabilities decline drastically. In the case of the MAX6421/MAX6424, high-impedance CMOS-logic inputs connected to RESET can drift to undetermined voltages. This presents no problems in most applications, since most µPs and other circuitry do not operate with V CC below 1V.In those applications where RESET must be valid down to zero, adding a pulldown resistor between RESET and ground sinks any stray leakage currents, holding RESET low (Figure 3). The value of the pulldown resis-tor is not critical; 100k Ωis large enough not to load RESET and small enough to pull RESET to ground. For applications using the MAX6422, a 100k Ωpullup resis-M A X 6340/M A X 6421–M A X 6426Low-Power, SC70/SOT µP Reset Circuits with Capacitor-Adjustable Reset Timeout Delay6_______________________________________________________________________________________tor between RESET and V CC holds RESET high when V CC falls below 1V (F igure 4). Open-drain RESET ver-sions are not recommended for applications requiring valid logic for V CC down to zero.Layout ConsiderationSRT is a precise current source. When developing the layout for the application, be careful to minimize board capacitance and leakage currents around this pin.Traces connected to SRT should be kept as short as possible. Traces carrying high-speed digital signals and traces with large voltage potentials should be rout-ed as far from SRT as possible. Leakage current and stray capacitance (e.g., a scope probe) at this pin could cause errors in the reset timeout period. When evaluating these parts, use clean prototype boards to ensure accurate reset periods.Figure 3. Ensuring RESET Valid to V CC= 0CCMAX6340/MAX6421–MAX6426Low-Power, SC70/SOT µP Reset Circuits with Capacitor-Adjustable Reset Timeout Delay7factory for availability of nonstandard versions.Typical Operating CircuitM A X 6340/M A X 6421–M A X 6426Low-Power, SC70/SOT µP Reset Circuits with Capacitor-Adjustable Reset Timeout Delay8_______________________________________________________________________________________Pin Configurations (continued)Chip InformationTRANSISTOR COUNT: 295PROCESS: BiCMOSMAX6340/MAX6421–MAX6426Low-Power, SC70/SOT µP Reset Circuits with Capacitor-Adjustable Reset Timeout Delay_______________________________________________________________________________________9Package 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 .)M A X 6340/M A X 6421–M A X 6426Low-Power, SC70/SOT µP Reset Circuits with Capacitor-Adjustable Reset Timeout DelayMaxim 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.10____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600©2002 Maxim Integrated ProductsPrinted USAis a registered trademark of Maxim Integrated Products.Package Information (continued)(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,go to /packages .)。

Data Sheet 26185.2008-BIT SERIAL-INPUT, CONSTANT-CURRENT LATCHED LED DRIVERAlways order by complete part number, e.g., A6275EA .The A6275EA and A6275ELW are specifically designed for LED-display applications. Each BiCMOS device includes an 8-bit CMOS shift register, accompanying data latches, and eight npn constant-current sink drivers. Except for package style and allowable package power dissipation, the two devices are identical.The CMOS shift register and latches allow direct interfacing with microprocessor-based systems. With a 5 V logic supply, typical serial data-input rates are up to 20 MHz. The LED drive current is deter-mined by the user’s selection of a single resistor. A CMOS serial data output permits cascade connections in applications requiring additional drive lines. For inter-digit blanking, all output drivers can be disabled with an ENABLE input high. Similar 16-bit devices are available as the A6276EA and A6276ELW.Two package styles are provided for through-hole DIP (suffix A) or surface-mount SOIC (suffix LW). Under normal applications, copper lead frames and low logic-power dissipation allow these devices to sink maximum rated current through all outputs continuously over the operating temperature range (90 mA, 0.9 V drop, +85°C). Bothdevices are also available for operation over the standard temperature range of -20°C to +85°C. To order, change the suffix letter ‘E’ to ‘S’.6275FEATURESI To 90 mA Constant-Current Outputs I Under-Voltage LockoutI Low-Power CMOS Logic and Latches I High Data Input RateIPin-Compatible with TB62705CP115 Northeast Cutoff, Box 15036Worcester, Massachusetts 01615-0036 (508) 853-********8-BIT SERIAL-INPUT,CONSTANT-CURRENT LATCHED LED DRIVER2Copyright © 2000, Allegro MicroSystems, Inc.5075100125150AMBIENT TEMPERATURE IN °C25Dwg. GP-018BA L L O W AB L E P AC K A G E P O W E RD I S S I P A T I O N I N W A T T SFUNCTIONAL BLOCK DIAGRAMGROUNDLATCH ENABLEOUTPUT ENABLE (ACTIVE LOW)SERIAL DATA OUTCLOCK SERIAL DATA IN SERIAL-PARALLEL SHIFT REGISTERLATCHESLOGIC SUPPLY REXT01Dwg. FP-013-32N62758-BIT SERIAL-INPUT,CONSTANT-CURRENT LATCHED LED DRIVER3CLOCK and SERIAL DATA INSERIAL DATA OUTLATCH ENABLEOUTPUT ENABLE (active low)Dwg. EP-010-6IN Dwg. EP-010-7INDwg. EP-010-5INTRUTH TABLEL = Low Logic (Voltage) Level H = High Logic (Voltage) Level X = Irrelevant P = Present State R = Previous State115 Northeast Cutoff, Box 15036Worcester, Massachusetts 01615-0036 (508) 853-500062758-BIT SERIAL-INPUT,CONSTANT-CURRENT LATCHED LED DRIVER4ELECTRICAL CHARACTERISTICS at T A = +25°C, V DD = 5 V (unless otherwise noted).LimitsCharacteristic Symbol Test Conditions Min.Typ.Max.Unit Supply Voltage Range V DD Operating 4.5 5.0 5.5V Under-Voltage Lockout V DD(UV)V DD = 0 ¡ 5 V3.4–4.0V Output Current I OV CE = 0.7 V, R EXT = 250 Ω64.275.586.8mA (any single output)V CE = 0.7 V, R EXT = 470 Ω34.140.045.9mAOutput Current Matching ∆I O0.4 V ≤ V CE(A) = V CE(B) ≤ 0.7 V:(difference between any R EXT = 250 Ω–±1.5±6.0%two outputs at same V CE )R EXT = 470 Ω–±1.5±6.0%Output Leakage Current I CEX V OH = 15 V– 1.0 5.0µA Logic Input VoltageV IH 0.7V DD –V DD V V ILGND –0.3V DD V SERIAL DATA OUT V OL I OL = 500 µA ––0.4V VoltageV OH I OH = -500 µ4A 4.6––V Input ResistanceR IENABLE Input, Pull Up 150300600k ΩLATCH Input, Pull Down100200400k ΩSupply CurrentI DD(OFF)R EXT = open, V OE = 5 V –0.8 1.4mA R EXT = 470 Ω, V OE = 5 V 3.5 6.08.0mA R EXT = 250 Ω, V OE = 5 V6.51115mA I DD(ON)R EXT = 470 Ω, V OE = 0 V 5.01014mA R EXT = 250 Ω, V OE = 0 V8.01624mATypical Data is at V DD = 5 V and is for design information only.62758-BIT SERIAL-INPUT,CONSTANT-CURRENT LATCHED LED DRIVER5RECOMMENDED OPERATING CONDITIONSCharacteristic Symbol ConditionsMin.Typ.Max.Unit Supply Voltage V DD 4.5 5.0 5.5V Output Voltage V O - 1.0 4.0V Output CurrentI O Continuous, any one output --90mA I OH SERIAL DATA OUT ---1.0mA I OLSERIAL DATA OUT -- 1.0mA Logic Input VoltageV IH 0.7V DD -V DD + 0.3V V IL-0.3-0.3V DD V Clock Frequencyf CKCascade operation --10MHzSWITCHING CHARACTERISTICS at T A = 25°C, V DD = V IH = 5 V, V CE = 0.4 V, V IL = 0 V,R EXT = 470 Ω, I O = 40 mA, V L = 3 V, R L = 65 Ω, C L = 10.5 pF.LimitsCharacteristicSymbol Test Conditions Min.Typ.Max.Unit Propagation Delay Timet pHLCLOCK-OUT n –3501000ns LATCH-OUT n –3501000ns ENABLE-OUT n–3501000ns CLOCK-SERIAL DATA OUT–80110ns Propagation Delay Timet pLHCLOCK-OUT n –3001000ns LATCH-OUT n –3001000ns ENABLE-OUT n–3001000ns CLOCK-SERIAL DATA OUT–80110ns Output Fall Time t f 90% to 10% voltage 1503501000ns Output Rise Timet r10% to 90% voltage150300600ns115 Northeast Cutoff, Box 15036Worcester, Massachusetts 01615-0036 (508) 853-500062758-BIT SERIAL-INPUT,CONSTANT-CURRENT LATCHED LED DRIVER6TIMING REQUIREMENTS and SPECIFICATIONS(Logic Levels are V DD and Ground)A.Data Active Time Before Clock Pulse(Data Set-Up Time), t su(D).......................................... 60 ns B.Data Active Time After Clock Pulse(Data Hold Time), t h(D).............................................. 20 ns C.Clock Pulse Width, t w(CK)............................................... 50 ns D.Time Between Clock Activationand Latch Enable, t su(L)............................................ 100 ns tch Enable Pulse Width, t w(L)................................... 100 ns F.Output Enable Pulse Width, t w(OE)................................ 4.5 µs NOTE – Timing is representative of a 10 MHz clock.Significantly higher speeds are attainable.—Max. Clock Transition Time, t r or t f .............................. 10 µsInformation present at any register is transferred to the respective latch when the LATCH ENABLE is high (serial-to-parallel conversion). The latches will continue to accept new data as long as the LATCH ENABLE is held high. Applica-tions where the latches are bypassed (LATCH ENABLE tied high) will require that the OUTPUT ENABLE input be high during serial data entry.When the OUTPUT ENABLE input is high, the output source drivers are disabled (OFF). The information stored in the latches is not affected by the OUTPUT ENABLE input. With the OUTPUT ENABLE input low, the outputs are controlled by the state of their respective latches.OUT Dwg. WP-029-1OUT Dwg. WP-030-162758-BIT SERIAL-INPUT,CONSTANT-CURRENT LATCHED LED DRIVER7ALLOWABLE OUTPUT CURRENT AS A FUNCTION OF DUTY CYCLEA6275EA A6275ELW20DUTY CYCLE IN PER CENT 1000 Dwg. GP-062-5A L L O W AB L E O U T P U TC U R R E N T I N m A /B I T6040204060100808020DUTY CYCLE IN PER CENT1000 Dwg. GP-062-3A L L O W AB L E O U T P U TC U R R E N T I N m A /B I T6040204060100808020DUTY CYCLE IN PER CENT1000 Dwg. GP-062-2A L L O W AB L E O U T P U TC U R R E N T I N m A /B I T6040204060100808020DUTY CYCLE IN PER CENT1000 Dwg. GP-062-4A L L O W AB L E O U T P U TC U R R E N T I N m A /B I T60402040601008080115 Northeast Cutoff, Box 15036Worcester, Massachusetts 01615-0036 (508) 853-500062758-BIT SERIAL-INPUT,CONSTANT-CURRENT LATCHED LED DRIVER820DUTY CYCLE IN PER CENT 1000 Dwg. GP-062-1A L L O W AB L E O U T P U TC U R R E N T I N m A /B I T6040204060100808020DUTY CYCLE IN PER CENT1000 Dwg. GP-062A L L O W AB L E O U T P U TC U R R E N T I N m A /B I T60402040601008080ALLOWABLE OUTPUT CURRENT AS A FUNCTION OF DUTY CYCLE (cont.)A6275EA A6275ELWTYPICAL CHARACTERISTICS0.5Dwg. GP-0631.01.5V CE IN VOLTS06040O U T P U T C U R R E N T I N m A /B I T2062758-BIT SERIAL-INPUT,CONSTANT-CURRENT LATCHED LED DRIVER9TERMINAL DESCRIPTIONTerminal No.Terminal NameFunction1GND Reference terminal for control logic.2SERIAL DATA INSerial-data input to the shift-register.3CLOCK Clock input terminal for data shift on rising edge.4LATCH ENABLEData strobe input terminal; serial data is latched with high-level input.5-12OUT 0-7The eight current-sinking output terminals.13OUTPUT ENABLE When (active) low, the output drivers are enabled; when high, all output drivers are turned OFF (blanked).14SERIAL DATA OUTCMOS serial-data output to the following shift-register.15R EXT An external resistor at this terminal establishes the output current for all sink drivers.16SUPPLY(V DD ) The logic supply voltage (typically 5 V).The products described here are manufactured under one or more U.S. patents or U.S. patents pending.Allegro MicroSystems, Inc. reserves the right to make, from time to time, such departures from the detail specifications as may berequired to permit improvements in the performance, reliability, or manufacturability of its products. Before placing an order, the user is cautioned to verify that the information being relied upon is current.Allegro products are not authorized for use as critical components in life-support devices or systems without express written approval.The information included herein is believed to be accurate and reliable. However, Allegro MicroSystems, Inc. assumes no responsi-bility for its use; nor for any infringement of patents or other rights of third parties which may result from its use.115 Northeast Cutoff, Box 15036Worcester, Massachusetts 01615-0036 (508) 853-500062758-BIT SERIAL-INPUT,CONSTANT-CURRENT LATCHED LED DRIVER10The load current per bit (I O ) is set by the external resistor (R EXT ) as shown in the figure below.300500700 1 k 2 k CURRENT-CONTROL RESISTANCE, R EXT IN OHMS1000100Dwg. GP-061O U T P U T C U R R E N T I N m A /B I T200 3 k 20406080Package Power Dissipation (P D ). The maximum allowable package power dissipation is determined asP D (max) = (150 - T A )/R θJA .The actual package power dissipation isP D (act) = dc(V CE • I O • 8) + (V DD • I DD ).When the load supply voltage is greater than 3 V to 5 V,considering the package power dissipating limits of these devices, or if P D (act) > P D (max), an external voltage reducer (V DROP ) should be used.Load Supply Voltage (V LED ). These devices are designed to operate with driver voltage drops (V CE ) of 0.4 V to 0.7 V with LED forward voltages (V F ) of 1.2 V to 4.0 V. If higher voltages are dropped across the driver,package power dissipation will be increased significantly.To minimize package power dissipation, it is recom-mended to use the lowest possible load supply voltage or to set any series dropping voltage (V DROP ) asV DROP = V LED - V F - V CEwith V DROP = I o • R DROP for a single driver, or a Zener diode (V Z ), or a series string of diodes (approximately0.7 V per diode) for a group of drivers. If the available voltage source will cause unacceptable dissipation and series resistors or diode(s) are undesirable, a regulator such as the Sanken Series SAI or Series SI can be used to provide supply voltages as low as 3.3 V.For reference, typical LED forward voltages are:Blue 3.0 – 4.0 V Green 1.8 – 2.2 V Yellow 2.0 – 2.1 V Amber 1.9 – 2.65 V Red 1.6 – 2.25 V Infrared 1.2 – 1.5 V Pattern Layout. This device has a common logic-ground and power-ground terminal. If ground pattern layout contains large common-mode resistance, and the voltage between the system ground and the LATCHENABLE or CLOCK terminals exceeds 2.5 V (because of switching noise), these devices may not operate correctly.Dwg. EP-064V LEDVV FV CEApplications Information62758-BIT SERIAL-INPUT,CONSTANT-CURRENT LATCHED LED DRIVER11A6275EADimensions in Inches (controlling dimensions)Dimensions in Millimeters (for reference only)NOTES:1.Exact body and lead configuration at vendor’s option within limits shown.2.Lead spacing tolerance is non-cumulative3.Lead thickness is measured at seating plane or below.Dwg. MA-001-16A mmDwg. MA-001-16A in115 Northeast Cutoff, Box 15036Worcester, Massachusetts 01615-0036 (508) 853-500062758-BIT SERIAL-INPUT,CONSTANT-CURRENT LATCHED LED DRIVER12A6275ELWDimensions in Inches (for reference only)Dimensions in Millimeters (controlling dimensions)NOTES:1.Exact body and lead configuration at vendor ’s option within limits shown.2.Lead spacing tolerance is non-cumulative.。

