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Integrated Circuits (ICs)

DM74LS75 Quad Latch: Logic Diagram, Ordering Code and Datasheet

CatalogProduct OverviewLogic DiagramConnection DiagramOrdering CodeAbsolute Maximum RatingRecommended Operating ConditionsDatasheetProduct AttributesManufacturerUsing WarningFAQProduct OverviewDM74LS75 latches are ideally suited for use as temporary storage for binary information between processing units and input/output or indicator units. Information present at a data (D) input is transferred to the Q output when the enable is HIGH, and the Q output will follow the data input as long as the enable remains HIGH. When the enable goes LOW, the information (that was present at the data input at the time the transition occurred) is retained at the Q output until the enable is permitted to go HIGH. These latches feature complementary Q and Q outputs from a 4-bit latch, and are available in 16-pin packages. Logic DiagramFigure:Logic DiagramConnection DiagramFigure:Connection DiagramOrdering CodeOrder NumberPackage NumberPackage DescriptionDM74LS75MM16A16-L ead Small Outline Integrated Circuit (SOIC), JEDEC MS-012, 0.150 NarrowDM74LS75N   N16E16-Lead Plastic Dual-In-Line Package (PDIP), JEDEC MS-001, 0.300 Wide Absolute Maximum RatingSupply Voltage 7VInput Voltage 7VOperating Free Air Temperature Range  0°C to +70°CStorage Temperature Range       −65°C to +150°C Recommended Operating ConditionsSymbolParameterMinNomMaxUnitsVCCSupply Voltage4.7555.25VVIHHIGH Level Input Voltage2  VVILLOW Level Input Voltage  0.8VIOHHIGH Level Output Current  -0.4mAIOLLOW Level Output Current  8mAtWEnable Pulse Width (Note 5)20  nstSUSetup Time (Note 5)20  nstHHold Time (Note 5)0  nsTAFree Air Operating Temperature0 70°C DatasheetDM74LS75-DatasheetProduct AttributesPhysicalCase/PackageDIPMountThrough HoleNumber of Pins16TechnicalHigh Level Output Current-400 µAIndependent Circuits1Logic FunctionD-Type, LatchMax Operating Temperature70 °CMax Supply Voltage5.25 VMin Operating Temperature0 °CMin Supply Voltage4.75 VNominal Supply Current12 mANumber of Circuits4Number of Input Lines4Number of Output Lines4PackagingBulkPolarityNon-InvertingPropagation Delay30 nsTurn-On Delay Time20 nsComplianceLead FreeContains LeadRoHSCompliantManufacturerFairchild Semiconductor International, Inc. was an American semiconductor company based in San Jose, California. Founded in 1957 as a division of Fairchild Camera and Instrument, it became a pioneer in the manufacturing of transistors and of integrated circuits. Schlumberger bought the firm in 1979 and sold it to National Semiconductor in 1987; Fairchild was spun off as an independent company again in 1997. In September 2016, Fairchild was acquired by ON Semiconductor. Using WarningNote: Please check their parameters and pin configuration before replacing them in your circuit. FAQWhat is a DM74LS75?Quad Latch. What is the package of DM74LS75?16-pin SOIC package. What are DM74LS75 latches ideal for?Temporary storage
kynix On 2022-04-12   1617
Integrated Circuits (ICs)

LT3751 Capacitor Charger Controller: Datasheet, Pinout, Applications [FAQ]

Product OverviewThe LT3751 is a high input voltage capable flyback controller designed to rapidly charge a large capacitor to a user-adjustable high target voltage set by the transformer turns ratio and three external resistors. Optionally, a feedback pin can be used to provide a low noise high voltage regulated output. This blog will introduce LT3751 systematically from its features, pinout to its specifications, applications, also including LT3751 datasheet and so much more. CatalogProduct OverviewLT3751 FeaturesLT3751 PinoutLT3751 ApplicationsLT3751 Block DiagramLT3751 Typical ApplicationsLT3751 SpecificationHow does LT3751 workLT3751 ManufacturerLT3751 DatasheetUsing WarningsLT3751 FAQ LT3751 FeaturesCharges Any Size CapacitorLow Noise Output in Voltage Regulation ModeStable Operation Under a No-Load ConditionIntegrated 2A MOSFET Gate Driver with Rail-to-RailOperation for VCC ≤ 8VSelectable 5.6V or 10.5V Internal Gate DriveVoltage ClampUser-Selectable Over/Undervoltage DetectEasily Adjustable Output VoltagePrimary or Secondary Side Output Voltage SenseWide Input VCC Voltage Range (5V to 24V)Available in 20-Pin QFN 4mm × 5mm and 20-LeadTSSOP Packages LT3751 PinoutThe following figure is the diagram of LT3751 pinout. LT3751 Pinout1 LT3751 Pinout2 LT3751 ApplicationsHigh Voltage Regulated SupplyHigh Voltage Capacitor ChargerProfessional Photoflash SystemsEmergency StrobeSecurity/Inventory Control SystemsDetonators LT3751 Block DiagramThe following figure shows the block diagram of LT3751. LT3751 Block Diagram LT3751 Typical ApplicationsThe following figures shows the typical applications of LT3751, which shows the compact solution dimensions. LT3751 Typical Applications Load Regulation and Efficiency LT3751 SpecificationBrand Name:Linear TechnologyLength:5 mmWidth:4 mmOperating Temperature-Max:125 °COperating Temperature-Min:-40 °CPeak Reflow Temperature (Cel):235Seated Height-Max:0.8 mmSupply Current-Max (Isup):8 mASupply Voltage-Max (Vsup):24 VSupply Voltage-Min (Vsup):4.75 VSupply Voltage-Nom (Vsup):5 VTime@Peak Reflow Temperature-Max (s):20 How does LT3751 workThe LT3751 has an integrated rail-to-rail MOSFET gate driver that allows for efficient operation down to 4.75V. A low 106mV differential current sense threshold voltage accurately limits the peak switch current. Added protection is provided via user-selectable overvoltage and undervoltage lockouts for both VCC and VTRANS. A typical application can charge a 1000µF capacitor to 500V in less than one second. The CHARGE pin is used to initiate a new charge cycle and provides ON/OFF control. The DONE pin indicates when the capacitor has reached its programmed value and the part has stopped charging. The FAULT pin indicates when the LT3751 has shut down due to either VCC or VTRANS voltage exceeding the user-programmed supply tolerances. LT3751 ManufacturerLinear Technology and Analog Devices have joined together. Analog Devices is a world leader in the design, manufacture, and marketing of a broad portfolio of high performance analog, mixed-signal, and digital signal processing (DSP) integrated circuits (ICs) used in virtually all types of electronic equipment. LT3751 DatasheetYou can download this datasheet for LT3751–Datasheet from the link given below:LT3751 Datasheet Using WarningsNote: Please check their parameters and pin configuration before replacing them in your circuit. LT3751 FAQIs the lt3751 a high voltage capacitor controller?The LT3751 is a high input voltage capable flyback controller designed to rapidly charge a large capacitor to a user-adjustable high target voltage set by the transformer turns ratio and three external resistors. Optionally, a feedback pin can be used to provide a low noise high voltage regulated output. What does the fault pin on the lt3751 mean?The FAULT pin indicates when the LT3751 has shut down due to either V CC or V TRANS voltage exceeding the user-programmed supply tolerances. At least one model within this product family is in production and available for purchase. What is a capacitor controller?The capacitor bank controller CQ is the complete solution for controlling and monitoring capacitors on distribution systems. CQ controller is available in two different models: CQ900 can automatically monitor and switch capacitor banks based on real time network conditions. What does a capacitor do to the voltage?When used in a direct current or DC circuit, a capacitor charges up to its supply voltage but blocks the flow of current through it because the dielectric of a capacitor is non-conductive and basically an insulator. How much time is required to discharge the capacitor?Note that as the decaying curve for a RC discharging circuit is exponential, for all practical purposes, after five time constants the voltage across the capacitor's plates is much less than 1% of its inital starting value, so the capacitor is considered to be fully discharged.
