The Kynix Components

CatalogMMBFJ113 FeaturesMMBFJ113 Ordering InformationMMBFJ113 Absolute Maximum RatingsMMBFJ113 Thermal CharacteristicsMMBFJ113 Electrical CharacteristicsMMBFJ113 Typical Performance CharacteristicsMMBFJ113 Physical DimensionsMMBFJ113 ManufacturerMMBFJ113 DatasheetUsing WarningMMBFJ113 FAQ MMBFJ113 FeaturesThis device is designed for low level analog switching,sample and hold circuits and chopper stabilized amplifiers.Sourced from process 51Source & Drain are interchangeable. MMBFJ113 Ordering InformationPart NumberTop MarkPackagePacking MethodMMBFJ1136SSOT-23 3LTape and Reel MMBFJ113 Absolute Maximum RatingsStresses exceeding the absolute maximum ratings may damage the device. The device may not function or be opera- ble above the recommended operating conditions and stressing the parts to these levels is not recommended. In addition, extended exposure to stresses above the recommended operating conditions may affect device reliability. The absolute maximum ratings are stress ratings only. Values are at TA = 25°C unless otherwise noted.SymbolParameterValueUnitVDGDrain-Gate Voltage35VVGSGate-Source Voltage-35VIGFForward Gate Current50mATJ, TSTGOperating and Storage Junction Temperature Range-55 to 150℃ Notes:1.These ratings are based on a maximum junction temperature of 150℃.2.These are steady-state limits. ON Semiconductor should be consulted on applications involving pulsed or low- duty-cycle operations. MMBFJ113 Thermal CharacteristicsValues are at TA = 25°C unless otherwise noted.SymbolParameterMaxUnitPDTotal Device Dissipation350mWDerate Above 25℃2.8mW/℃RΘJCThermal Resistance, Junction-to-Case ℃/WRΘJAThermal Resistance, Junction-to-Ambient357℃/W Notes:3.PCB size: FR-4, 76 mm x 114 mm x 1.57 mm (3.0 inch x 4.5 inch x 0.062 inch) with minimum land pattern size.4.Device mounted on FR-4 PCB 36m x 18mm x 1.5mm; mounting pad for the collector lead minimum 6cm2. MMBFJ113 Electrical CharacteristicsValues are at TA = 25℃ unless otherwise noted.SymbolParameterConditionsMin.Max.UnitOff CharacteristicsV(BR)GSSGate-Source Breakdown VoltageIG = -1.0 μA, VDS = 0-35 VIGSSGate Reverse CurrentVGS = -15 V, VDS = 0 -1nAVGS(off)Gate-Source Cut-Off VoltageVDS = 15 V, ID = 1.0 μA-0.5-3VID(off)Drain Cutoff Leakage CurrentVDS = 5.0 V, VGS = -10 V 1nAOn CharacteristicsIDSSZero-Gate Voltage Drain CurrentVDS = 15 V, VGS = 02 mArDS(on)Drain-Source On ResistanceVDS ≤ 0.1 V, VGS = 0 100 Small Signal CharacteristicsCdg(on) Csg(on)Drain-Gate &Source-Gate On CapacitanceVDS = 0, VGS = 0, f = 1.0 MHz 28pFCdg(off)Drain-Gate Off CapacitanceVDS = 0, VGS = -10 V, f = 1.0 MHz 5pFCsg(off)Source-Gate Off CapacitanceVDS = 0, VGS = -10 V, f = 1.0 MHz 5pFNote:5.Pulse test: pulse width ≤300μs, duty cycle ≤ 2%. MMBFJ113 Typical Performance CharacteristicsFigure: Common Drain-Source Figure: Parameter Interactions Figure: Transfer Characteristics Figure: On Resistance vs. Drain Current Figure: Normalized Drain Resistance vs. Bias Voltage Figure: Transconductance vs. Drain Current Figure: Output Conductance vs. Drain Current Figure: Capacitance vs. Voltage Figure: Noise Voltage vs. Frequency Figure: Noise Voltage vs. Current Figure: Power Dissipation vs. Ambient Temperature Figure: Switching Turn-On Time vs.Gate-Source Voltage Figure: Switching Turn-Off Time vs. Drain Current MMBFJ113 Physical DimensionsFigure: 3-Lead, TO-92, JEDEC TO-92 Compliant Straight Lead Configuration, Bulk Type MMBFJ113 ManufacturerOnsemi is driving energy efficient innovations, empowering customers to reduce global energy use. The company offers a comprehensive portfolio of energy efficient power and signal management, logic, discrete and custom solutions to help design engineers solve their unique design challenges in automotive, communications, computing, consumer, industrial, LED lighting, medical, military/aerospace and power supply applications. onsemi operates a responsive, reliable, world-class supply chain and quality program, and a network of manufacturing facilities, sales offices and design centers in key markets throughout North America, Europe, and the Asia Pacific regions. MMBFJ113 DatasheetYou can download the datasheet from the link given below:MMBFJ113 Datasheet Using WarningNote: Please check their parameters and pin configuration before replacing them in your circuit. MMBFJ113 FAQWhat is JFET N channel?The JFET is a long channel of semiconductor material, doped to contain an abundance of positive charge carriers or holes (p-type), or of negative carriers or electrons (n-type). Ohmic contacts at each end form the source (S) and the drain (D). What is JFET switch?As a reverse-biased PN junction, it firmly opposes the flow of current through it. As a voltage-controlled device, the JFET requires negligible input current. This is an advantageous trait of the JFET over the bipolar transistor: there is virtually zero power required of the controlling signal. What is JFET used for?The JFET transistors are used as electronically controlled switches, Voltage controlled resistors and as amplifiers. BJT transistors are constructed with the PN-junctions but the JFET transistors have a channel instead of the PN-junctions. 