AVPro Triple SCART A/V SwitchDESCRIPTIONThe AVPro ® 5003 is a low cost IC that performs switching of analog audio and video signals. The device accepts analog audio and video inputs from three external sources, typically a video encoder IC/stereo DAC, an auxiliary SCART connector, and a VCR SCART connector. The input signals from these sources are presented to a set of internal multiplexers that perform the SCART switching function. Outputs are provided to the VCR and auxiliary SCART connectors, as well as a TV SCART connector and an RF modulator. Video outputs are buffered to drive 150 Ω loads. Audio outputs are buffered to provide 2 Vrms output into 600 ohms. Typical applications for the 5003 include digital video recorders (DVRs) and digital receivers for satellite, cable, and terrestrial television.August 2000FEATURES•SCART connections for TV, VCR, AUX• Integrated video drivers • Integrated audio drivers- Negative supply eliminates AC coupling caps• 5-bit audio attenuation for TV output - Attenuation from 0 to 31 dB, 1 dB steps - Mute of TV outputs• Serial port control of SCART switching • 64-lead MQFP packaging (JEDEC MO-108)BLOCK DIAGRAMBLANK TV_C TV_R TV_G TV_B SVHS_Cout AUX_YCout TV_YCout TV_Mod VCR_YCout TV_Fnc DO_0DO_1VCR_Lout VCR_Rout Lout TV_Lout TV_Rout Rout AUX_Lout AUX_RoutV C C V C CV C CV C CV E E V E E V E E V E EV D DMono Lin Rbias VrefVCR_RinVCR_Lin Tgen AUX_RinAUX_Lin SDATASCLK Enc_Y Enc_YC VCR_YCin AUX_YCin AUX_Fnc AUX_B Enc_B Enc_G AUX_G SVHS_Cin Enc_C Enc_R AUX_R EBLANK ABLANKVCR_Fnc V C CAVPro® 5003Triple SCART A/V SwitchFUNCTIONAL DESCRIPTIONSCART Video SwitchingThe device is designed to accept video signals from several SCART video resources. The device includes an analog multiplexer that receives the external video signals and allows routing of the signals to the various video outputs on the device. Writing bits to serial port Register 1 controls switching.RGB Outputs: The device accepts RGB video signals from two sources. The AUX_R, AUX_G, AUX_B input pins are typically connected to the auxiliary SCART connector. The Enc_R, Enc_G, Enc_B input pins are connected to the RGB outputs of an external video encoder device. The lower two bits of serial port Register 1 determine which RGB input port will be used as the source for the TV_R, TV_G, TV_B output pins. When these bits are set to xxxxxx00, the auxiliary SCART is used as the input. When these bits are set to xxxxxx01, the video encoder is used as the input.The RGB sync can be selected from either the RGB signals or the output on TV_YCout, as set by the MSB of serial port Register 0. Setting this bit selects the timing signal for the DC restore circuit. The DC restore circuit acts to position the blank level to 0.6 V at the output video load. When the bit is high, the timing signal is from the output on TV_YCout from either the AUX_YCin or Enc_YC. When the bit is low, the timing signal will detect sync on either of the RGB signals. The associated blanking signal from respective video sources is also switched accordingly with a delay matched to that of the RGB signals.When the SVHS mode is active, the TV_R pin receives a chroma signal from either Enc_C or SVHS_Cin. The DC restore averages to approximately 1.8 VDC at the output pin. The TV_G, TV_B outputs are also disabled (~0 V) in this mode.TV Composite Output: The device accepts up to three composite (YC) video sources. The AUX_YCin input pin is typically connected to the Video In pin on the auxiliary SCART connector. The VCR_YCin input pin is typically connected to the Video In pin from the VCR SCART connector. The Enc_YC input pin is typically connected to the YC output from the external video encoder device. Two bits in the serial port register determine which of the composite input signals will be switched to the TV_YCout output pin. When bits of Register 1 are set to xxxx00xx, the signal on AUX_YCin is used as the input. When the bits are set to xxxx01xx, the signal on Enc_YC is used as the input. When the bits are set to xxxx10xx, the signal on VCR_YCin is used as the input. The TV_YCout pin can be active with a composite video signal when RGB inputs are active. When the TV SVHS mode is selected the composite video mode is not available and the TV_YCout pin provides luminance information to the TV SCART connector. The DC restore circuit acts to position the blank level to 0.6 V at the output 75 ohm load.RF Modulator Outputs: The device has a TV_Mod output that follows the TV_YCout signal. When the TV SCART has composite video, TV_Mod can be fed directly to the RF modulator. When the TV is in SVHS mode, the TV_Mod output (luminance) can be summed with the TV_C output (chroma) to provide a composite signal for the RF modulator. When the TV SCART has composite available, the TV_C output can be disabled via the MSB of serial port Register 1. Auxiliary Composite Output: The VCR and video encoder composite video sources are available to switch to the AUX_YCout output pin. This pin is typically connected to the Video Out pin on the auxiliary SCART connector. A bit in serial port Register 1 determines the signal source for the AUX_YCout output pin. Setting the register to x0xxxxxx selects the signal on VCR_YCin, while setting the register to x1xxxxxx selects the signal on ENC_YC. The DC restore circuit acts to position the blank level to 0.5 V at the output pin.VCR Composite Output: The auxiliary SCART and video encoder composite video sources are available to switch to the VCR_YCout output pin. This pin is typically connected to the Video Out pin on the VCR SCART connector. Two bits in serial port Register 1 determine the source for the AUX_YCout output pin. Setting the register to xx01xxxx selects the signal on AUX_YCin, while setting the register to xx10xxxx selects the signal on ENC_YC.SVHS Switching: The device supports the SVHS mode from the VCR SCART connector. The SVHS_Cin pin provides chroma information from the VCR SCART connector to the TV SCART connector. The SVHS_Cout pin provides chroma informationAVPro® 5003 Triple SCART A/V Switchfrom the encoder IC to the VCR SCART connector. The encoder chroma output can also be routed to the TV_R pin to support SVHS applications. When Register 1 is set to xxxx1011, the SVHS mode is selected with SVHS_Cin and VCR_YCin providing the chroma and luma inputs, respectively. In this mode, the load for the VCR chroma source (SCART pin 15) is provided by the series resistor for the SVHS_Cout pin and the low output impedance of the amplifier. The SVHS_Cin is ac coupled, and its dc bias set to approximately 0.9V. When the bits are set to xxxx1110, the ENC_C and ENC_Y inputs provide the chroma and luma inputs, respectively. The VCR SCART can also receive SVHS information from the video encoder by setting the register bits to xx00xxxx. Note that when the VCR is receiving information it cannot be used as a signal source for other devices.Function Switch: The device monitors the function switch pin (pin 8) of the auxiliary SCART and VCR SCART connectors, AUX_Fnc and VCR_Fnc pins, respectively. It is also known as slow blanking. Each of these inputs can detect three distinct levels and set two bits in serial port read Register 0. When the SCART input level is 0 to 2 V, the register bits are set to 00. When the input level is 4.5 to 7.0 V, the register bits are set to 01. When the input level is 9.5 to 12 V, the register bits are set to 10. The device also provides a function switching output (TV_Fnc) to the TV SCART connector (pin 8). The output level is determined by the state of two LSBs in serial port write Register 0. The table below defines the state of the TV_Fnc pin based on the register bit values.Bits OutputvoltageFunctionxxxxxx00~0 V Normal TVxxxxxx01~6 V16:9 aspectxxxxxx10~ 11 V Peritelevisionxxxxxx11~ 11 V PeritelevisionSCART Audio switchingThe device is designed to accept stereo audio inputs from an external audio DAC and from auxiliary SCART and VCR SCART connectors. The device provides audio outputs to the TV SCART, auxiliary SCART, and VCR SCART connectors. It also provides fixed gain, stereo line outputs of the audio output on the TV SCART. The line outputs are intended for use by an external stereo receiver/amplifier. These outputs are also combined for a Mono output to a RF modulator.The audio inputs are considered to be associated with the respective composite video input. As a result, the video selection determines which audio signals will be switched to a given SCART output. Refer to the SCART Video Switching section of this document for more information.Volume Control: The device provides control of the output level on the TV audio outputs (TV_Lout/Rout). The output level is controlled through serial port write Register 2. The lower 6-bits of this register set an attenuation level from 0 to -63 dB in 1 dB steps, where xx000000 is 0 dB and xx111111 is -63 dB. However, the attenuation is only specified to 5-bits of accuracy (-31 dB).The mute function is controlled by the fifth bit of write Register 0, which allows these outputs to be muted to -75 dB. When this bit is set to 0, the attenuator is active. When it is set to 1, the outputs are muted to -75 dB. This bit can be set independent of the attenuation register such that the output can be muted before any change in volume, or any switching of audio sources. The audio control circuits have a zero crossing detector that allows volume control changes to be completed only when the audio signal is near a zero crossing. This prevents audible popping and clicking during a volume change.Hot-plug of SCART connectors. The 5003 devices are sensitive to discharge caused by floating chassis grounds between audio/video equipment. This is observed when the SCART cables are repeatedly connected and disconnected while the 5003 is powered on inside the IRD. When the SCART cable is unplugged, an AC potential can exist between equipments. When the SCART cable is plugged back into the IRD, the AC potential discharges through the SCART connector. If the discharge occurs through the shield of the SCART connector or the ground pins, there is no problem. If the discharge occurs through the signal pins, the 5003 devices can experience a latch-up condition and a high current situation will exist. The latch-up will occur if the pulse created by the discharge has a fast rising edge, typically a few hundred pico-seconds. This is an order of magnitude faster than a standard ESD pulse so the internal ESD diodes of the 5003 will not respond fast enough to protect the device. This problem can be resolved by placing aAVPro® 5003Triple SCART A/V Switchsmall shunt capacitor on each SCART I/O pin. The capacitor slows the rising edge of the discharge pulse and allows the internal ESD diodes to react to the discharge. Good results are achieved using a 470 pF value, but an exact value should be calculated for each signal line depending upon the signal type so as to avoid roll-off of the intended signal. As an alternate approach, external diodes can be used to shunt this discharge.Digital OutputsThe device includes programmable digital outputs (DO_0, and DO_1). These pins are general purpose outputs programmed by bits in serial port Register 0. Bit 3 of this register controls DO_0 while bit 4 controls DO_1. Setting the register bits to 0 puts these outputs in the LOW state. Setting the register bits to 1 puts the outputs in the HIGH state. Internal pull-ups are incorporated.Serial Port DefinitionInternal functions of the device are monitored and controlled by a simple two-wire serial port that is compatible with the inter-IC (I2C) bus. The serial port operates in a slave mode only and can