kynix On 2022-01-24   1610
Integrated Circuits (ICs)

LM324N Quad Operational Amplifier Datasheet PDF Download

CatalogDescriptionFeaturesInternal Block DiagramSchematic DiagramAbsolute Maximum RatingsThermal DataElectrical CharacteristicsTypical Performance CharacteristicsOrdering InformationLM324N DatasheetLM324N FAQ DescriptionThe LM324/LM324A, LM2902/LM2902A consist of four independent, high gain, internally frequency compensated operational amplifiers which were designed specifically to operate from a single power supply over a wide voltage range. operation from split power supplies is also possible so long as the difference between the two supplies is 3 volts to 32 volts. Application areas include transducer amplifier, DC gain blocks and all the conventional OP Amp circuits which now can be easily implemented in single power supply systems. FeaturesInternally Frequency Compensated for Unity GainLarge DC Voltage Gain: 100dBWide Power Supply Range: LM324/LM324A : 3V~32V (or±1.5 ~ 16V)                                              LM2902/LM2902A: 3V~26V (or ±1.5V ~ 13V)Input Common Mode Voltage Range Includes GroundLarge Output Voltage Swing: 0V to VCC-1.5VPower Drain Suitable for Battery Operation Internal Block Diagram Schematic Diagram Absolute Maximum RatingsParameterSymbolLM324/LM324ALM2902/LM2902AUnitPower Supply VoltageVCC±16 or 32±13 or 26VDifferential Input VoltageVI(DIFF)3226VInput VoltageVI-0.3 to +32-0.3 to +26VOutput Short Circuit to GND Vcc≤15V, TA=25°C(one Amp)-ContinuousContinuous-Power Dissipation, TA=25°C    14-DIPPD13101310mW14-SOP 640640 Operating Temperature RangeTOPR0 ~ +70-40 ~ +85°CStorage Temperature RangeTSTG-65 ~ +150-65 ~ +150°C Thermal DataParameterSymbolValueUnitThermal Resistance Junction-Ambient Max. 14-DIP14-SOP RΘja 95195 ° C/W Electrical Characteristics1.VCC = 5.0V, VEE = GND, TA = 25℃, unless otherwise specifiedParameter  Symbol  Conditions LM324LM2902 Unit Min.Typ.Max.Min.Typ.Max. Input Offset Voltage VIOVCM = 0V to VCC -1.5V VO(P) = 1.4V, RS = 0Ω(Note1) - 1.5 7.0 - 1.5 7.0 mVInput Offset CurrentIIOVCM = 0V-3.050-3.050nAInput Bias CurrentIBIASVCM = 0V-40250-40250nAInput Common-Mode Voltage RangeVI(R)Note10-VCC-1.50-VCC-1.5V Supply Current  ICC RL = ∞,VCC = 30V (LM2902,VCC=26V)-1.03-1.03mARL = ∞,VCC = 5V-0.71.2-0.71.2mALarge Signal Voltage GainGVVCC = 15V,RL=2kΩ VO(P) = 1V to 11V25100-25100-V/mV Output Voltage Swing  VO(H) Note1 RL = 2kΩ26--22--VRL=10kΩ2728-2324-VVO(L)VCC = 5V, RL=10kΩ-520-5100mVCommon-Mode Rejection RatioCMRR-6575-5075-dBPower Supply Rejection RatioPSRR-65100-50100-dBChannel SeparationCSf = 1kHz to 20kHz (Note2)-120--120-dBShort Circuit to GNDISCVCC = 15V-4060-4060mA   Output Current  ISOURCEVI(+) = 1V, VI(-) = 0V VCC = 15V, VO(P) = 2V2040-2040-mA  ISINK VI(+) = 0V, VI(-) = 1V VCC = 15V,VO(P) = 2V 10 13 - 10 13 - mAVI(+) = 0V, VI(-) = 1V VCC = 15V,VO(R) = 200mV 12 45 - - - - mADifferential Input VoltageVI(DIFF)---VCC--VCCVNote :1.VCC=30V for LM324 , VCC = 26V for LM29022.This parameter, although guaranteed, is not 100% tested in production. 