Catalog LT3580 Description LT3580 Related Video Instruction LT3580 CAD Models LT3580 Pin Configuration LT3580 Block Diagram LT3580 Features LT3580 Applications LT3580 Datasheet LT3580 Specifications LT3580 Manufacturer Using Warning LT3580 FAQ LT3580 Description The LT3580 is a PWM DC/DC converter containing an internal 2A, 42V switch. The LT3580 can be configured as either a boost, SEPIC or inverting converter. Capable of generating 12V at 550mA or -12V at 350mA from a 5V input, the LT3580 is ideal for many local power supply designs.   The LT3580 has an adjustable oscillator, set by a resistor from the RT pin to ground. Additionally, the LT3580 can be synchronized to an external clock. The free running or synchronized switching frequency range of the part can be set between 200kHz and 2.5MHz. The LT3580 also features innovative SHDN pin circuitry that allows for slowly varying input signals and an adjustable undervoltage lockout function.Additional features such as frequency foldback and soft-start are integrated. The LT3580 is available in tiny 3mm×3mm 8-lead DFN and 8-lead MSOP packages.   LT3580 Related Video Instruction Video: Digital to Analog Converter using PWM LT3580 Video Description:  This a short explanation how a PWM DAC works. It is a kind of technical background knowledge you might be interested in for some upcoming sound synthesis projects. It also shows a simple low pass filter.   LT3580 CAD Models   Figure: PCB Symbol     Figure: Footprint     Figure: 3D Model   LT3580 Pin Configuration   Figure: Pin Configuration   LT3580 Block Diagram   Figure: Block Diagram   LT3580 Features 2A Internal Power SwitchAdjustable Switching FrequencySingle Feedback Resistor Sets VOUTSynchronizable to External ClockHigh Gain SHDN Pin Accepts Slowly Varying Input SignalsWide Input Voltage Range: 2.5V to 32VLow VCESAT Switch: 300mV at 1.5A (Typical)Integrated Soft-Start FunctionEasily Configurable as a Boost or Inverting ConverterUser Configurable Undervoltage Lockout (UVLO)Tiny 8-Lead 3mm×3mm DFN and 8-Lead MSOP Packages   LT3580 Applications VFD Bias SuppliesTFT-LCD Bias SuppliesGPS ReceiversDSL ModemsLocal Power Supply   LT3580 Datasheet You can download the datasheet from the link given below. LT3580-Datasheet   LT3580 Specifications Product Category:Switching Voltage RegulatorsMounting Style:SMD/SMTPackage / Case:MSOP-E-8Topology:Boost, InvertingOutput Voltage:42 VOutput Current:2 ANumber of Outputs:1 OutputInput Voltage MAX:32 VInput Voltage MIN:2.5 VQuiescent Current:1 mASwitching Frequency:200 kHz to 2.5 MHzMinimum Operating Temperature:- 40 ℃Maximum Operating Temperature:+ 125 ℃Series:LT3580Packaging:ReelPackaging:Cut TapePackaging:MouseReelManufacturer:Analog Devices Inc.Brand:Analog DevicesInput Voltage:2.5 V to 32 VOperating Supply Current:1 mAProduct Type:Switching Voltage RegulatorsShutdown:ShutdownFactory Pack Quantity:2500Subcategory:PMIC - Power Management ICsType:Boost/Inverting DC/DC ConverterUnit Weight:0.005218 oz   LT3580 Manufacturer Analog Devices, Inc. (ADI), also known simply as Analog, is an American multinational semiconductor company specializing in data conversion, signal processing and power management technology, headquartered in Wilmington, Massachusetts.   Using Warning Note: Please check their parameters and pin configuration before replacing them in your circuit.   LT3580 FAQ What is a PWM converter? PWM converters are used to power and control the speed of asynchronous motors. Pulse width modulation (PWM) uses a rectifier to create DC voltage in the same way as a synchro-converter. On the inverter side it uses forced commutation to give a series of pulses of common voltage both positive and negative.   What is PWM used for? PWM is used in many applications, ranging from communications to power control and conversion. For example, the PWM is commonly used to control the speed of electric motors, the brightness of lights, in ultrasonic cleaning applications, and many more.   Is PWM digital or analog? In a nutshell, PWM is a way of digitally encoding analog signal levels. The PWM signal is still digital because, at any given instant of time, the full DC supply is either fully on or fully off. The voltage or current source is supplied to the analog load by means of a repeating series of on and off pulses.  