be written to or read from. The default address of the device is 1001000x. The serial port uses a clock input (SCLK) that is driven by the bus master and a bi-directional data input (SDATA) to perform all data transfers. Data Transfers: The device is enabled for a data transfer when the SDATA pin is driven from HIGH to LOW by the bus master while the SCLK pin is HIGH. The data transfer is complete when the bus master drives the SDATA pin from LOW to HIGH while thedecoded to determine if a valid address has been received. The first seven bits of information are the address with the eighth bit indicating whether the cycle is a read (bit is HIGH) or a write (bit is LOW). If the address is valid for this device, on the falling SCLK edge of the eighth bit of data, the device will drive the SDATA pin low and hold it LOW until the next falling edge of the SCLK pin to acknowledge the address transfer. Once a valid address is detected the device will continue to transmit or receive data until the process is complete, or the bus master issues a stop.Reset: At power-up the serial port defaults to the states indicated in boldface type. At device power-up, the device also generates an acknowledge. The device also responds to the system level reset that is transmitted through the serial port. When the master sends the address 00000000 followed by the data 00000110, the device resets to the default condition, and generates and acknowledge.I2C Latch-up. The 5003 may latch-up if the I2C bus is active and there is no power to the 5003 device. In a typical application, this will not occur as the I2C bus and the 5003 device are powered from the same power supply. This condition typically occurs when evaluating the 5003 devices on a demo board. When the I2C is powered on and the 5003 device is powered off, the I/O lines of the I2C bus are active and therefore will be at +5V. The SDATA pin internal ESD diodes will begin to conduct current through the SDATA pin and attempt to power-on internal circuits of the device. When power is applied to the 5003 device, circuits can be in an unknown state and therefore latch-up occurs. This is prevented by disconnecting the I2C interface when the device is powered down.Power Supply Sequence: The 5003 require three power supplies ( 12V, 5V and –5V ) for proper operation. Similar to other CMOS devices that are powered from multiple supplies, the 5003 family device requires proper power ramp-up sequence to avoid forwardly biasing the substrate diodes which can cause destructive latch-up. In order to insure that the chip substrate diodes are always reverse biased, the –5V supply should always be applied before the other two supplies. The preferred power ramp-up sequences is “–5V, +12V and then +5V.”If this sequence can not be achieved, placing schottky diodes from –5V to ground and / or +12V to +5V supply, depending upon sequence and timing, can prevent latchup.AVPro® 5003Triple SCART A/V SwitchSerial Port Register Table (Write registers); Device Address = 10010000 (Bold indicates default setting) REGISTER FUNCTION BITS DESCRIPTION0TV Function Control xxxxxx00xxxxxx01xxxxxx10xxxxxx11Level 0; normal TV output (TV_Fnc = 0V)Level 1A; 16:9 aspect ratio (TV_Fnc = 6V)Level 1B; Peritelevision output mode (TV_Fnc =11V) Level 1B; not valid mode (TV_Fnc =11V)0Digital Outputs(independent)xxxx00xxxxxx11xxDO_0, DO_1 are set LOWDO_0, DO_1 are set HIGH0TV Mute Control*xxx0xxxxxxx1xxxx TV audio (TV_Lout/TV_Rout, Lout/Rout/Mono) output = ON TV audio (TV_Lout/TV_Rout, Lout/Rout/Mono) output = Mute0n/a x00xxxxx Reserved: Set these bits to “0” for normal operation0RGB Sync Source0xxxxxxx1xxxxxxx RGB sync /DC restore source = RGB RGB sync /DC restore source = TV_YC1TV RGB/ S videochroma Source(S Video has chroma on TV_R. TV_G & TV_B outputs are disabled.)xxxxxx00xxxxxx01xxxxxx10xxxxxx11TV RGB signal source = Auxiliary SCART input (RGB )TV RGB signal source = Video encoder IC,TV RGB signal source = Video encoder IC, chroma on TV redTV RGB signal source = VCR SCART (red) chroma on TV red1TV composite video /Audio Source xxxx00xxxxxx01xxxxxx10xxxxxx11xxTV composite & audio signal source = Auxiliary SCART inputTV composite & audio signal source =Video encoder ICaudio DAC ICTV composite & audio signal source = VCR SCART inputTV composite (S video luma ) & audio signal source =Video encoder IC (Enc_Y), audio DAC IC1VCR Signal Source xx00xxxxxx01xxxxxx10xxxxxx11xxxx SVHS mode, source = Video encoder IC (Y & C), audio DAC IC VCR signal source = Auxiliary SCART composite inputVCR signal source = Video encoder IC (YC), audio DAC IC VCR signal source = Video encoder IC (YC), audio DAC IC1Auxiliary Output Select x0xxxxxxx1xxxxxx Auxiliary signal source = VCR SCART inputAuxiliary signal source = Video encoder IC, audio DAC IC1TV Chroma RF output0xxxxxxx1xxxxxxx TV_C (chroma RF) output: output disabledTV_C (chroma) output: = TV_R (for RF mod to sum Y & C)2TV Volume Control*xx000000xx011111TV audio volume = normal (0 dB)TV audio volume = minimum (31 dB atten.)2n/a00xxxxxxSerial Port Register Table (Read register); Device Address = 10010001 (Bold indicates default setting)0AUX Function ControlInput xxxxxx00xxxxxx01xxxxxx10Level 0; normal TV output (TV_Fnc = 0 volts)Level 1A; 16:9 aspect ratio (TV_Fnc = 6 volts)Level 1B; Peritelevision output mode (TV_Fnc = 11 volts)0VCR Function ControlInput xxxx00xxxxxx01xxxxxx10xxLevel 0; normal TV output (TV_Fnc = 0 volts)Level 1A; 16:9 aspect ratio (TV_Fnc= 6 volts)Level 1B; Peritelevision output mode (TV_Fnc = 11 volts)0n/a0000xxxx Reserved: These bits set to “0” in normal operationAVPro® 5003Triple SCART A/V SwitchSCART Switching TableINPUT PIN OUTPUT PINAUX_R: Red input from AUX SCARTEnc_R: Red input from video encoder ICEnc_C: Chroma input from video encoder ICSVHS_Cin: Chroma input from VCR SCARTTV_R: Red video output to TV or SVHS chroma output to TVAUX_R: Red input from AUX SCARTEnc_R: Red input from video encoder IC Enc_C: Chroma input from video encoder IC SVHS_Cin: Chroma input from VCR SCART TV_C: Follows TV_R output. Chroma output to sum Y & C for RF modulator when TV in S video mode, On/off selectableAUX_G: Green input from AUX SCARTEnc_G: Green input from video encoder ICTV_G: Green video output to TVAUX_B: Blue input from AUX SCARTEnc_B: Blue input from video encoder ICTV_B: Blue video output to TVABLANK: Blanking input from AUX SCARTEBLANK: Blanking input from video encoder ICBLANK: TV blanking output for RGBAUX_YCin: Composite input from AUX SCARTEnc_YC: Composite input from video encoder ICEnc_Y: Luma input from video encoder ICVCR_YCin: Composite (YC or Y) input from VCRTV_YCout: Composite video, RGB sync, or Luma output to TVAUX_YCin: Composite input from AUX SCART Enc_YC: Composite input from video encoder IC Enc_Y: Luma input from video encoder ICVCR_YCin: Composite (YC or Y) input from VCR TV_Mod: Follows TV_YCout output. Composite (or luma sum with chroma) output to RF modulatorAUX_YCin: Composite input from AUX SCARTEnc_YC: Composite input from video encoder ICEnc_Y: Luma input from video encoder ICVCR_YCout: Composite or Luma output to VCREnc_C: Chroma input from video encoder IC SVHS_Cout: Chroma output to VCREnc_YC: Composite input from video encoder ICVCR_YCin: Composite input from VCR SCARTAUX_YCout: Composite video output to auxiliary SCARTAUX_Lin: Left audio input from AUX SCARTLin: Left audio input from audio DACVCR_Lin: Left audio input from VCR SCARTLout: Left audio output to RCA jackAUX_Lin: Left audio input from AUX SCARTLin: Left audio input from audio DACVCR_Lin: Left audio input from VCR SCARTTV_Lout: Left audio output to TV SCARTLin: Left audio input from audio DACVCR_Lin: Left audio input from VCR SCARTAUX_Lout: Left audio output to auxiliary SCARTAUX_Lin: Left audio input from AUX SCARTLin: Left audio input from audio DACVCR_Lout: Left audio output to VCR SCARTAUX_Rin: Right audio input from AUX SCARTRin: Right audio input from audio DACVCR_Rin: Right audio input from VCR SCARTRout: Right audio output to RCA jackAUX_Rin: Right audio input from AUX SCARTRin: Right audio input from audio DACVCR_Rin: Right audio input from VCR SCARTTV_Rout: Right audio output to TV SCARTRin: Right audio input from audio DACVCR_Rin: Right audio input from VCR SCARTAUX_Rout: Right audio output to auxiliary SCARTAUX_Rin: Right audio input from AUX SCARTRin: Right audio input from audio DACVCR_Rout: Right audio output to VCR SCARTAVPro® 5003Triple SCART A/V SwitchPIN DESCRIPTIONSNAME TYPE DESCRIPTIONAnalog Pins:ABLANK I Auxiliary Blanking Input: In a typical system, this pin is connected to the RGBstatus pin (pin 16, fast blanking) from the auxiliary SCART connector.AUX_R I Auxiliary Red Input: In a typical system, this pin is connected to the RED input pin(pin 15) of the auxiliary SCART connector. This input can be selected as thesignal source for the TV_R output pin.AUX_G I Auxiliary Green Input: In a typical system, this pin is connected to the GREENinput pin (pin 11) of the auxiliary SCART connector. This input can be selected asthe signal source for the TV_G output pin.AUX_B I Auxiliary Blue Input: In a typical system, this pin is connected to the BLUE inputpin (pin 7) of the auxiliary SCART connector. This input can be selected as thesignal source for the TV_B output pin.AUX_Fnc I Function Switching Input, AUX: In a typical system, this pin is connected to pin 8of the auxiliary SCART connector to monitor the function select input from thatdevice. This input can identify three different levels and record the level in theserial port register.AUX_YCin I Auxiliary Video Input: In a typical system, this pin is connected to the compositevideo input pin (pin 20) of the auxiliary SCART connector. This input can beselected as the signal source for the TV_YCout and/or VCR_YCout pins.AUX_Lin I Auxiliary Left Audio Input: In a typical system, this pin is connected to the L AudioOutput pin (pin 3) of the auxiliary SCART connector. This input can be selectedas the signal source for the TV_Lout and/or VCR_Lout pins.AUX_Rin I Auxiliary Right Audio Input: In a typical system, this pin is connected to the RAudio Output pin (pin 1) of the auxiliary SCART connector. This input can beselected as the signal source for the TV_Rout and/or VCR_Rout pins.EBLANK I Encoder Blanking Input: In a typical system, this pin is connected to the fastblanking signal from the external video encoder device.Enc_R I Encoder Red Input: In a typical system, this pin is connected to the RED outputpin from the external video encoder device. This input can be selected as thesignal source for the TV_R output pin.Enc_G I Encoder Green Input: In a typical system, this pin is connected to the GREENoutput pin from the external video encoder device. This input can be selected asthe signal source for the TV_G output pin.Enc_B I Encoder Blue Input: In a typical system, this pin is connected to the BLUE outputpin from the external video encoder device. This input can be selected as thesignal source for the TV_B output pin.Enc_YC I Encoder Video Input: In a typical system, this pin is connected to the compositevideo output pin from the external video encoder device. This input can beselected as the signal source for the AUX_YCout, TV_YCout and/or VCR_YCoutpins.Enc_Y I Encoder Luminance Input: In a typical system, this pin is connected to thecomposite video output pin from the external video encoder device whenoperating S video. This input can be selected as the signal source for theTV_YCout and/or VCR_YCout pins.AVPro® 5003Triple SCART A/V SwitchPIN DESCRIPTIONS (continued)NAME TYPE DESCRIPTIONEnc_C I Encoder Chrominance Input: In a typical system, this pin is connected to the TV_Routput pin from the external video encoder device when operating S video. This inputcan be selected as the signal source for the TV_R and/or VCR’s SVHS_Cout output pin. Lin I Left Audio Input: In a typical system, this pin is connected to the left audio outputpin of the external audio DAC. This input can be selected as the signal source forthe TV_Lout, VCR_Lout and/or AUX_Lout pins.Rin I Right Audio Input: In a typical system, this pin is connected to the right audiooutput pin of the external audio DAC. This input can be selected as the signalsource for the TV_Rout, VCR_Rout and/or AUX_Rout pins.SVHS_Cin I SVHS Chroma Input: In a typical system, this pin is connected to the SVHSChroma pin (pin 15) on the VCR SCART connector. It provides chroma input fromthe VCR when the SVHS mode is selected for the TV connector.VCR_YCin I VCR Video Input: In a typical system, this pin is connected to the composite videoinput pin (pin 20) of the VCR SCART connector. This input can be selected as thesignal source for the TV_YCout and/or AUX_YCout pins.VCR_Lin I VCR Left Audio Input: In a typical system, this pin is connected to the L AudioOutput pin (pin 3) of the VCR SCART connector. This input can be selected asthe signal source for the TV_Lout and/or AUX_Lout pins.VCR_Rin I VCR Right Audio Input: In a typical system, this pin is connected to the R AudioOutput pin (pin 1) of the VCR SCART connector. This input can be selected asthe signal source for the TV_Rout and/or