2.VCC = 5.0V, VEE = GND, unless otherwise specifiedThe following specification apply over the range of 0℃ ≤ TA ≤ +70℃ for the LM324 ; and the -40℃ ≤ TA ≤ +85℃ for the LM2902Parameter Symbol Conditions LM324LM2902Unit Min.Typ.Max.Min.Typ.Max. Input Offset Voltage VIOVICM = 0V to VCC -1.5V VO(P) = 1.4V, RS = 0Ω(Note1) - - 9.0 - - 10.0 mVInput Offset Voltage DriftΔVIO/ΔTRS = 0Ω (Note2)-7.0--7.0-mV/°CInput Offset CurrentIIOVCM = 0V--150--200nAInput Offset Current DriftΔIIO/ΔTRS = 0Ω (Note2)-10--10-pA/°CInput Bias CurrentIBIASVCM = 0V--500--500nAInput Common-Mode Voltage RangeVI(R)Note10-VCC-2.00-VCC-2.0VLarge Signal Voltage GainGVVCC = 15V, RL = 2.0kΩ VO(P) = 1V to 11V15--15--V/mV Output Voltage Swing  VO(H) Note1 RL=2kΩ26--22--VRL=10kΩ2728-2324-VVO(L)VCC = 5V, RL=10kΩ-520-5100mV Output Current ISOURCEVI(+) = 1V, VI(-) = 0V VCC = 15V, VO(P) = 2V1020-1020-mAISINKVI(+) = 0V, VI(-) = 1V VCC = 15V, VO(P) = 2V58-58-mADifferential Input VoltageVI(DIFF)---VCC--VCCVNote:1.VCC=30V for LM324 , VCC = 26V for LM29022.These parameters, although guaranteed, are not 100% tested in production. 3. VCC = 5.0V, VEE = GND, TA = 25℃, unless otherwise specifiedParameter Symbol Conditions LM324ALM2902AUnit Min.Typ.Max.Min.Typ.Max. Input Offset Voltage VIOVCM = 0V to VCC =1.5V VO(P) = 1.4V, RS = 0Ω(Note1) - 1.5 3.0 - 1.5 2.0 mVInput Offset CurrentIIOVCM = 0V-3.030-3.050nAInput Bias CurrentIBIASVCM = 0V-40100-40250nAInput Common-Mode Voltage Range VI(R) VCC = 30V 0 -VCC-1.5 0 -VCC-1.5 V Supply Current  ICC VCC = 30V, RL = ∞(LM2902,VCC=26V)-1.53-1.03mAVCC = 5V, RL = ∞-0.71.2-0.71.2mALarge Signal Voltage GainGVVCC = 15V, RL= 2kΩ VO(P) = 1V to 11V25100-25100-V/mV Output Voltage Swing  VO(H) Note1 RL = 2kΩ26--22--VRL = 10kΩ2728-2324-VVO(L)VCC = 5V, RL=10kΩ-520-5100mVCommon-Mode Rejection RatioCMRR-6585-5075-dBPower Supply Rejection RatioPSRR-65100-50100-dBChannel SeparationCSf = 1kHz to 20kHz (Note2)-120--120-dBShort Circuit to GNDISCVCC = 15V-4060-4060mA   Output Current  ISOURCEVI(+) = 1V, VI(-) = 0V VCC =15V, VO(P) = 2V2040-2040-mA  ISINK VI(+) = 0V, VI(-) = 1V VCC = 15V, VO(P) = 2V1020-1013-mAVI(+) = 0V, VI(-) = 1V VCC = 15V, VO(P) = 200mV 12 50 - - - - mADifferential Input VoltageVI(DIFF)---VCC--VCCVNote:1.VCC=30V for LM324A ; VCC=26V for LM2902A2.This parameter, although guaranteed, is not 100% tested in production. 