Product Overview The LM78XX series, LM7812 of three terminal positive regulators are available in the TO-220 package and with several fixed output voltages, making them useful in a wide range of applications. Each type employs internal current limiting, thermal shut down and safe operating area protection, making it essentially indestructible. If adequate heat sinking is provided, they can deliver over 1A output current. Although designed primarily as fixed voltage regulators, these devices can be used with external components to obtain adjustable voltages and currents.   This blog will introduce LM7812 systematically from its features, pinout to its specifications, applications, also including LM7812 datasheet and so much more.   Catalog Product Overview Related Video Introduction LM7812 Features LM7812 Pinout LM7812 Pin Configuration LM7812 Applications LM7812 Equivalents LM7812 Circuit Diagram LM7812 Block Diagram LM7812 Package LM7812 Specification LM7812 Manufacturer LM7812 Datasheet Using Warnings LM7812 FAQ   Related Video Introduction   Video: How to Make 12V Regulator Using LM7812 IC | Simple Ideas | Javier's DIY   LM7812 Video Description: The ic 7812 is a positive voltage regulator which means that it generates the positive voltage with respect to the common ground. In case if both the positive and negative voltage supply is needed in the same circuit. The voltage regulator ic 7812 is combined with its corresponding 79XX family IC that is 7912 IC. The IC can handle maximum load of 1A to 1.5A but the input current should be 2A to get 1A to 1.5A at the output.   Component's Needed: ° LM7812 IC ° 25V 1000uf capacitor ° 16V 1500uf capacitor ° Heatsink ° insulated wires ° soldering ° 23V powersupply input   LM7812 Features TO-220 PackageThe Output current is 1.5 AmpereImmediate short circuit shutdown functionImmediate over heat shutdown functionLow priceAuthentic to use in commercial devicesAccurate and fixed 12V outputMaximum input voltage is 35V DCLow standby current only 8mA   LM7812 Pinout The following figure is the diagram of LM7812 pinout.   LM7812 Pinout   LM7812 Pin Configuration Pin NumberPin TypePin Description1INPositive Input Voltage2GNDGround3OUTPositive Output Voltage   LM7812 Applications Remote control carsToysPhone chargersPower distribution circuitsCurrent Limiter for certain applicationsRegulated Dual Supply   LM7812 Equivalents LM340-12, LM340A-12 and LM1084-12 can be used as equivalent of LM7812, if these equivalent voltage regulators are not available you can also use an LM317 IC to get fixed 12V output.   LM7812 Circuit Diagram The circuit shown below is a typical application circuit of the 7812 IC. The circuit includes a power source, two capacitors, and the voltage regulator IC.   LM7812 Circuit Diagram   As we can observe through the voltage probe, when an input voltage of ~25V is provided through the 7812 IC, the output voltage we obtain is 12V DC. The image below represents all the internal circuit components of the regulator IC.   LM7812 Circuit Diagram   The application circuit shown above also consists of two ceramic capacitors. Ceramic capacitor C1(0.33uF) is used to deal with the problems of input impedance, whereas the capacitor C2(0.1uF) is used to provide a stable output voltage. Ceramic capacitors are used here because they are faster than the electrolytic capacitors.   LM7812 Block Diagram The following figure shows the block diagram of LM7812.   LM7812 Block Diagram LM7812 Package The following diagram shows the LM7812 package.   LM7812 Package   LM7812 Specification  CONDITIONSMINMAXUNITOutput VoltageVin=19V; IO=500mA11.7512.25VLine Regulation14.8V≤Vin≤30V; IO=500mA 120mVLoad Regulation5.0mA≤IO≤1.0A;Vin=19V 100mVQuiescent CurrentVin=19V; IO=1A 6mAQuiescent Current Change5.0mA≤IO≤1.0A;Vin=19V 0.5mAQuiescent Current Change15V≤Vin≤30V; IO=500mA 0.8mA   LM7812 Manufacturer ON Semiconductor is a Fortune 500 company driving energy efficient innovations, empowering customers to reduce global energy use. The company is a leading supplier of semiconductor-based solutions, offering a comprehensive portfolio of energy efficient power and signal management, logic, standard and custom devices. The company’s products help engineers solve their unique design challenges in automotive, communications, computing, consumer, industrial, medical and military/aerospace applications.   