AUX_Rout pins.VCR_Fnc I Function Switching Input, VCR: In a typical system, this pin is connected to pin 8 ofthe VCR SCART connector to monitor the function select input from that device. Thisinput can identify three different levels and records the level in the serial port register. AUXYCout O Auxiliary Video Output: This pin is the composite video output to the auxiliarySCART connector (pin 19).AUX_Lout O Auxiliary Left Audio Output: This pin is the output to the left channel audio (pin 3)of the auxiliary SCART connector.AUX_Rout O Auxiliary Right Audio Output: This pin is the output to the right channel audio(pin1) of the auxiliary SCART connector.BLANK O Blanking output: This output provides the blanking signal to the TV SCARTconnector (pin 16). This signal is either the blanking signal from the auxiliarySCART connector (ABLANK) or the signal from the external video encoder(EBLANK).Lout O Left Audio Output: This pin is the output to the left channel audio RCA jack.Rout O Right Audio Output: This pin is the output to the right channel audio RCA jack. Mono O Mono Audio Output: This pin is sum of Lout & Rout to the RF modulator input. SVHS_Cout O SVHS Chroma Output: This pin is typically AC coupled to pin 15 of the VCRSCART connector. When the S-video mode is selected for the VCR connector,video from the video encoder input pin (Enc_C) is output to this pinTV_YCout O TV Video Output: This pin is the composite video output to the TV SCARTconnector (pin 19). In the SVHS mode, this pin provides luminance information.AVPro® 5003Triple SCART A/V SwitchPIN DESCRIPTIONS (continued)NAME TYPE DESCRIPTIONTV_Mod O TV Modulator Video Output: This pin follows the composite video output to theTV_YCout signal to the TV SCART connector. It provides composite video for anexternal RF modulator. In S video mode, it provides luminance information only TV_R O TV Red Output: This pin provides Red video output to the TV SCART connector(pin 15). In S video mode, this pin provides the chroma information.TV_C O TV Chroma Output: This pin provides chroma signal to sum with TV_Mod’sluminance when operating in S video mode for composite video signal for RFmodulator. It is on/off selectable.TV_G O TV Green Output: This pin provides Green video output to the TV SCARTconnector (pin 11).TV_B O TV Blue Output: This pin provides Blue video output to the TV SCART connector(pin 7).TV_Lout O TV Left Audio Output: This pin is the output to the left channel audio (pin 3) of theTV SCART connector.TV_Rout O TV Right Audio Output: This pin is the output to the right channel audio (pin1) ofthe TV SCART connector.TV_Fnc O Function Output TV: This pin is the function switching output to the TV SCARTconnector pin 8. The output level is determined by the serial port write register. VCR_YCout O VCR Video Output: This pin is the composite video output to the VCR SCARTconnector (pin 20). In the SVHS mode, this pin provides luminance informationfrom the video encoder IC (pin Enc_Y).VCR_Lout O VCR Left Audio Output: This pin is the output to the left channel audio (pin 3) ofthe VCR SCART connector.VCR_Rout O VCR Right Audio Output: This pin is the output to the right channel audio (pin1) ofthe VCR SCART connector.Digital Pins:DO_0O Digital Output 0: This pin is a general purpose output that is controlled by serialport register.DO_1O Digital Output 1: This pin is a general purpose output that is controlled by serialport register.SCLK I Serial Clock Input: This pin accepts a serial port clock input signal.SDATA I Serial Data Input: This is a tri-state pin that receives or transmits serial data. Power/Ground Pins:VCC-+5 VDC power inputs.VEE--5 VDC power inputs.VDD-+12 VDC power input for function switchingVref-Internal voltage reference, bypass pin. Add capacitor 4.7 uF to ground.GND-Ground for all blocks.Rbias-Bias point of internal current generator. Add resistor 10k to ground.Tgen-Reference point for internal timing circuit. Add capacitor 470 pF to ground.。

C i r c u i t b r e a k e r sCircuit breakersTeSys GV, GBC ontrol and P rotection C omponentsChapterB60.75g g 1.1g g 1.5375 2.533.5 LR2 K0308GV2LE071.1g g –––––– 2.533.5 LR2 K0308GV2LE071.5g g 1.5g g 3375451 LR2 K0310GV2LE08––– 2.2g g –––451 LR2 K0312GV2LE082.2g g 3501004375 6.378 LR2 K0312GV2LE103g g 410100 5.537510138 LR2 K0314GV2LE144g g 5.510100–––10138 LR2 K0316GV2LE14––––––7.537510138 LRD 14GV2LE14––––––937514170 LRD 16GV2LE165.515507.56751137514170 LR2 K0321GV2LE167.5155096751537518223 LRD 21GV2LE20915401147518.537525327 LRD 22GV2LE2211154015475–––25327 LRD 22GV2LE2215105018.54752237532416LRD 32GV2LE32(1) As % of Icu.g ) > 100 kA.GV2 LE10D F 526144.t i fC i r c u i t b r e a k e r s0.09––––––0.45LRD 03GV2L030.12g g –––0.37g g 0.638LRD 04GV2L040.18g g ––––––0.638LRD 04GV2L04––––––0.55g g 113LRD 05GV2L050.25g g ––––––113LRD 05GV2L05––––––0.75g g 113LRD 06GV2L050.37g g 0.37g g –––113LRD 05GV2L050.55g g 0.55g g 1.1g g 1.622.5LRD 06GV2L06–––0.75g g ––– 1.622.5LRD 06GV2L060.75g g 1.1g g 1.54100 2.533.5LRD 07GV2L07Example: GV3 L32 becomes GV3 L326.(1) As % of Icu. Associated current limiter or fuses, where required. See characteristics page B6/33.g > 100 kA.GV2 L10D F 526145.t i fGV3 L65D F 526146.t i fTeSys GVThermal-magnetic motor circuit breakers GV2 ME0.06gg––––––0.16…0.252.4GV2ME020.09g g––––––0.25…0.405GV2ME030.12 0.18g g g g – –– –– – 0.37 –g–g –0.40…0.638GV2ME040.25gg––– 0.55gg0.63…113GV2ME050.37 0.55 –g g –g g –0.37 0.55 0.75g g g g g g – 0.75 1.1– g g – g g 1…1622.5GV2ME060.75g g1.1gg1.5375 1.6...2.533.5GV2ME071.1 1.5g g g g 1.5 2.2g g g g 2.2 3 3 375 75 2.5 (4)51GV2ME082.2gg350100 43754...6.378GV2ME103 4g g g g 4 5.510 10100 100 5.5 7.5 3 375 756 (10)138GV2ME145.5 –15 –50 –7.5 – 6 –75 – 9 11 3 375 759…14170GV2ME167.5155096751537513…18223GV2ME209154011475 18.537517…23327GV2ME2111154015475 –––20…25327GV2ME22 (3)15105018.54752237524 (32)416GV2ME32Motor circuit breakers from 0.06 to 15 kW / 400 V, with lugsTo order thermal magnetic circuit breakers with connection by lugs, add the digit 6 to the end of reference selected above.Example: GV2 ME08 becomes GV2 ME086.Thermal magnetic circuit breakers GV2 ME with built-in auxiliary contact block With instantaneous auxiliary contact block (composition, see page B6/11):b GV AE1, add suffix AE1TQ to the motor circuit breaker reference selected above. Example: GV2 ME01AE1TQ .b GV AE11, add suffix AE11TQ to the motor circuit breaker reference selected above. Example: GV2 ME01AE11TQ .b GV AN11, add suffix AN11TQ to the motor circuit breaker reference selected above. Example: GV2 ME01AN11TQ .These circuit breakers with built-in contact block are sold in lots of 20 units in a single pack.(1) As % of Icu.(2) The thermal trip setting must be within the range marked on the graduated knob.(3) Maximum rating which can be mounted in enclosures GV2 MC or MP , please consult your Regional Sales Office. g > 100 kA.GV2 ME10D F 526134.t i fC i r c u i t b r e a k e r sTeSys GVTeSys protection componentsThermal-magnetic motor circuit breakers GV2 MEReferences0.06g g ––– 0.16…0.25 2.4GV2ME0230.09g g ––– 0.25…0.405GV2ME0330.120.18g g g g –––0.40…0.638GV2ME0430.250.37g g g g 0.37g g 0.63…113GV2ME0530.370.55g g g g 0.370.550.75g g g g g g 1…1.622.5GV2ME0630.75g g1.1g g 1.6…2.533.5GV2ME0731.11.5g g g g 1.52.2g g g g 2.5…451GV2ME0832.2g g 350100 4…6.378GV2ME10334g g g g 45.510101001006…10138GV2ME1435.515507.5675 9…14170GV2ME1637.515509675 13…18223GV2ME203911151540401147517…23327GV2ME2131115401547520 (25)327GV2ME223Contact blocksDescription Mounting Maximum number Type of contacts Sold in lots of Unitreference Instantaneous auxiliary contactsFront 1N/O + N/C 10GVAE113N/O + N/O 10GVAE203LH side2N/O + N/C 1GVAN113N/O + N/O1GVAN203AccessoryDescriptionApplicationSold in lots of Unitreference Cable end reducerFor connection of conductors from 1 to 1.5 mm 220LA9D99(1) For connection of conductors from 1 to 1.5 mm 2, the use of an LA9 D99 cable end reducer is recommended.(2) Maximum rating which can be mounted in enclosures GV2 MC or MP , please consult your Regional Sales Office (3) The thermal trip setting must be within the range marked on the graduated knob.g > 100 kA.GV2 ME pp 3D F 526135.t i fLA9 D99D F 533898.e p sTeSys GVReferencesTeSys protection componentsThermal-magnetic motor circuit breakersGV2 P, GV3 P and GV3 ME80GV2 P10D F 526137.t i fGV3 P65D F 526139.t i fGV3 P651D F 526140.t i fC i r c u i t b r e a k e r sTeSys GVReferences93610011181001581007.59707010010091150501001001115101010010012…20GV7RS20 2.0109113636100100111518181001001518.58810010015…25GV7RE25 2.0109117070100100111550501001001518.5101010010015…25GV7RS25 2.01018.53610018.522181810010022810025…40GV7RE40 2.01018.57010018.550100221010025…40GV7RS40 2.0102236100301810030810030…50GV7RE50 2.01522701003050100301010030 (50)GV7RS502.01537361004555181810010055810048...80GV7RE80 2.040377010045555050100100551010048...80GV7RS80 2.0404536100–1810075810060...100GV7RE100 2.0404570100–50100751010060...100GV7RS100 2.0405575353510010075903030100100901108810010090 (150)GV7RE1502.020557570701001007590505010010090110101010010090…150GV7RS150 2.02090110353510010011013216030303010010010016020088100100132…220GV7RE220 2.3509011070701001001101321605050501001001001602001010100100132…220GV7RS220 2.350(1) As % of lcu.TeSys protection componentsThermal-magnetic motor circuit breakers GV7 RGV7 RE40D F 526138.t i fGV7 RS220D F 526141.t i f0.12–0.120.180.18–0.370.40…0.6313GV2RT040.090.120.250.370.250.370.370.550.63…122GV2RT050.180.250.370.550.370.550.370.550.750.751.11…1.633GV2RT060.370.750.751.1 1.11.51.6…2.551GV2RT070.550.75 1.11.5 1.51.52.2 2.23 2.5…478GV2RT081.12.22.23344…6.3138GV2RT101.52.234445.5 5.57.56…10200GV2RT142.23 5.55.57.57.59119…14280GV2RT1647.57.5991513…18400GV2RT205.5911111118.517…23400GV2RT21(1) The thermal trip setting must be within the range marked on the graduated knob.GV2 RTD F 526142.t i fC i r c u i t b r e a k e r sblack handle, blue legend plate(1) The thermal trip setting must be within the range marked on the graduated knob.(2) Other accessories such as mounting, cabling and marking accessories are identical to those used for GV2 ME motor circuit breakers, see page B6/13.GV2 RTD F 526142.t i fD F 526340.e p sC i r c u i t b r e a k e r sTeSys GVDescription Mounting Maximum number Type of contacts Sold inlots of Unitreference Instantaneous auxiliary contactsFront (1)1N/O or N/C (2)10GVAE1N/O + N/C 10GVAE11N/O + N/O10GVAE20Side (LH)2N/O + N/C1GVAN11N/O + N/O1GVAN20Fault signalling contact + instantaneous auxiliary contact Side (3) (LH)1N/O (fault)+ N/O1GVAD1010+ N/C1GVAD1001N/C (fault)+ N/O1GVAD0110+ N/C1GVAD0101Short-circuit signalling contactSide (LH)1C/O common point1GVAM11(1 block on RH sideof circuit breaker GV2 ME)50 Hz GVAX11560 Hz GVAX116127 V60 Hz GVAX115220…240 V 50 Hz GVAX22560 Hz GVAX226380…400 V50 Hz GVAX38560 Hz GVAX386415…440 V 50 Hz GVAX415440 V60 Hz GVAX385Add-on contact blocksDescriptionMountingMaximum number Reference Visible isolation block (5)Front (1)1GV2AK00 (6)LimitersAt top(GV2 ME and GV2 P)1GV1L3Independent1LA9LB920(1) Mounting of a GV AE contact block or a GV2 AK00 visible isolation block on GV2 P and GV2 L .(2) Choice of N/C or N/O contact operation, depending on which way round the reversible block is mounted.(3) The GV AD is always mounted next to the circuit breaker.(4) To order an undervoltage trip: replace the dot (p ) in the reference with a U , example: GV AU025. To order a shunt trip: replace the dot (p ) in the reference with an S , example: GV AS025.(5) Visible isolation of the 3 poles upstream of circuit breaker GV2 P and GV2 L .Visible isolation block GV2 AK00 cannot be used with motor circuit breakers GV2 P32 and GV2 L32 (Ith max = 25 A).