4. VCC = 5.0V, VEE = GND, unless otherwise specifiedThe following specification apply over the range of 0℃ ≤TA ≤ +70℃ for the LM324A ; and the -40℃ ≤ TA ≤ +85℃ for the LM2902AParameter Symbol Conditions LM324ALM2902AUnit Min.Typ.Max.Min.Typ.Max. Input Offset Voltage VIOVCM = 0V to VCC -1.5V VO(P) = 1.4V, RS = 0Ω(Note1) - - 5.0 - - 6.0 mVInput Offset Voltage DriftΔVIO/ΔTRS = 0Ω (Note2)-7.030-7.0-mV/°CInput Offset CurrentIIOVCM = 0V--75--200nAInput Offset Current DriftΔIIO/ΔTRS = 0Ω (Note2)-10300-10-pA/°CInput Bias CurrentIBIAS--40200--500nA Input Common-Mode Voltage Range VI(R) Note1 0 - VCC-2.0 0 - VCC-2.0 VLarge Signal Voltage GainGVVCC = 15V, RL= 2.0kΩ15--15--V/mV Output Voltage Swing  VO(H) Note1 RL = 2kΩ26--22--VRL = 10kΩ2728-2324-VVO(L)VCC = 5V, RL= 10kΩ-520-5100mV Output Current ISOURCEVI(+) = 1V, VI(-) = 0V VCC = 15V, VO(P) = 2V1020-1020-mAISINKVI(+) = 0V, VI(-) = 1V VCC = 15V, VO(P) = 2V58-58-mADifferential Input VoltageVI(DIFF)---VCC--VCCVNote:1.VCC=30V for LM324A ; VCC=26V for LM2902A.2.These parameters, although guaranteed, are not 100% tested in production. Typical Performance Characteristics           Ordering InformationProduct NumberPackageOperating TemperatureLM324N14-DIP  0 ~ +70°C   LM324ANLM324M14-SOP LM324AMLM2902N14-DIP -40 ~ +85°C LM2902M14-SOP LM2902AM LM324N DatasheetYou can download the datasheet of LM324N from the link given below:LM324N Datasheet LM324N FAQWhat is Lm324n used for?Lm324n is widely used in transducer amplifiers. DC gain blocks and conventional amplifiers circuits are mainly consists of Lm324n. It can be used as a rectifier, oscillator and comparator. What is a quad operational amplifier?They have several distinct advantages over standard operational amplifier types in single supply applications. The quad amplifier can operate at supply voltages as low as 3.0 V or as high as 32 V with quiescent currents about one−fifth of those associated with the MC1741 (on a per amplifier basis). How does a op-amp work?An operational amplifier is an integrated circuit that can amplify weak electric signals. An operational amplifier has two input pins and one output pin. Its basic role is to amplify and output the voltage difference between the two input pins. Why negative power supply is used in operational amplifiers?Opamps don't produce voltage or current. They let more or less current pass from the powersupply to the output. To get a negative voltage out of an opamp, you have give it a powersupply with a negative voltage. The output of an opamp is limited to what is available from the supply rails. What is operational amplifier and its types?Op amps can be classified into 3 main types based on the input/output voltage range: Dual Supply, Single Supply, and Rail-to-Rail. The input/output voltage range of each type of op amp is shown below. 