LM7812 Datasheet You can download LM7812 datasheet from the link given below: LM7812 Datasheet   Using Warnings Note: Please check their parameters and pin configuration before replacing them in your circuit.   LM7812 FAQ What is the regulated output voltage of LM7812? LM7812 IC comes in the family and provides a fixed regulated output of 12V DC for a variable input voltage range of 14.5 to 27V DC.   What is the purpose of LM7812? LM7812 ICs are widely used in the larger rating motor and electrical power supply industry. They are used as an independent voltage regulator of high supply voltage of electric motors. In addition, they are used in the AC motor controllers. LM7812 ICs are used in electronic security and fire alarms.   What is the maximum input voltage of LM7812? The 7812 is a fixed voltage linear regulator that can output 12V at up to 1A current with an input voltage range of 14 – 35V.   How does a 7812 voltage regulator work? The ic 7812 is a positive voltage regulator which means that it generates the positive voltage with respect to the common ground. In case if both the positive and negative voltage supply is needed in the same circuit. The voltage regulator ic 7812 is combined with its corresponding 79XX family IC that is 7912 IC.   What is voltage regulator IC? A voltage regulator is an integrated circuit (IC) that provides a constant fixed output voltage regardless of a change in the load or input voltage. It can do this many ways depending on the topology of the circuit within, but for the purpose of keeping this project basic, we will mainly focus on the linear regulator.

Catalog Product Overview MC34716EP Related Video Introduction MC34716EP Pin Connections MC34716EP Internal Block Diagram MC34716EP Features MC34716EP Application Diagram MC34716EP Functional description MC34716EP Datasheet MC34716EP Specifications MC34716EP Manufacturer Using Warning MC34716EP FAQ   Product Overview The 34716 is a highly integrated, space-efficient, low cost, dual synchronous buck switching regulator with integrated N-channel power MOSFETs  . It is a high performance point-of-load (PoL) power supply  with its second output having the ability to track an external reference voltage  . It provides a full power supply solution for Double-Data-Rate (DDR) Memories.   Channel one provides a source only, 5.0 A drive capability  , while channel two can sink and source up to 3.0 A. With its high current drive capability.  channel one can be used to supply the VDDQ to the memory chipset. The second channel’s ability to track a reference voltage  provides an ideal means of supporting the termination voltage  (VTT) required by modern data buses  such as Double-Data-Rate (DDR) memory buses, including, but not limited to DDR, DDR2, DDR3 and Low power DDR3/DDR4 memories. Both channels are highly efficient with tight output regulation. The 34716 also provides a buffered output reference voltage  (VREFOUT) to the memory chipset.     The 34716 SMARTMOS device offers a variety of control, supervisory and protection functions that simplify the implementation of complex designs. It is housed in a Pb-free, thermally enhanced and space efficient 26-pin exposed pad QFN.   MC34716EP Related Video Introduction MC34716EP Video Description: How to make a DC voltage regulator, super easy powerful power supply. Today I will show you how to make a dc volt regulator, super powerful power supply make at home. awesome diy dc voltage regulator power supply using mosfet make at home. Simple and easy dc power supply regulator make at home. Simple and easy electronics diy projects, diy electronics circuit make at home.   MC34716EP Pin Connections Figure: MC34716EP Pin Connections   MC34716EP Internal Block Diagram Figure: MC34716EP Internal Block Diagram   MC34716EP Features   MC34716EP Application Diagram Figure: Simplified Application Diagram   MC34716EP Functional description In modern microprocessor/memory applications, address command and control lines require system level termination to a voltage (VTT) equal to 1/2 the memory supply voltage (VDDQ). Having the termination voltage  at the midpoint ensures that the power supply  maintains symmetry when switching occurs. Also, the DDR SDRAM input receiver must have a reference voltage  (VREF) that is free of any noise or voltage variations. VREF is also equal to 1/2 VDDQ. Varying the VREF voltage effects the setup and hold time of the memory. To comply with DDR requirements and to obtain the best performance, VTT and VREF must be tightly regulated to track 1/2 VDDQ across voltage, temperature and noise margins. VTT must track any variations in the DC VREF value (VTT = VREF 40 mV), for a DDR system level diagram.   