(6) Ie Max = 32 A.ReferencesTeSys protection componentsThermal-magnetic and magnetic motor circuit breakers GV2 with screw clamp connectionsAdd-on blocks and accessoriesCharacteristics:pages B6/89 and B6/94Dimensions, schemes:pages B6/70 to B6/82LA9LB920D B 126629.e p sC i r c u i t b r e a k e r sTeSys GVTerminal blockfor supply to one or more GV2 G busbar setsConnection from the top1GV1G09Can be fitted with current limiter GV1 L3 (GV2 ME and GV2 P)1GV2G05Cover for terminal block For mounting in modular panels10LA9E07Flexible 3-pole connection for connecting a GV2 to a contactor LC1-D09…D25 Centre distance between mounting rails: 100…120 mm10GV1G02Set of connections upstream/downstream For connecting GV2 ME to a printed circuit board 10GV2GA01“Large Spacing” adapter UL 508 type EFor GV2 P pp H7 (except 32 A)1GV2GH7Clip-in marker holders (supplied with each circuit breaker)For GV2 P , GV2 L, GV2 LE and GV2 RT (8 x 22 mm)100LA9D92ReferencesTeSys protection componentsThermal-magnetic and magnetic motor circuit breakers GV2 with screw clamp connectionsAccessoriesDimensions, schemes:pages B6/70 to B6/82D B 417942.e p sTeSys GVD B 126631.e p sD B 126630.e p sD B 126632.e p s7P B 106297_45.e p sExtended Rotary HandleAllows a circuit breaker or a starter-controller installed in back of an enclosure to be operated from the front of the enclosure.A rotary handle can be black or red/yellow, IP54 or IP65. It includes a function for locking the circuit breaker or the starter in the O (Off) or I (On) position(depending of the type of rotary handle) by means of up to 3 padlocks with a shank diameter of 4 to 8 mm. The extended shaft must be adjusted to use in different size enclosures. The IP54 rotary handle is fixed with a nut (Ø22) to make easierthe assembling. The new Laser Square tool brings the accuracy to align the circuit breaker and the rotary handle.device(padlocks not included)ReferencesTeSys protection componentsThermal-magnetic and magnetic motor circuit breakers GV2 with screw clamp connectionsC i r c u i t b r e a k e r sTeSys GVDescriptionMounting Maximum number Type of contacts Sold inlots of Unitreference Instantaneous auxiliary contactsFront1N/O or N/C (1)10GVAE1N/O + N/C 10GVAE11 (2)N/O + N/O10GVAE20 (2)Side (LH)2N/O + N/C1GVAN11 (2)N/O + N/O1GVAN20 (2)Fault signalling contact + instantaneous auxiliary contactFront 1N/O (fault)+ N/O1GVAED101 (2)N/O (fault)+ N/C1GVAED011 (2)Side (3) (LH)1N/O (fault)+ N/O1GVAD1010+ N/C1GVAD1001N/C (fault)+ N/O1GVAD0110+ N/C1GVAD0101Short-circuit signalling contact Side (LH)1C/O common point 1GVAM11(4)MountingVoltage ReferenceSide(1 block on RH side of circuit breaker)24 V 50 Hz GVA p 02560 Hz GVA p 02648 V 50 Hz GVA p 05560 Hz GVA p 05610050 Hz GVA p 107100…110 V 60 Hz GVA p 107110…115 V 50 Hz GVA p 11560 Hz GVA p 116120…127 V 50 Hz GVA p 125127 V 60 Hz GVA p 115200 V50 Hz GVA p 207200…220 V 60 Hz GVA p 207220…240 V 50 Hz GVA p 22560 Hz GVA p 226380…400 V 50 Hz GVA p 38560 Hz GVA p 386415…440 V 50 Hz GVA p 415415 V 60 Hz GVA p 416440 V 60 Hz GVA p 385480 V 60 Hz GVA p 415500 V 50 Hz GVA p 505600 V60 HzGVA p 505AccessoriesDescription Reference Sets of 3-pole 115 A busbars Pitch: 64 mm2 tap-off GV3 P pp and GV3 L pp GV3G2643 tap-off GV3 P pp and GV3 L pp GV3G364Cover “Large Spacing” UL 508 type E (Only one cover required on supply side)GV3 P ppGV3G66(1) Choice of N/C or N/O contact operation, depending on which way round the reversible block is mounted.(2) Contact blocks available in version with spring terminal connections. Add a figure 3 at the end of the references selected above. Example: GV AED101 becomes GV AED1013.(3) The GV AD pp is always mounted next to the circuit breaker.(4) To order an undervoltage trip: replace the dot (p ) in the reference with a U , example: GV AU025. To order a shunt trip: replace the dot (p ) in the reference with an S , example: GV AS025.Add-on blocks and accessoriesGV3 G66D F 537424.e p sTeSys GVD B 126637.e p sD B 126636.e p sD B 126632.e p s7P B 106297_45.e p sExtended Rotary HandleAllows a circuit breaker or a starter-controller installed in back of an enclosure to be operated from the front of the enclosure.A rotary handle can be black or red/yellow, IP54 or IP65. It includes a function for locking the circuit breaker or the starter in the O (Off) or I (On) position(depending of the type of rotary handle) by means of up to 3 padlocks with a shank diameter of 4 to 8 mm. The extended shaft must be adjusted to use in different size enclosures. The IP54 rotary handle is fixed with a nut (Ø22) to make easierthe assembling. The new Laser Square tool brings the accurency to align the circuit breaker and the rotary handle.For English 10-GVAPSEN For German 10-GVAPSDE For Spanish10-GVAPSES For Chinese 10-GVAPSCN For Portuguese 10-GVAPSPT For Russian 10-GVAPSRU For Italian10-GVAPSITD F 526342.e p sB6/21C i r c u i t b r e a k e r sTeSys GVfor locking the Start button (on open-mounted product)using up to 3 padlocks(padlocks to be ordered separately)External operator for mounting on enclosure door.Red Ø40 knob on yellow plate, padlockable in position O (with up to 3 padlocks). Door locked when knob in position I, and when knob padlocked in position O.GK3AP03(1) 1 voltage trip OR 1 fault signalling contact to be fitted inside the motor circuit breaker.Other versions24 to 690 V, 50 or 60 Hz voltage trips for circuit breakers GV3 ME80.Please consult your Regional Sales Office.ReferencesTeSys protection componentsMotor circuit breakers GV3 ME80 and GK3 EF80Add-on blocks and accessoriesCharacteristics:pages B6/89 and B6/92Dimensions:page B6/47B6/22D F 526344.e p sB6/23C i r c u i t b r e a k e r sTeSys GVThese allow remote indication of the circuit breaker contact states. They can be used for signalling, electrical locking, relaying, etc. They are available in two versions: standard and low level. They include a terminal block and the auxiliary circuits leave the circuit breaker through a hole provided for this purpose.They perform the following functions, depending on where they are located in the circuit breaker:Low levelGV7AB11Fault discrimination devicesThese make it possible to:b either differentiate a thermal fault from a magnetic fault,b or open the contactor only in the event of a thermal fault.VoltageReference a 24...48 and c 24…72 V GV7AD111 (1)z 110…240 VGV7AD112 (1)Electric tripsThese allow the circuit breaker to be tripped via an electrical control signal.b Undervoltage trip GV7 AUv Trips the circuit breaker when the control voltage drops below the tripping threshold, which is between 0.35 and 0.7 times the rated voltage.v Circuit breaker closing is only possible if the voltage exceeds 0.85 times the rated voltage. Circuit breaker tripping by a GV7 AU trip meets the requirements of IEC 60947-2.b Shunt trip GV7 ASTrips the circuit breaker when the control voltage rises above 0.7 times the rated voltage.b Operation (GV7 AU or GV7 AS)v When the circuit breaker has been tripped by a GV7 AU or AS, it must be reset either locally or by remote control. (For remote control, please consult your Regional Sales Office).v Tripping has priority over manual closing: if a tripping instruction is present, manual action does not result in closing, even temporarily, of the contacts.v Durability: 50 % of the mechanical durability of the circuit breaker.TypeVoltageReference Undervoltage trip48 V, 50/60 HzGV7AU055 (1)110…130 V, 50/60 Hz GV7AU107 (1)200…240 V, 50/60 Hz GV7AU207 (1)380…440 V, 50/60 Hz GV7AU387 (1)525 V, 50 HzGV7AU525 (1)Shunt trip48 V, 50/60 HzGV7AS055 (1)110…130 V, 50/60 Hz GV7AS107 (1)200…240 V, 50/60 Hz GV7AS207 (1)380…440 V, 50/60 Hz GV7AS387 (1)525 V, 50 HzGV7AS525 (1)(1) For mounting of a GV7 AD or a GV7 AU or AS.ReferencesTeSys protection componentsThermal-magnetic motor circuit breakers GV7 R with screw clamp connectionsAdd-on blocks and accessoriesCharacteristics:pages B6/51, B6/52 and B6/56Dimensions:pages B6/79 to B6/81Schemes:page B6/83B6/24B6/25C i r c u i t b r e a k e r sTeSys GVDescription ApplicationFor use on contactors Sold in lots of Unitreference Clip-on connectors for GV7 RUp to 150 A, 1.5…95 mm 2–3GV7AC021Up to 220 A, 1.5…185 mm 2–3GV7AC022Spreader 3-pole (1)To increase the pitch to 45 mm–1GV7AC03Terminal shields IP 405 (1)Supplied with sealing accessory–1GV7AC01Phase barriersSafety accessories used when fitting of shields is impossible –2GV7AC04Insulating screens Ensure insulation between the connections and the backplate –2GV7AC05Kits for combination with contactor (2)Allowing link between thecircuit breaker and the contactor. The cover provides protection against direct finger contactLC1 F115…F1851GV7AC06LC1 F225 and F2651GV7AC07LC1 D115 and D1501GV7AC08Replaces the circuit breaker front cover; secured by screws. It includes a device for locking the circuit breaker in the O (Off) position by means of up to 3 padlocks with a shank diameter of 5 to 8 mm (padlocks not included). A conversion accessory allows the direct rotary handle to be mounted on the enclosure door. In this case, the door cannot be opened if the circuit breaker is in the “ON” position. Circuit breaker closing is inhibited if the enclosure door is open.Description TypeDegree of protection Reference Direct rotary handleBlack handle, black legend plate IP 40GV7AP03Red handle, yellow legend plateIP 40GV7AP04Adapter plate (3)Four mounting direct rotary handle on enclosure doorIP 43GV7AP05Allows a circuit breaker installed in the back of an enclosure to be operated from the front of the enclosure. It comprises:b a unit which screws onto the front cover of the circuit breaker,b an assembly (handle and front plate) to be fitted on the enclosure door,b an extension shaft which must be adjusted (distance between the mounting surface and the door: 185 mm minimum, 600 mm maximum). It includes a device for locking the circuit breaker in the O (Off) position by means of up to 3 padlocks with a shank diameter of 5 to 8 mm (padlocks not included). This prevents the enclosure door from being opened.DescriptionTypeDegree of protection Reference Extended rotary handleBlack handle, black legend plate IP 55GV7AP01Red handle, yellow legend plateIP 55GV7AP02Allows circuit breakers not fitted with a rotary handle to be locked in the O (Off) position by means of up to 3 padlocks with a shank diameter of 5 to 8 mm (padlocks not included).Description ApplicationReference Locking deviceFor circuit breaker not fitted with a rotary handleGV7V01(1) Terminal shields cannot be used together with spreaders.(2) The kit comprises links, a protective shield and a depth adjustable metal bracket for the breaker.(3) This conversion accessory makes it impossible to open the door if the device is closed and prevents the device from being closed if the door is open.ReferencesTeSys protection componentsThermal-magnetic motor circuit breakers GV7 R with screw clamp connectionsAccessoriesGV7 AC07D F 537429.e p sGV7 AC08D F 537428.e p sDimensions:pages B6/79 to B6/81B6/260.5 6.63GB2DB051143GB2DB062263GB2DB073403GB2DB084503GB2DB095663GB2DB106833GB2DB1281083GB2DB14101383GB2DB16121653GB2DB20162203GB2DB21202703GB2DB22(1) Conforming to IEC 60947-1.GB2 CBppD F 526243.t i fGB2 CD ppD F 526244.t i fGB2 DBppD F 526245.t i fPresentation, selection :page B6/84Characteristics :pages B6/85 to B6/87Dimensions :page B6/88Schemes :page B6/88B6/27C i r c u i t b r e a k e r s(1) Conforming to IEC 60947-1.Accessories for circuit breakers GB2-CB, DB and CSDescriptionSold in lots of Unitreference Busbar set for supply to 10 GB2 DB or20 GB2 CB or GB2 CS with 2 connectors1GB2G210Supply connector 10GB2G01GB2 CS ppD F 526246.t i fPresentation, selection :page B6/84Characteristics :pages B6/85 to B6/87Dimensions :page B6/88Schemes :page B6/88B6/28B6/29B6/30TeSys GVCharacteristicsTeSys protection componentsMagnetic motor circuit breakers GV2 LE and GV2 LReferences:pages B6/2 and B6/3Dimensions:pages B6/43 to B6/47Schemes:page B6/48add-on contact blocks. Side by side mounting is possible up to 40 °C.(2) When mounting on a vertical rail, fit a stop to prevent any slippage.(1) As % of Icu.Average operating times at 20 °C related to multiples of the setting currentD F 534092.e p s1 3 poles from cold state2 2 poles from cold state3 3 poles from hot stateDynamic stressI peak = f (prospective Isc) at 1.05 Ue = 435 VD F 534093.e p s1 Maximum peak current2 32 A3 25 A4 18 A5 14 A6 10 A7 6.3 A8 4 A9 2.5 A 10 1.6 A11 Limit of rated ultimate breaking capacity on short-circuit of GV2 LE (14, 18, 23 and 25 A ratings).Dynamic stressI peak = f (prospective Isc) at 1.05 Ue = 435 VD F 534094.e p s1 Maximum peak current2 32 A3 25 A4 18 A5 14 A6 10 A7 6.3 A8 4 A9 2.5 A 10 1.6 A11 Limit of rated ultimate breaking capacity on short-circuit of GV2 LE (14, 18, 23 and 25 A ratings).Thermal limit in kA 2s in the magnetic operating zone Sum of I 2dt = f (prospective Isc) at 1.05 Ue = 435 V22Prospective Isc (kA)D F 534095.e p s1 32 A 2 25 A3 18 A4 14 A5 10 A6 6.3 A7 4 A8 2.5 A9 1.6 AThermal limit in kA 2s in the magnetic operating zone Sum of I 2dt = f (prospective Isc) at 1.05 Ue = 435 V22D F 534096.e p s1 25 A and 32 A 2 18 A3 14 A 4 10 A5 6.3 A6 4 A7 2.5 A8 1.6 AThermal limit in kA 2s in the magnetic operating zone Sum of I 2dt = f (prospective Isc) at 1.05 Ue = 435 V22D F 534097.e p s1 32 A (GV2 LE32)2 25 A and 32 A (GV2 L32)3 18 A4 14 A5 10 A6 6.3 A7 4 A8 2.5 A9 1.6 A10 Limit of rated ultimate breaking capacity on short-circuit of GV2 LE (14, 18, 23 and 25 A ratings).Average operating time at 20 °C without prior current flowx the setting current (Ir)D F 534098.e p s1 3 poles from cold state2 2 poles from cold state3 3 poles from hot stateA Thermal overload relay protection zoneB GV3 L protection zoneDynamic stressI peak = f (prospective Isc) at 1.05 Ue = 435 VProspective Isc (kA)D B 418280.e p s1 Maximum peak current2 GV3 L653 GV3 L504 GV3 L405 GV3 L326 GV3 L25Thermal limit in A 2sSum of I 2dt = f (prospective Isc) at 1.05 Ue = 435 V2Prospective Isc (kA)D B 418279.e p s1 GV3 L652 GV3 L503 GV3 L404 GV3 L325 GV3 L25TeSys GVDimensions, mountingD F 537440.e p sD F 537441.e p sD F 537444.e p sTeSys protection componentsMagnetic motor circuit breakers GV2 L and GV2 LETeSys GVDimensions, mounting TeSys protection componentsMagnetic motor circuit breakers GV2 L and GV2 LED B 127415.e p sD B 127414.e p sa b Mini Maxi Mini Maxi GV2 APN pp140250GV2 APN pp + GV APH02151250GV2 APN pp + GV APK11250434--GV2 APN pp + GV APH02 + GV APK11--250445TeSys GVDimensions,mounting Sets of busbars GV2 G445, GV2 G454, GV2 G472, with terminal block GV2 G05D F 537451.e p sGV2 G445224269314359GV2 G454260314368422GV2 