kynix On 2022-02-11   1606
Integrated Circuits (ICs)

SN74HC00N NAND Gate IC: Datasheet, Pinout and Specifications [Video&FAQ]

The SN74HC00N is a four independent 2-input NAND Gate IC. Catalog Product OverviewCAD MODELSN74HC00N PinoutSN74HC00N Product InformationSN74HC00N  PrinceSN74HC00N  FeaturesApplicationsPower ConsiderationsInput ConsiderationsOutput ConsiderationsUsing WarningFrequently Asked QuestionsProduct OverviewThe SN74HC00N is a four independent 2-input NAND Gate IC. It performs the Boolean function Y = (A • B)\ or Y = A\ + B\ in positive logic.Outputs Can Drive up to 10 LSTTL LoadsLow-power Consumption, 20µA Maximum ICC8ns Typical Propagation Delay Time CAD MODELPart Symbol Footprint 3D Model SN74HC00N PinoutSN74HC00N Pinout Component DatasheetSN74HC00N Datasheet SN74HC00N Product InformationSource Content uid:SN74HC00NManufacturer Part Number:SN74HC00NPart Life Cycle Code:ActivePart Package Code:DIPPackage Description:DIP, DIP14,.3Pin Count:14Reach Compliance Code:compliantECCN Code:EAR99HTS Code:8542.39.00.01Factory Lead Time:1 WeekRisk Rank:0.88Samacsys Description:Quad 2i/p NANDgate,SN74HC00N DIP14 25pcsFamily:HCJESD-30 Code:R-PDIP-T14JESD-609 Code:e3Length:19.305 mmLoad Capacitance (CL):50 pFLogic IC Type:NAND GATEMax I(ol):0.0052 ANumber of Functions:4Number of Inputs:2Number of Terminals:14Operating Temperature-Max:85 °COperating Temperature-Min:-40 °CPackage Body Material:PLASTIC/EPOXYPackage Code:DIPPackage Equivalence Code:DIP14,.3Package Shape:RECTANGULARPackage Style:IN-LINEPacking Method:TUBEPeak Reflow Temperature (Cel):NOT SPECIFIEDPower Supplies:2/6 VPower Supply Current-Max (ICC):0.02 mAProp. Delay@Nom-Sup:23 nsPropagation Delay (tpd):115 ns SN74HC00N PrinceSuppliersFromIn stockDelivery(Day)MOQCurrency1+10+100+1K+10K+Digi-Key 2USA0Immediate1USD $0.490.4170.3120.1890.184element14 2China0Immediate1USD $0.4160.3590.2690.1630.139Verical 8USA020USD $-0.3550.2580.2130.213JLCShopChina5478Immediate1USD $0.2340.1810.1620.1550.155ICBaseChina0-1USD $0.1920.1640.140.1210.121 SN74HC00N FeaturesBuffered inputsWide operating voltage range: 2 V to 6 VWide operating temperature range: –40°C to +85°CSupports fanout up to 10 LSTTL loads • Significant power reduction compared to LSTTL logic ICs ApplicationsAlarm / tamper detect circuitS-R latch Power ConsiderationsPower Considerations Ensure the desired supply voltage is within the range specified in the Recommended Operating Conditions. The supply voltage sets the device's electrical characteristics as described in the Electrical Characteristics. The positive voltage supply must be capable of sourcing current equal to the total current to be sourced by all outputs of the SN74HC00 plus the maximum static supply current, ICC, listed in Electrical Characteristics and any transient current required for switching. The logic device can only source as much current as is provided by the positive supply source. Be sure not to exceed the maximum total current through VCC listed in the Absolute Maximum Ratings.  The ground must be capable of sinking current equal to the total current to be sunk by all outputs of the SN74HC00 plus the maximum supply current, ICC, listed in Electrical Characteristics, and any transient current required for switching. The logic device can only sink as much current as can be sunk into its ground connection. Be sure not to exceed the maximum total current through GND listed in the Absolute Maximum Ratings. The SN74HC00 can drive a load with a total capacitance less than or equal to 50 pF while still meeting all of the datasheet specifications.  Larger capacitive loads can be applied, however it is not recommended to exceed 50 pF. The SN74HC00 can drive a load with total resistance described by RL ≥ VO / IO, with the output voltage and current defined in the Electrical Characteristics table with VOH and VOL. When outputting in the high state, the output voltage in the equation is defined as the difference between the measured output voltage and the supply voltage at the VCC pin. Total power consumption can be calculated using the information provided in CMOS Power Consumption and Cpd Calculation. Thermal increase can be calculated using the information provided in Thermal Characteristics of Standard Linear and Logic (SLL) Packages and Devices. Input ConsiderationsInput signals must cross VIL(max) to be considered a logic LOW, and VIH(min) to be considered a logic HIGH. Do not exceed the maximum input voltage range found in the Absolute Maximum Ratings. Unused inputs must be terminated to either VCC or ground. These can be directly terminated if the input is completely unused, or they can be connected with a pull-up or pull-down resistor if the input is to be used sometimes, but not always. A pull-up resistor is used for a default state of HIGH, and a pull-down resistor is used for a default state of LOW.  