G472332404476548D F 537452.e p sD F 537454.e p sGV2 G345 (3 x 45 mm)134GV2 G354 (3 x 54 mm)152TeSys protection componentsMagnetic motor circuit breakers GV2 L and GV2 LED F 537480.e psD F 537435.e p sD F 510637.e p sD F 510638.e p sD B 127416.e p sD B 127417.e p sa b Mini Maxi Mini Maxi GV3 APN pp189300--GV3 APN pp + GV APK12300481GV3 APN pp + GV APH03--200300GV3 APN pp + GV APH03 + GV APK12--300492TeSys GVSchemesTeSys protection componentsMagnetic motor circuit breakers GV2 L, GV2 LE, GV3 LD F 537474.e p sD F 537475.e p sD F 537476.e p sGV2 ME, GV2 P , GV3 ME, GV3 P and GV7 R motor circuit breakers are 3-pole thermal-magnetic circuit breakers specifically designed for the control and protection of motors , conforming to standards IEC 60947-2 and IEC 60947-4-1.Connection GV2GV2 ME and GV2 P circuit breakers are designed for connection by screw clamp terminals.Circuit breaker GV2 ME can be supplied with lugs or spring terminal connections.Spring terminal connections ensure secure, permanent and durable clamping that is resistant to harsh environments, vibration and impact and are even more effective when conductors without cable ends are used. Each connection can take two independent conductors.GV3GV3 circuit breakers feature connection by BTR screws (hexagon socket head), tightened using a n° 4 Allen key.This type of connection uses the Ever Link ® system with creep compensation (1) (Schneider Electric patent).This technique makes it possible to achieve accurate and durable tightening torque, in order to avoid cable creep.GV3 circuit breakers are also available with connection by lugs. This type of connection meets the requirements of certain Asian markets and is suitable for applications subject to strong vibration, such as railway transport.GV7GV7 circuit breakers: with connection by screw clamp terminals (for bars and lugs) and by clip-on connectors.OperationControl is manual and local when the motor circuit breaker is used on its own.Control is automatic and remote when it is associated with a contactor.GV2 ME and GV3 ME80Pushbutton control.Energisation is controlled manually by operating the Start button “I” 1.De-energisation is controlled manually by operating the Stop button “O” 2, or automatically by the thermal-magnetic protection elements or by a voltage trip attachment.GV2 P , GV3 P and GV7 Rb Control by rotary knob: for GV2 P and GV3 P b Control by rocker lever: for GV7 R.Energisation is controlled manually by moving the knob or rocker lever to position “I” 1.De-energisation is controlled manually by moving the knob or rocker lever to position “O” 2.De-energisation due to a fault automatically places the knob or rocker lever in the “Trip” position 3.Re-energisation is possible only after having returned the knob or rocker lever to position “O”.(1) Creep: normal crushing phenomenon of copper conductors, that is accentuated over time.GV2 MEwith screw clamp terminals124D F 526134.t i fGV2 MEwith spring terminals connections124D F 526135.t i fGV3 P1324D F 526136.t ifGV2 P1342D F 526137.t i fGV7 R132D F 526138.t i f。

HD74LV1G04AInverterREJ03D0064-0800Rev.8.00 Mar 21, 2008DescriptionThe HD74LV1G04A has an inverter in a 5 pin package. Low voltage and high-speed operation is suitable for the battery powered products (e.g., notebook computers), and the low power consumption extends the battery life.Features• The basic gate function is lined up as Renesas uni logic series. • Supplied on emboss taping for high-speed automatic mounting. • Electrical characteristics equivalent to the HD74LV04A Supply voltage range : 1.65 to 5.5 VOperating temperature range : –40 to +85°C• All inputs V IH (Max.) = 5.5 V (@V CC = 0 V to 5.5 V) All outputs V O (Max.) = 5.5 V (@V CC = 0 V)• Output current ±6 mA (@V CC = 3.0 V to 3.6 V), ±12 mA (@V CC = 4.5 V to 5.5 V) • All the logical input has hysteresis voltage for the slow transition. • Ordering InformationPart NamePackage TypePackage Code (Previous Code) Package AbbreviationTaping Abbreviation(Quantity) HD74LV1G04ACME CMPAK–5 pinPTSP0005ZC-A(CMPAK-5V) CM E (3000 pcs/reel) HD74LV1G04AVSE VSON–5 pinPUSN0005KA-A(TNP-5DV)VSE (3000 pcs/reel)Note: Please consult the sales office for the above package availability.Outline and Article IndicationOutline and Article IndicationFunction TableInput A Output YH LL H H : High levelL : Low levelPin ArrangementAbsolute Maximum RatingsItem Symbol Ratings Unit Test ConditionsSupply voltage range V CC –0.5 to 7.0 VInput voltage range *1V I –0.5 to 7.0 V–0.5 to V CC + 0.5 Output : H or LOutput voltage range *1, 2 V O –0.5 to 7.0 VV CC : OFFInput clamp current I IK –20 mA V I < 0 Output clamp current I OK ±50 mA V O < 0 or V O > V CC Continuous output current I O ±25 mA V O = 0 to V CC Continuous current through V CC or GNDI CC or I GND ±50 mAMaximum power dissipationat Ta = 25°C (in still air) *3P T 200 mW Storage temperature Tstg–65 to 150°CNotes: The absolute maximum ratings are values, which must not individually be exceeded, and furthermore no twoof which may be realized at the same time.1. The input and output voltage ratings may be exceeded if the input and output clamp-current ratings areobserved.2. This value is limited to 5.5 V maximum.3. The maximum package power dissipation was calculated using a junction temperature of 150°C.Recommended Operating ConditionsItem Symbol Min Max Unit ConditionsSupply voltage range V CC 1.65 5.5 V Input voltage range V I 0 5.5 V Output voltage range V O 0 V CC V— 1 V CC = 1.65 to 1.95 V — 2 V CC = 2.3 to 2.7 V— 6 V CC = 3.0 to 3.6 V I OL— 12 V CC = 4.5 to 5.5 V— –1 V CC = 1.65 to 1.95 V — –2 V CC = 2.3 to 2.7 V— –6 V CC = 3.0 to 3.6 V Output current I OH— –12 mAV CC = 4.5 to 5.5 V 0 300 V CC = 1.65 to 1.95 V 0 200 V CC = 2.3 to 2.7 V0 100 V CC = 3.0 to 3.6 V Input transition rise or fall rate ∆t / ∆v 0 20 ns / VV CC = 4.5 to 5.5 V Operating free-air temperatureT a –40 85 °CNote: Unused or floating inputs must be held high or low.• Ta = –40 to 85°CItem Symbol V CC (V) * Min Typ Max Unit Test condition1.65 to 1.95 V CC ×0.75 — —2.3 to 2.7 V CC ×0.7 — —3.0 to 3.6 V CC ×0.7 — — V IH4.5 to5.5 V CC ×0.7 — —1.65 to 1.95 — — V CC ×0.252.3 to 2.7 — — V CC ×0.33.0 to 3.6 — — V CC ×0.3 Input voltage V IL4.5 to5.5 — — V CC ×0.3 V1.8 — 0.25 —2.5 — 0.30 —3.3 — 0.35 —Hysteresis voltage V H 5.0 — 0.45 — V V T + – V T –Min to Max V CC –0.1 — — I OH = –50 µA1.65 1.4 — — I OH = –1 mA2.3 2.0 — —I OH = –2 mA 3.0 2.48 — —I OH = –6 mA V OH4.5 3.8 — —I OH = –12 mAMin to Max — — 0.1I OL = 50 µA 1.65 — — 0.3 I OL = 1 mA 2.3 — — 0.4 I OL = 2 mA 3.0 — — 0.44I OL = 6 mAOutput voltageV OL4.5 — — 0.55 VI OL = 12 mA Input current I IN0 to 5.5 — — ±1 µA V IN = 5.5 V or GNDQuiescent supply current I CC 5.5 — — 10 µAV IN = V CC or GND,I O = 0Output leakage currentI OFF 0 — — 5 µA V IN or V O = 0 to 5.5 V Input capacitanceC IN 3.3 — 3.0 — pF V IN = V CC or GNDNote: For conditions shown as Min or Max, use the appropriate values under recommended operating conditions.• V CC = 1.8 ± 0.15 VTa = 25°C Ta = –40 to 85°CItem Symbol Min Typ Max Min Max UnitTestConditions FROM (Input) TO (Output)— 12.6 22.0 1.0 24.0 C L = 15 pF Propagation delay time t PLHt PHL — 19.7 33.0 1.0 36.0 nsC L = 50 pFAY• V CC = 2.5 ± 0.2 VTa = 25°C Ta = –40 to 85°CItem Symbol Min Typ Max Min Max UnitTestConditions FROM (Input) TO (Output)— 7.0 11.7 1.0 14.0 C L = 15 pF Propagation delay time t PLHt PHL — 10.5 15.5 1.0 18.0 nsC L = 50 pFAY• V CC = 3.3 ± 0.3 VTa = 25°C Ta = –40 to 85°CItem Symbol Min Typ Max Min Max UnitTestConditions FROM (Input) TO (Output)— 5.0 7.1 1.0 8.5 C L = 15 pF Propagation delay time t PLHt PHL — 7.5 10.6 1.0 12.0 nsC L = 50 pFAY• V CC = 5.0 ± 0.5 VTa = 25°C Ta = –40 to 85°CItem Symbol Min Typ Max Min Max UnitTestConditions FROM (Input) TO (Output)— 3.8 5.5 1.0 6.5C L = 15 pF Propagation delay time t PLH t PHL— 5.3 7.5 1.0 8.5nsC L = 50 pFAYOperating Characteristics• C L = 50 pFTa = 25°CItem Symbol V CC (V)Min Typ MaxUnit Test Conditions3.3 — 8.5 —Power dissipationcapacitanceC PD5.0 — 10.0 —pFf = 10 MHzTest CircuitWaveformsPackage DimensionsRefer to "/en/network " for the latest and detailed information.Renesas Technology America, Inc.450 Holger Way, San Jose, CA 95134-1368, U.S.A Tel: <1> (408) 382-7500, Fax: <1> (408) 382-7501Renesas Technology Europe LimitedDukes Meadow, Millboard Road, Bourne End, Buckinghamshire, SL8 5FH, U.K.Tel: <44> (1628) 585-100, Fax: <44> (1628) 585-900Renesas Technology (Shanghai) Co., Ltd.Unit 204, 205, AZIACenter, No.1233 Lujiazui Ring Rd, Pudong District, Shanghai, China 200120Tel: <86> (21) 5877-1818, Fax: <86> (21) 6887-7858/7898Renesas Technology Hong Kong Ltd.7th Floor, North Tower, World Finance Centre, Harbour City, Canton Road, Tsimshatsui, Kowloon, Hong Kong Tel: <852> 2265-6688, Fax: <852> 2377-3473Renesas Technology Taiwan Co., Ltd.10th Floor, No.99, Fushing North Road, Taipei, Taiwan Tel: <886> (2) 2715-2888, Fax: <886> (2) 3518-3399Renesas Technology Singapore Pte. Ltd.1 Harbour Front Avenue, #06-10, Keppel Bay Tower, Singapore 098632 Tel: <65> 6213-0200, Fax: <65> 6278-8001Renesas Technology Korea Co., Ltd.Kukje Center Bldg. 18th Fl., 191, 2-ka, Hangang-ro, Yongsan-ku, Seoul 140-702, Korea Tel: <82> (2) 796-3115, Fax: <82> (2) 796-2145Renesas Technology Malaysia Sdn. BhdUnit 906, Block B, Menara Amcorp, Amcorp Trade Centre, No.18, Jln Persiaran Barat, 46050 Petaling Jaya, Selangor Darul Ehsan, Malaysia Tel: <603> 7955-9390, Fax: <603> 7955-9510RENESAS SALES OFFICES。

V3.00GaAs Constant GammaHyperabrupt Tuning VaractorsMA46410 thru 480 SeriesFeaturesq Constant Gamma = 1.0, 1.25 or 1.5q High Q (up to 4000 at -4 Volts)q Larger Capacitance Change with Voltage q More Linear Frequency TuningqHigh and Nearly Constant Modulation SensitivityDescriptionThe MA46450, MA46470 and MA46410 series of tuning varactors are hyperabrupt junction Gallium Arsenide diodes featuring constant gamma 1.0 (MA46450 series),1.25 (MA46470 series) or 1.5 (MA46410 series). These diodes offer high Q (up to 4000) permitting excellent tun-ing performance from VHF through Ka band. Each part in this series exhibits the large change in capacitance versus bias voltage characteristic of hyperabrupt junctions. The standard capacitance tolerance is ±10%, with tighter toler-ances available. Capacitance matching at one or more bias voltages is also available. All diode types are available in a wide selection of ceramic packages and in chip form.ApplicationsThe constant gamma value of 1.0, 1.25 or 1.5 available with these diodes enables the circuit designer to produce significant improvements in circuit performance. Constant gamma tuning varactors permit more linear VCO frequen-cy tuning than do conventional hyperabrupt tuning varac-tors. These varactors are particularly well suited for use in voltage tuned filters, analog phase shifters, and modulatorcircuits.Case Styles30277V3.00* The maximum storage and operating temperature of the plastic1088 case style is 125°C.Absolute Maximum Ratings at +25°CElectrical Specifications at 25°CMA46450 SeriesGamma = 1.0Reverse Voltage 6= 22 Volts minimum Gamma 4= 0.9 - 1.1, V R = 2 - 20 VoltsJunction Capacitance Ratio (C J2/C J20) = 5.0 - 8.0MA46470 SeriesGamma = 1.25Reverse Voltage 6= 22 Volts minimum Gamma 4= 1.13 - 1.38, V R = 2 - 20 VoltsJunction Capacitance Ratio (C J2/C J20) = 8.15 - 12.99Notes:1.All GaAs tuning varactors are available in chip form as well as the case styles shown on the following page.When ordering, specify the desired case by adding the case designation as a suffix to the type number.2.Case parasitics (C p and L s ) are given for most case styles along with case outlines in the appendix.The Cp values listed typically have toler-ances of ±0.02 pF .3.The nominal tolerance at -4 Volts is ±10%.Closer tolerances are avail-able upon request.By adding the suffix A to the part number, a toler-ance of ±5% at -4 Volts is guaranteed.4.The values guaranteed for gamma are measured on unpackaged chips.The total capacitance versus bias voltage curve will deviateslightly from the chip capacitance versus bias voltage curve due to the package parasitic capacitance (Cp).5.Capacitance is measured at 1 MHz.6.Reverse voltage (V B ) is measured at 10 microamps.7.The total capacitance and capacitance ratios shown are for diodes housed in case style 30.Other case styles will result in different val-ues.Total 2, 6, 7Total50 MHz Capacitance Capacitance 7Q at Model Case 1@ -4 Volts Ratio (2/12)-4 Volts Number Style Min./Max.(pF)Min./Max.Typical MA46410300.45-0.60 2.7-4.33000MA46413300.90-1.10 4.2-5.72500MA4641630 1.62-1.98 5.2-4.92500MA4641830 2.42-2.97 5.7-7.61800MA4642030 3.33-4.22 6.0-8.11800MA4642130 4.22-5.17 6.2-8.31200MA4642230 5.04-6.16 6.3-8.41200MA46425309.00-11.006.6-8.81200Environmental Ratings PER MIL-STD-750MIL MethodLevelStorage Temperature 1031See maximum ratingsTemperature Cycle 105110 cycles, -65°C to +175°C Shock 2016500 g’s Vibration 205615 g’s Constant Acceleration 200620,000 g’s Humidity 102110 daysMA46410 Series Gamma = 1.5Breakdown Voltage 6= 18 Volts minimum Gamma 4= 1.4 - 1.6, V R = 2 - 12 VoltsJunction Capacitance Ratio (C J2/C J12) = 6.2 - 10.84V3.00 Case Styles (See appendix for complete dimensions).1100V R(VOLTS).1100V R(VOLTS).1100V R(VOLTS).1100V R(VOLTS).1110100V R(VOLTS)V R(VOLTS).1110100V R(VOLTS)。