The resistor size is limited by drive current of the controller, leakage current into the SN74HC00, as specified in the Electrical Characteristics, and the desired input transition rate. A 10-kΩ resistor value is often used due to these factors. The SN74HC00 has CMOS inputs and thus requires fast input transitions to operate correctly, as defined in the Recommended Operating Conditions table. Slow input transitions can cause oscillations, additional power consumption, and reduction in device reliability. Refer to the Feature Description section for additional information regarding the inputs for this device. Output ConsiderationsThe positive supply voltage is used to produce the output HIGH voltage. Drawing current from the output will decrease the output voltage as specified by the VOH specification in the Electrical Characteristics. The ground voltage is used to produce the output LOW voltage. Sinking current into the output will increase the output voltage as specified by the VOL specification in the Electrical Characteristics. Push-pull outputs that could be in opposite states, even for a very short time period, should never be connected directly together.  This can cause excessive current and damage to the device. Two channels within the same device with the same input signals can be connected in parallel for additional output drive strength. Unused outputs can be left floating. Do not connect outputs directly to VCC or ground. Refer to Feature Description section for additional information regarding the outputs for this device. Using WarningPlease check their parameters and pin configuration before replacing them in your circuit. Frequently Asked QuestionsWhich NAND circuits are contained in a 7400 NAND IC?For a NAND gate two inputs are required and one output is obtained means for NAND gate 3 pin connections are required. Thus, a 7400IC contains 4 NAND gates with each having 3 pins. What is the IC of NAND gate?The standard, 4000 series, CMOS IC is the 4011, which includes four independent, two-input, NAND gates. Does NAND gate have 4 inputs?It can take in four logic inputs and provide an output based on the truth table. NAND gate is commonly used in buffer circuits and logic inverter circuits for digital communication. 
kynix On 2022-04-14   1579
Integrated Circuits (ICs)

BR2335 Lithium Battery: Datasheet, Applications, Features [FAQ]

 CatalogDescriptionConstructionTab and Pin DetailProtective Battery CircuitsFeaturesApplicationsDatasheetSpecificationsUsing WarningFAQ DescriptionLithium has become a generic term representing a family of battery systems in which Lithium metal is used as the active anode material or negative electrode. Variations in the cathode material, or positive electrode, and the cell electrolyte result in hundreds of possible combinations of Lithium batteries. Rayovac Lithium Carbon-monofluoride (BR) batteries are a solid-cathode type which optimizes reliability, safety, cost and performance. ConstructionFigure: BR2335 Construction Tab and Pin DetailFigure: Tab and Pin Detail Protective Battery CircuitsFigure: Protective Battery Circuits FeaturesOutstanding shelf life and excellent performance over a wide temperature rangeStable discharge voltageHigh energy density and voltage (3V)Enhanced safety by the use of Carbon-monofluoride electrode material and a non-corrosive, non-toxic electrolyteExcellent leak resistanceShelf life of ten years or morePre-tinned terminals are solderableAvailable with many wave-solderable terminal configurations ApplicationsThe following devices are examples of good uses for BR coin cells:Computer Memory and Real Time Clock BackupElectronic Counters, Process ControllersPortable InstrumentsTime/Data ProtectionIndustrial ControlsElectronic Gas, Water and Electric MetersCommunication EquipmentTire Pressure Monitoring Systems (TPMS)RF Tags, Toll Tags, and ID TagsPortable Electronic Devices DatasheetYou can download the datasheet the link given below.BR2335-Datasheet SpecificationsPhysicalCase/Package300TechnicalChemistry/TechnologyLithiumTerminationSMD/SMTDimensionsHeight3.5 mmOutside Diameter23 mmComplianceREACH SVHCUnknownRoHSNon-Compliant Using WarningNote: Please check their parameters and pin configuration before replacing them in your circuit. FAQWhat is a lithium battery used for?Lithium-ion (Li-ion) batteries are used in many products such as electronics, toys, wireless headphones, handheld power tools, small and large appliances, electric vehicles and electrical energy storage systems. What is the difference between a lithium battery and a lithium-ion battery?Lithium batteries feature primary cell construction. This means that they are single-use—or non-rechargeable. Ion batteries, on the other hand, feature secondary cell construction. This means that they can be recharged and used over and over again. How long do lithium batteries last?The typical estimated life of a Lithium-Ion battery is about two to three years or 300 to 500 charge cycles, whichever occurs first. One charge cycle is a period of use from fully charged, to fully discharged, and fully recharged again. Which battery type is best?Lithium batteries have the highest capacity and last the longest. Alkaline non-rechargeable batteries come second, having a long shelf life, low self-discharge and are inexpensive. Which is better lithium-ion or lithium phosphate?Lithium-ion has a higher energy density at 150/200 Wh/kg versus lithium iron phosphate at 90/120 Wh/kg. So, lithium-ion is normally the go-to source for power hungry electronics that drain batteries at a high rate. On the other hand, the discharge rate for lithium iron phosphate outmatches lithium-ion. 
Kynix On 2022-05-05   1569
Integrated Circuits (ICs)

MAX30102EFD+T Sensor: Datasheet, Applications and Features

 CatalogDescriptionCAD ModelsPin ConfigurationBlock DiagramBenefits and FeaturesApplicationsDatasheetProduct AttributesManufacturerUsing WarningDescriptionThe MAX30102 is an integrated pulse oximetry and heart-rate monitor module. It includes internal LEDs, photodetectors, optical elements, and low-noise electronics with ambient light rejection. The MAX30102 provides a complete system solution to ease the design-in process for mobile and wearable devices. The MAX30102 operates on a single 1.8V power supply and a separate 5.0V power supply for the internal LEDs. Communication is through a standard I2C-compatible interface. The module can be shut down through software with zero standby current, allowing the power rails to remain powered at all times.CAD Models Figure:  PCB Symbol  Figure:  Footprint  Figure:  3D Model Pin Configuration Figure:  Pin Configuration Block Diagram Figure:  Block Diagram Benefits and FeaturesHeart-Rate Monitor and Pulse Oximeter Sensor in LED Reflective SolutionTiny 5.6mm x 3.3mm x 1.55mm 14-Pin Optical ModuleIntegrated Cover Glass for Optimal, Robust PerformanceUltra-Low Power Operation for Mobile DevicesProgrammable Sample Rate and LED Current for Power SavingsLow-Power Heart-Rate Monitor (< 1mW)Ultra-Low Shutdown Current (0.7µA, typ)Fast Data Output CapabilityHigh Sample RatesRobust Motion Artifact ResilienceHigh SNR-40°C to +85°C Operating Temperature Range ApplicationsWearable DevicesFitness Assistant Devices DatasheetMAX30102EFD+T-Datasheet Product AttributesManufacturer:Maxim IntegratedProduct Category:Biometric SensorsProduct:SensorsOperating Supply Current:600 uAMounting Style:SMD/SMTMaximum Operating Temperature:+ 85 ℃Minimum Operating Temperature:- 40 ℃Operating Supply Voltage:1.8 VPackage / Case:OLG-14Packaging:Cut TapePackaging:MouseReelPackaging:ReelSeries:MAX30102Brand:Maxim IntegratedMoisture Sensitive:YesProduct Type:Biomedical SensorsFactory Pack Quantity:5000Subcategory:SensorsSupply Voltage - Max:2 VSupply Voltage - Min:1.7 VUnit Weight:0.114446 oz ManufacturerMaxim Integrated, a subsidiary of Analog Devices, designs, manufactures, and sells analog and mixed-signal integrated circuits for the automotive, industrial, communications, consumer, and computing markets. Maxim's product portfolio includes power and battery management ICs, sensors, analog ICs, interface ICs, communications solutions, digital ICs, embedded security, and microcontrollers. The company is headquartered in San Jose, California, and has design centers, manufacturing facilities, and sales offices worldwide. Using WarningNote: Please check their parameters and pin configuration before replacing them in your circuit. 
kynix On 2022-01-24   1566

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