ebm-papst St.Georgen GmbH&Co.KGHermann-Papst-Straße1D-78112St.GeorgenPhone+49772481-0Fax+49772481-1309info2@Nominal dataType6424Nominal voltage VDC24Nominal voltage range VDC12..28Speed min-13400Power input W18.0Min.ambient temperature°C-20Max.ambient temperature°C72Air flow m3/h410Sound power level B 6.4Sound pressure level dB(A)57ml=max.load·me=max.efficiency·fa=running at free air·cs=customer specs·cu=customer unitSubject to alterationsTechnical featuresGeneral description Particular design features:Optional Vario-Pro:Highly flexible software configuration for the fan ensures an easily customisablesolution to meet the individual requirements of your application.General features:Housing made of aluminium,impeller made of fibreglass-reinforced PA;housing with grounding lugfor M4x8screw(Torx).48V version incl.screws.Electronic commutation completely integrated.Protected against reverse polarity and locking.Electrical connection to flat plugs,3x0.5mm.Air exhaust over bars.Direction of rotation counter-clockwise seen on rotor.Mass:760g.Mass0.760kgDimensions172x150x51mmMaterial of impeller Fiberglass-reinforced PA plasticHousing material Aluminum.Housing with grounding lug for screw M4x8(TORX).Direction of air flow Air exhaust over barsDirection of rotation Left,looking at rotorBearing Ball bearingsLifetime L10at40°C75000h35000hLifetime L10at maximumtemperatureConnection line Flat plugs3.0x0.5mm.Motor protection Protected against reverse polarity and locking.Locked-rotor protection Electronic blocking protection,with electronic motor current limit in the startup phase and when therotor is blocked.Approval VDE,CSA,UL,CEProduct drawing LuCharts:Air flow分销商库存信息: EBM-PAPST6424。

ORDERING INFORMATIONFEATURES• Superminiature type, light-weight snap action switchPC board terminal type(0.2g)Solder terminal type with mounting holes (0.3g)mm• Mechanical life of 300,000 operations minimumStainless steel plated silver or gold is used for actuating spring• Switches can be mounted closetogether in any directionsTYPICALAPPLICATIONS• Compact visual equipment Camera, portable VCR• Small-sized audio equipment Cassette tape recorder, Car stereo • Office automation equipmentLight pen for personal computer, floppy disc apparatus, printer, computerCONSTRUCTIONPC board straight terminal typeCONTACT ARRANGEMENTAECTB16E 201201-TPanasonic Corporation Automation Controls Business Unit /ac/e RoHS compliant/AV4PRODUCT TYPESSPECIFICATIONS1. Contact rating2. CharacteristicsDATAGold plate contact typeRange of low-level current and voltage (Reference only)Type of contactsActuatorOperating force, Max.T ype No.PC board terminalSolder terminal with mounting holesStraight terminal Angle terminalReverse angleterminalSilver plated contact typePin plunger 0.98 NAV4404AV4504AV4604AV4004Hinge lever0.25 N AV4424AV4524AV4624AV4024Simulated roller lever 0.29 N AV4444AV4544AV4644AV4044Gold plated contact typePin plunger 0.98 N AV440461AV450461AV460461AV400461Hinge lever0.25 N AV442461AV452461AV462461AV402461Simulated roller lever0.29 NAV444461AV454461AV464461AV404461Type of contact Resistive load (cos φ]1)Silver plated contact 0.5A 30V DC Gold plated contact0.1A 30V DCItemsCharacteristicsLifeMechanicalMin. 3 × 105operations (at 60 cpm)ElectricalSilver plated contact Min. 2 × 104 operations (0.5A 30V DC; at 20 cpm)Gold plated contactMin. 2 × 105 operations (0.1A 30V DC; at 20 cpm)Insulation resistanceMin. 100 M Ω (250V DC by insulation resistance meter)VoltagewithstandBetween non-continuous terminals500V AC for 1 min.Between each terminal and other exposed metal parts500V AC for 1 min.Between each terminal and ground500V AC for 1 min.Vibration resistancePin plunger type10 to 55 Hz at single amplitude of 0.75mm (contact opening: max. 1 msec.)Lever type10 to 55 Hz at single amplitude of 0.15mm (contact opening: max. 1 msec.)Shock resistancePin plunger typeMin. 294m/s 2 (contact opening: max. 1 msec.)Lever typeMin. 147m/s 2 (contact opening: max. 1 msec.)Contact resistance (initial value)Max. 200 m Ω (by YHP4328A)Allowable operation speed0.1mm/s to 500mm/s (pin plunger type)Mechanical max. switching frequency 60 operations/min.Ambient temperature –25 to +80°C (Not freezing below 0°C)Unit weightPC board terminal type: Approx. 0.2gSolder terminal with mounting holes type: Approx. 0.3gDC voltage (V)A E CTB16E 201201-TPanasonic Corporation Automation Controls Business Unit /ac/e/AV4DIMENSIONSmm General tolerance: ±0.151. PC board terminal Straight terminalPin plunger typePC board patternPretravel0.3 max.Movement Differential 0.1 max.Overtravel0.1 min.Operating Position 4.8±0.15Free Position 5.2 max.Hinge lever typeNote:All other dimensions are the same asthose of pin plunger type.Pretravel2.4 max.Movement Differential 0.7 max.Overtravel0.4 min.Operating Position 5.8±0.7Free Position 7.5 max.Simulated roller lever typeNote:All other dimensions are the same asthose of pin plunger type.Pretravel2.2 max.Movement Differential 0.7 max.Overtravel0.3 min.Operating Position 6.1±0.7Free Position 8.0 max.AECTB16E 201201-TPanasonic Corporation Automation Controls Business Unit /ac/e The CAD data of the products with a mark can be downloaded from: /ac/e/AV42. Angle terminal Right angle terminal Pin plunger typeplungerRight angle terminalmm General tolerance: ±0.15Note:All other dimensions of hinge lever type and simulated roller lever type are thesame as those of straight terminaltypes.Pretravel0.3 max. Movement Differential0.1 max. Overtravel0.1 min. Operating Position 4.8±0.15 Free Position 5.2 max.Left angle terminal Pin plunger typeplungerLeft angle terminalNote:All other dimensions of hinge lever typeand simulated roller lever type are thesame as those of straight terminaltypes.Pretravel0.3 max.Movement Differential0.1 max.Overtravel0.1 min.Operating Position 4.8±0.15Free Position 5.2 max.3. Solder terminal with mounting holesPin plunger typePretravel0.3 max.Movement Differential0.1 max.Overtravel0.1 min.Operating Position 5.4±0.15Free Position 5.8 max.A E CTB16E 201201-T Panasonic Corporation Automation Controls Business Unit /ac/e/AV4NOTESHinge lever typemm General tolerance: ±0.15Note:All other dimensions are the same asthose of pin plunger type.Pretravel2.4 max.Movement Differential 0.7 max.Overtravel0.4 min.Operating Position 6.4±0.6Free Position 9.0 max.Simulated roller lever typeNote:All other dimensions are the same asthose of pin plunger type.Pretravel2.2 max.Movement Differential 0.7 max.Overtravel0.3 min.Operating Position 6.7±0.5Free Position 9.4 max.1. Mounting1) After mounting and wiring, theinsulation distance between ground and each terminal should be confirmed as sufficient.2) When the operation object is in the free position, force should not be applied to the actuator or to the pin plunger. Also force should be applied to the pin plunger from vertical direction to the switch.3) In setting the movement afteroperation, the over-travel should be set within the range of the specified O.T . value.4) In fastening the switch body, use the M1.4 screw, with tightening torque of not more than 0.098 N·m.2. Soldering1) Manual soldering should beaccomplished within 5 seconds with max. 350°C iron.Care should be taken not to apply force to the terminals during soldering.2) T erminal portion must not be moved within 1 minute after soldering. Also no tensile strength of lead wires should be applied to the terminals.3) When using the angle terminal type, insert an insulation separator between the switch body and the printed circuit board (Insulation separator 0.2 to 0.4mm thick) to prevent the soldering flux from flowing under the PC board.3. CleaningAs AV4 switch is not completely sealed construction, avoid cleaning.4. Selection of switchWhen specifying AV4 switches, allow ±20% to the listed operating characteristics.5. Avoid using and keeping switches in the following conditions:• In corrosive gases• In a dusty environment• Where silicon atmosphere prevails 6. When switching low-level circuits (max. 100 mA), gold plate contact types are recommended.7. When using the lever type, avoid applying force from the reverse and side direction of actuating.AECTB16E 201201-TPanasonic Corporation Automation Controls Business Unit /ac/e /分销商库存信息:PANASONICAV444461AV4444AV4524 AV404461AV4004AV4404 AV4644AV4424AV4024 AV4544AV4624AV450461 AV460461AV400461AV440461 AV442461AV402461AV452461 AV454461AV462461AV464461 AV4424619AV4044。

元器件交易网This datasheet is under modification and could not be completed intime for this CD-ROM. Before designing in, please be so kind as to contact your nearest OKI office or representative. The reviseddatasheet will be included in the next CD-ROM issue. Please alsowatch our web sites for further announcements. We sincerelyapologise for any inconveniences.Oki Electric Industry Co., Ltd., Tokyo, JapanDevice Business GroupMarketing Communicationstel: +81-3-5445-6027fax: +81-3-5445-6058email: brenner595@dm1.oii.oki.co.jphttp://www.oki.co.jp/semi/1/24GENERAL DESCRIPTIONThe MSM64155A (1.5 V)/64155AL (3.0 V) is a 4-bit microcontroller that incorporates an nX-4/20 CPU core. The MSM64155A family offers a built-in 256-nibble data memory, 4-Kbyte program memory, melody output, LCD driver, and other functions.FEATURES•Operating range Operating voltage:1.5 V/3.0 V Operating temperature :–40 to +70 °COperating frequency :32.768 kHz crystal oscillation Approx. 32 kHz RC oscillation Current consumption (TYP.):0.9 m A (3.0 V at HALT mode)•Minimum instruction execution time:91 m s•General memory space :4064 bytes •Local memory space :256 nibbles •LCD driver:64Common driver ¥ 4Segment driver ¥ 601/4 duty, 1/3 bias; 240 segments (60 ¥ 4)1/3 duty, 1/3 bias; 180 segments (60 ¥ 3)•I/O portInput-output port :2 ports ¥ 4 bits (open-drain output/CMOS output selectable; pull-down resistor input selectable)Input port :1 port ¥ 2 bits (A pull-down resistor input can be selected)1 port ¥ 4 bits (pull-down resistor input)Output port :1 port ¥ 4 bits (CMOS output)•Counter:1 channel •Melody output :2•Interrupts:10 sourcesExternal 4, time base 4, melody 2•Package:100-pin plastic QFP (QFP100-P-1420-0.65-BK) : (Product name :MSM64155A-¥¥¥GS-BK,MSM64155AL-¥¥¥GS-BK)Chip¥¥¥ indicates the code number.•OTP version :MSM64P155/64P155L(The power polarity and operating voltage of the MSM64P155/64P155L are different from the MSM64155A/64155AL. For details, refer to the MSM64P155 User's Manual.)MSM64155A/64155ALBuilt-in Melody Circuit and LCD Driver 4-Bit MicrocontrollerE2E0030-27-Y3元器件交易网MSM64155A/64155AL¡ Semiconductor2/24BLOCK DIAGRAMV SS1V SS2V SS3C 1C 23/24PIN CONFIGURATION (TOP VIEW)RESET OSCO OSC1V SSL P2.3P2.2P2.1P2.0P3.1P3.0P4.3P4.2P4.1P4.0P6.3P6.2P6.1P6.0P7.3P7.2P7.1P7.0V DD MD0MD0MD1MD1TST3TST2TST1S E G 41S E G 42S E G 43S E G 44S E G 45S E G 46S E G 47S E G 48S E G 49S E G 50(N C )S E G 51S E G 52S E G 53S E G 54S E G 55S E G 56S E G 57S E G 58S E G 59SEG11SEG12SEG13SEG14SEG15SEG16SEG17SEG18SEG19SEG20SEG21SEG22SEG23SEG24SEG25SEG26SEG27SEG28SEG29SEG30SEG31SEG32SEG33SEG34SEG35SEG36SEG37SEG38SEG39SEG40E G 10E G 9E G 8E G 7E G 6E G 5E G 4E G 3E G 2E G 1E G 0O M 4O M 3O M 2O M 121S S 3S S 2S S 1NC: No-connection pin 100-Pin Plastic QFP4/24PIN DESCRIPTIONSBasic FunctionsPad —Power SupplyPin Digital supply voltage(0 V)DescriptionType 21Function OscillationTestRESET2310099989796497969594932——————Digital negative supply voltage (1.5 V operation)Bias output for LCD driver (3.0 V operation)Digital negative supply voltage (3.0 V operation)Bias output for LCD driver (1.5 V operation)Bias output for LCD driver (–4.5 V)For connection to capacitors that generate bias for the LCD driverNegative supply voltage pin for internal logic (internally generated constant voltage)Clock oscillation pins:Quartz oscillator (32.768 kHz) and capacitor (10 pF to 30 pF) or resistor (1 M W ) are connected.23991I O 302928282726I I I Input pins for test198ISystem reset input :When this pin switches from "L" to "H", the internal status is initialized and instructions start executing from address 000H. The pin has a built-in pull-down resistor which pulls the signal down to V SS1 or V SS2.Symbol V DD V SS1V SS2V SS3C 1C 2V SSL OSC0OSC1TST1TST2TST3RESET5/24IPorts4-bit input port (port 2) :Select between pull-down resistor input and high impedance input for each bit with the port 2 control register (P2CON). When configured for secondary functions, an external interrupt and capture circuit trigger input are allocated.If P2.0 to P2.3 are set to "H" level, the IC enters system reset mode.68761095487I2-bit input port (port 3) :Select between pull-down resistor input and high impedance input with the port 3 control register (P3CON).When configured for a secondary function, an external interrupt is allocated to P3.0 and an event counter is allocated to P3.1.53O4-bit output port (port 4) :4-bit CMOS output port.121413*********I/O4-bit input-output port (port 6) :Select between input and output, between pull-down resistor input and high impedance input, and between open-drain output and CMOS output with the port 6 control register (P6CON). When configured for a secondary function, an external interrupt is allocated.1618171615141513I/O4-bit input-output port (port 7) :Select between input and output, between pull-down resistor input and high impedance input, and betweenopen-drain output and CMOS output with the port 7 control register (P7CON). When configured for a secondary function, an external interrupt is allocated.2022212019181917Melody DriversO Output pin of melody driver 0.2325O Negative-phase output pin of MD0 output.2224O Output pin of melody driver 1.2426O Negative-phase output pin of MD1 output.2527O LCD common signal output pins.9295949391909289LCD DriversO O OPad Pin DescriptionType Function P2.0P2.1P2.2P3.0P3.1P2.3P4.0P4.1P4.2P4.3P6.0P6.1P6.2P6.3P7.0P7.1P7.2P7.3MD0MD0MD1MD1COM1COM2COM3COM4Symbol6/24O LCD segment signal output pins.8891O 8790O 8689O 8588O 8487O 8386O 8285O 8184O 8083O 7982O 7881O 7780O 7679O 7578O 7477O 7376O 7275O 7174O 7073O 6972LCD DriversO 6871O 6770O 6669O 6568O 6467O 6366O 6265O 6164O 6063O 5962O 5861O 5760O 5659O 5558O 5457O 5356O 5255O 5154O 5053O4952Pad Pin DescriptionType Function SEG0SEG1SEG2SEG3SEG4SEG5SEG6SEG7SEG8SEG9SEG10SEG11SEG12SEG13SEG14SEG15SEG16SEG17SEG18SEG19SEG20SEG21SEG22SEG23SEG24SEG25SEG26SEG27SEG28SEG29SEG30SEG31SEG32SEG33SEG34SEG35SEG36SEG37SEG38SEG39Symbol7/24Secondary FunctionsO LCD segment signal output pins.4851O 4750O 4649O 4548O 4447O 4346O 4245O 4144O 4043O 3942O 3841O 37O 3639O 3538O 3437O 3336O 3235O 3134O 3033O2932LCD Drivers31Pad Pin DescriptionType Function SEG40SEG41SEG42SEG43SEG44SEG45SEG46SEG47SEG48SEG49SEG50SEG51SEG52SEG53SEG54SEG55SEG56SEG57SEG58SEG59Symbol8/24Secondary Functions (Continued)IP2.0 to P2.3 secondary functions :These are level-triggered external interrupt input pins. Select interrupt enable/disable for each bit with the P2 interrupt enable register (P21E).If P2.0 to P2.3 pins are set to “H” level for a minimum of 2 seconds, the device enters system reset mode.P2.0, P2.1 secondary functions :trigger input pins for capture circuit.68574635External InterruptsIP3.0 secondary functions :This is an input pin for external interrupt. This pin can receive an interrupt at a rising edge, a falling edge, or at both rising and falling edges.810IP6.0 to P6.3 secondary functions :These are level-triggered external interrupt input pins.1618151714161315IP7.0 to P7.3 secondary functions :These are level-triggered external interrupt input pins.2022192118201719IP3.1 secondary functions :input port for event counter79Event Counter InputPad Pin DescriptionType Function P2.0P2.1P2.2P2.3P3.0P6.0P6.1P6.2P6.3P7.0P7.1P7.2P7.3P3.1Symbol9/24Connections of Unused PinsOpenRecommended Pin ConnectionSymbol TST1 to 3"L" level or open P2.0 to P2.3"L" level or open P3.0 to P3.1OpenP4.0 to P4.3Open COM1 to 4OpenSEG0 to 59For input setting : "L" level or open (Initial value is an input mode.)For output setting : OpenP6.0 to P6.3For input setting : "L" level or open (Initial value is an input mode.)For output setting : Open P7.0 to P7.3Open MD0, MD0MD1, MD1ABSOLUTE MAXIMUM RATINGS 1.5 V Operation (MSM64155A)RECOMMENDED OPERATING CONDITIONS 1.5 V Operation (MSM64155A)Rating ParameterPower Supply Voltage 1Power Supply Voltage 2Power Supply Voltage 3Power Supply Voltage 4Input Voltage 1(V DD =0 V)Symbol Condition Unit Output Voltage 1Output Voltage 2Output Voltage 3Output Voltage 4Storage TemperatureInput Voltage 2V SS1V SS2V SS3V SSL V IN1V OUT1V OUT2V OUT3V OUT4T STGV IN2Ta=25°C Ta=25°C Ta=25°C Ta=25°C V SS1 input, Ta=25°C V SS1 input, Ta=25°C V SS2 input, Ta=25°C V SS3 input, Ta=25°C V SSL input, Ta=25°CV SSL input, Ta=25°C –2.0 to +0.3–4.0 to +0.3–5.5 to +0.3–2.0 to +0.3V SS1 –0.3 to +0.3V SS1 –0.3 to +0.3V SS2 –0.3 to +0.3V SS3 –0.3 to +0.3V SSL –0.3 to +0.3–55 to +125V SSL –0.3 to +0.3V V V V V V V V V °CV —Unit ConditionOperating Temperature Operating Voltage T op V SS1–40 to +70–1.7 to –1.25°C V Crystal Oscillator Frequencyf XT 30 to 35kHz CROSC External ResistanceR OS1 M±10%W—BUPF="0"——Range Parameter(V DD =0 V)Symbol –1.7 to –1.15BUPF="1"ELECTRICAL CHARACTERISTICS 1.5 V Operation (MSM64155A)DC CharacteristicsParameter(V DD =0 V, V SS1=–1.5 V, Ta=–40 to +70°C unless otherwise specified.)Symbol Condition Unit Measuring CircuitMin.Typ.Max.V SS2 VoltageV SS2Ca, Cb, C 12=0.1 m F Ta=–40 to +60°CBUPF="0"+100%–20%–3.2–3.0–2.8V Ca, Cb, C 12=0.1 m F Ta=–40 to +70°CBUPF="0"+100%–20%–3.2–3.0–2.7Ca, Cb, C 12=0.1 m F Ta=–40 to +60°CBUPF="1"+100%–20%–3.2–3.0–2.5Ca, Cb, C 12=0.2 m F Ta=–40 to +70°CBUPF="1"+100%–20%–3.2–3.0–2.3Ca, Cb, C 12=0.1 m F Ta=–40 to +60°CBUPF="0"+100%–20%–4.7–4.5–4.2V Ca, Cb, C 12=0.1 m F Ta=–40 to +70°CBUPF="0"+100%–20%–4.7–4.5–4.0Ca, Cb, C 12=0.1 m F Ta=–40 to +60°CBUPF="1"+100%–20%–4.7–4.5–3.9Ca, Cb, C 12=0.2 m F Ta=–40 to +70°CBUPF="1"+100%–20%–4.7–4.5–3.711'V SS3 VoltageV SS3BUPF="0"–1.5–1.3–0.6V V SSL VoltageV SSL BUPF="1"–1.9–1.3–0.6Within 5 seconds after oscillation starts——–1.45V XTOSC Oscillation Start Voltage V STA ———–1.15V XTOSC Oscillation Hold Voltage V HOLD —10—30pF XTOSC External Capacitance CG —101520pF XTOSC Internal Capacitance CD R OS = 1M W 154075kHz1'CROSC Oscillation Frequencyf CR1Notes:1."XTOSC" indicates the 32.768 kHz crystal oscillation circuit.2."CROSC" indicates the 32 kHz RC oscillation circuit.DC Characteristics•32.768 kHz crystal oscillationMeasuringCircuitCurrent Consumption 1 Current Consumption 1I DD1I DD1I DD2I DD2CPU in HALT stateBUPF="0"22364010501525m A1Current Consumption 2 Current Consumption 2Ta=–40 to +40°CTa=+40 to +70°CTa=–40 to +40°CTa=+40 to +70°CTa=–40 to +40°CTa=+40 to +70°CTa=–40 to +40°CTa=+40 to +70°C36610105060m Am Am Am Am Am Am A CPU in HALT stateBUPF="1"CPU in operation stateBUPF="0"CPU in operation stateBUPF="1"————————Parameter(V DD=0 V, V SS1=–1.5 V, Ta=–40 to +70°C unless otherwise specified.) Symbol Condition UnitMin.Typ.Max.•RC oscillationMeasuringCircuitCurrent Consumption 1 Current Consumption 1I DD1I DD1I DD2I DD2CPU in HALT stateBUPF="0"336104515502030m A1'Current Consumption 2 Current Consumption 2Ta=–40 to +40°CTa=+40 to +70°CTa=–40 to +40°CTa=+40 to +70°CTa=–40 to +40°CTa=+40 to +70°CTa=–40 to +40°CTa=+40 to +70°C67715155070m Am Am Am Am Am Am A CPU in HALT stateBUPF="1"CPU in operation stateBUPF="0"CPU in operation stateBUPF="1"————————Parameter(V DD=0 V, V SS1=–1.5 V, R OS=1 M W, Ta=–40 to +70°C unless otherwise specified.) Symbol Condition UnitMin.Typ.Max.DC CharacteristicsOutput Current 1Output Current 3Output Current 2Output Leakage CurrentI OH1I OL1I OH3I OL32(P4.0 to P4.3)(MD0, MD0)(MD1, MD1)(P6.0 to P6.3)(P7.0 to P7.3)(SEG0 to SEG59)(COM1 to COM4)(P4.0 to P4.3)(P6.0 to P6.3)(P7.0 to P7.3)I OH2I OMH2I OMH2S I OML2I OML2S I OL2I OOH I OOL V OH1=–0.5 V V OL1=V SS1+0.5 V V OH3=–0.5 V V OL3=V SS1+0.5 V V OH2=–0.2 V V OMH2=V SS1+0.2 V V OMH2S =V SS1–0.2 V V OML2=V SS2+0.2 V V OML2S =V SS2–0.2 V V OL2=V SS3+0.2 V V OH =V DD V OL =V SS1(V SS2 level)(V SS3 level)(V SS1 level)(V SS2 level)(V DD level)(V SS1 level)–2.00.1–5.00.1444–0.3–0.60.6–2.10.7–0.12.0–0.32.0–4–4–40.3mA mA mAmA m A m A m A m A m A m A m A m A ————————————————Measuring CircuitParameter (Pin Name)(V DD =0 V, V SS1=V SSL =–1.5 V, V SS2=–3.0 V, V SS3=–4.5 V,Ta=–40 to +70°C unless otherwise specified.)Symbol Condition Unit Min.Typ.Max.Input Current 1Input Current 2Input Current 3Input Voltage 1I IH1I IH1Z I IH2I IL23(P2.0 to P2.3)(P3.0 to P3.1)(P6.0 to P6.3)(P7.0 to P7.3)(TST1, TST2, TST3)(RESET)(P2.0 to P2.3)(P3.0 to P3.1)(P6.0 to P6.3)(P7.0 to P7.3)(TST1, TST2, TST3)(RESET)I IH3I IL3V IH1V IL1V IH1=V DD (when pulled down)V IH1=V DD (at high impedance)V IH2=V DD V IL2=V SS1V IH3=V DD V IL3=V SS1100.3–1–1–1.5200.754010011.501000m A m A mA m A m A m A VVI IL1V IL1=V SS1–10m A 415–0.30–1.2————————Measuring circuit 1C L CGm F m FMeasuring circuit 1'C LR OS12: 0.1 to 0.2 m F: 0.1 m F: 1 M WMeasuring circuit 2Measuring circuit 3V IHV ILMeasuring circuit 4V IHV IL* 1Input logic is set to the designated state.* 2Measurement is repeated for the designated output pins. * 3Measurement is repeated for the designated input pins.ABSOLUTE MAXIMUM RATINGS 3.0 V Operation (MSM64155AL)Rating ParameterPower Supply Voltage 1Power Supply Voltage 2Power Supply Voltage 3Power Supply Voltage 4Input Voltage 1(V DD =0 V)Symbol Condition Unit Output Voltage 1Output Voltage 2Output Voltage 3Storage TemperatureInput Voltage 2V SS1V SS2V SS3V SSL V IN1V OUT1V OUT2V OUT3T STGV IN2Ta=25°C Ta=25°C Ta=25°C Ta=25°C V SS2 input, Ta=25°C V SS2 input, Ta=25°C V SS3 input, Ta=25°C V SSL input, Ta=25°CV SSL input, Ta=25°C –2.0 to +0.3–4.0 to +0.3–5.5 to +0.3–4.0 to +0.3V SS2 –0.3 to +0.3V SS2 –0.3 to +0.3V SS3 –0.3 to +0.3V SSL –0.3 to +0.3–55 to +125V SSL –0.3 to +0.3V V V V V V V V °CV —RECOMMENDED OPERATING CONDITIONS 3.0 V Operation (MSM64155AL)Operating Temperature Operating Voltage T op V SS2–40 to +70–3.5 to –2.5°C V Crystal Oscillator Frequency f XT 30 to 66kHz BUPF="0"BUPF="1"–3.5 to –2.0—Range Parameter(V DD =0 V)Symbol ConditionUnit —CROSC External ResistanceR OS1 M±10%W—ELECTRICAL CHARACTERISTICS 3.0 V Operation (MSM64155AL)DC CharacteristicsV SS1 Voltage V SS3 Voltage XTOSC Oscillation Start Voltage XTOSC Oscillation Hold VoltageXTOSC External Capacitance XTOSC Internal Capacitance V SS1V SS3V STA V HOLD CG CD Ca, Cb, C 12=0.1 m F Ca, Cb, C 12=0.1 m F Within 5 seconds afteroscillation starts–1.7–4.71010+100%–20%+100%–20%–1.5–4.515–1.3–4.2–2.5–2.03020VVV V pF pF 1————————Parameter(V DD =0 V, V SS2=–3.0 V, Ta=–40 to +70°C unless otherwise specified.)Symbol Condition Unit Measuring CircuitMin.Typ.Max.V SSL VoltageV SSL–1.5–1.3–0.6V BUPF="0"–1.9–1.3–0.6BUPF="1"CROSC Oscillation Frequencyf CR154075kHzR OS =1 M W1'11'Notes:1."XTOSC" indicates the 32.768 kHz crystal oscillation circuit.2."CROSC indicates the 32 kHz RC oscillation circuit.DC Characteristics•32.768 kHz crystal oscillationMeasuringCircuitCurrent Consumption 1 Current Consumption 1I DD1I DD1I DD2I DD2CPU in HALT stateBUPF="0"0.90.91.54.5306401015m A1Current Consumption 2 Current Consumption 2Ta=–40 to +40°CTa=+40 to +70°CTa=–40 to +40°CTa=+40 to +70°CTa=–40 to +40°CTa=+40 to +70°CTa=–40 to +40°CTa=+40 to +70°C1.533554050m Am Am Am Am Am Am A CPU in HALT stateBUPF="1"CPU in operation stateBUPF="0"CPU in operation stateBUPF="1"————————Parameter(V DD=0 V, V SS2=–3.0 V, Ta=–40 to +70°C unless otherwise specified.) Symbol Condition UnitMin.Typ.Max.•RC oscillationMeasuringCircuitCurrent Consumption 1 Current Consumption 1I DD1I DD1I DD2I DD2CPU in HALT stateBUPF="0"1.51.5364010501225m A1'Current Consumption 2 Current Consumption 2Ta=–40 to +40°CTa=+40 to +70°CTa=–40 to +40°CTa=+40 to +70°CTa=–40 to +40°CTa=+40 to +70°CTa=–40 to +40°CTa=+40 to +70°C344885060m Am Am Am Am Am Am A CPU in HALT stateBUPF="1"CPU in operation stateBUPF="0"CPU in operation stateBUPF="1"————————Parameter(V DD=0 V, V SS2=–3.0 V, R OS=1 M W, Ta=–40 to +70°C unless otherwise specified.) Symbol Condition UnitMin.Typ.Max.DC CharacteristicsOutput Current 1Output Current 3Output Current 2Output Leakage CurrentI OH1I OL1I OH3I OL32(P4.0 to P4.3)(MD0, MD0)(MD1, MD1)(P6.0 to P6.3)(P7.0 to P7.3)(SEG0 to SEG59)(COM1 to COM4)(P4.0 to P4.3)(P6.0 to P6.3)(P7.0 to P7.3)I OH2I OMH2I OMH2S I OML2I OML2S I OL2I OOH I OOL V OH1=–0.5 V V OL1=V SS2+0.5 V V OH3=–0.5 V V OL3=V SS2+0.5 V V OH2=–0.2 V V OMH2=V SS1+0.2 V V OMH2S =V SS1–0.2 V V OML2=V SS2+0.2 V V OML2S =V SS2–0.2 V V OL2=V SS3+0.2 V V OH =V DD V OL =V SS2(V SS2 level)(V SS3 level)(V SS1 level)(V SS2 level)(V DD level)(V SS1 level)–60.7–180.7444–0.3–1.81.8–61.6–0.76–26.0–4–4–40.3mA mA mA mA m A m A m A m A m A m A m A m A ————————————————Measuring CircuitParameter (Pin Name)(V DD =0 V, V SS1=V SSL =–1.5 V, V SS2=–3.0 V, V SS3=–4.5 V,Ta=–40 to +70°C unless otherwise specified.)Symbol Condition Unit Min.Typ.Max.Input Current 1Input Current 2Input Current 3Input Voltage 1I IH1I IH1Z I IH2I IL23(P2.0 to P2.3)(P3.0 to P3.1)(P6.0 to P6.3)(P7.0 to P7.3)(TST1, TST2, TST3)(RESET)(P2.0 to P2.3)(P3.0 to P3.1)(P6.0 to P6.3)(P7.0 to P7.3)(TST1, TST2, TST3)(RESET)I IH3I IL3V IH1V IL1V IH1=V DD (when pulled down)V IH1=V DD (at high impedance)V IH2=V DD V IL2=V SS2V IH3=V DD V IL3=V SS25000.75–1–1–3.01001.5803001302000m A m A mA m A m A mA VVI IL1V IL1=V SS2–10m A 440–0.60–2.4————————Measuring circuit 1Measuring circuit 1'C LCGm FC R OS, C L : 0.1 m F :1M WMeasuring circuit 2Measuring circuit 3V IH VILMeasuring circuit 4* 1Input logic is set to the designated state.* 2Measurement is repeated for the designated output pins.* 3Measurement is repeated for the designated input pins.V IHV IL(Unit : mm)PACKAGE DIMENSIONSNotes for Mounting the Surface Mount Type PackageThe SOP, QFP, TSOP, SOJ, QFJ (PLCC), SHP and BGA are surface mount type packages, which are very susceptible to heat in reflow mounting and humidity absorbed in storage.Therefore, before you perform reflow mounting, contact Oki’s responsible sales person for the product name, package name, pin number, package code and desired mounting conditions (reflow method, temperature and times).QFP100-P-1420-0.65-BKPackage material Lead frame material Pin treatmentSolder plate thickness Package weight (g)Epoxy resin 42 alloySolder plating 5 m m or more 1.29 TYP.Mirror finish。