The 34716 supplies the VDDQ, VTT and a buffered VREF output. To ensure compliance with DDR specifications, the VDDQ line is applied to the VREFIN pin and divided by 2 internally through a precision resistor divider. This internal voltage is then used as the reference voltage for the VTT output. The same internal voltage is also buffered so that the VREF voltage at the applications VREFOUT pin can be used without an external resistor divider. The 34716 offers tight voltage regulation and power sequencing/tracking along with the ability to handle DDR peak transient current requirements. It gives the user a complete DDR power supply  solution with optimum performance. Buffering the VREF output provides enhanced immunity to noise and load changes.   The 34716 uses a voltage mode synchronous buck  switching converter topology with integrated low RDS(on) (50 m) N-channel power MOSFETs to provide an output voltage accuracy of less than ±2.0%. It has a programmable switching frequency that operates at up to 1.0 MHz. The 34716 supplies 5.0 A maximum from one output and sinks and sources up to 3.0 A of continuous current from the other output. It provides protection against output overcurrent, overvoltage, undervoltage and overtemperature conditions. It also protects the system from short-circuit events. A power good output signal alerts the host when a fault occurs.   For boards that support the suspend-to-RAM (S3) and the suspend-to-disk (S5) states, the 34716 offers the STBY and the SD pins respectively. Pulling any of these pins low, puts the IC in the corresponding state.   By integrating the control/supervisory circuitry along with the power MOSFET switches for the buck  converter into a space-efficient package, the 34716 offers a complete, small-size, cost-effective and simple solution to satisfy the needs of DDR memory applications.   Besides DDR memory termination, the 34716 also supports supply termination for other active buses and graphics card memory. It can be used in Netcom/Telecom applications like servers and is suitable for desktop motherboards, game consoles, set top boxes, and high end high definition TVs.  Figure: MC34716EP DDR System Level Diagram   MC34716EP Datasheet You can download the datasheet from the link given below: MC34716EP Datasheet   MC34716EP Specifications TypeDescriptionCategoryIntegrated Circuits (ICs)PMIC - Voltage Regulators - Special PurposeMfrNXP USA Inc.PackageTrayPart StatusObsoleteApplicationsConverter, DDRVoltage - Input3V ~ 6VNumber of Outputs2Voltage - Output0.7V ~ 3.6VOperating Temperature-40°C ~ 85°CMounting TypeSurface MountPackage / Case26-VFQFN Exposed PadSupplier Device Package26-QFN (5x5)Base Product NumberMC347 MC34716EP Manufacturer NXP Semiconductors N.V. is a Netherlands-domiciled American semiconductor manufacturer with headquarters in Eindhoven, Netherlands that focuses in the automotive industry. The company employs approximately 31,000 people in more than 35 countries, including 11,200 engineers in 33 countries.   Using Warning Note: Please check their parameters and pin configuration before replacing them in your circuit.   MC34716EP FAQ What is voltage regulator power supply? A voltage regulator is a component of the power supply unit that ensures a steady constant voltage supply through all operational conditions. It regulates voltage during power fluctuations and variations in loads. A voltage regulator usually takes in higher input voltage and emits a lower, more stable output voltage.   What is voltage regulator use for? Voltage regulator, any electrical or electronic device that maintains the voltage of a power source within acceptable limits. The voltage regulator is needed to keep voltages within the prescribed range that can be tolerated by the electrical equipment using that voltage.   What are the different types of voltage regulators? There are two main types of voltage regulators: linear and switching. Both types regulate a system's voltage, but linear regulators operate with low efficiency and switching regulators operate with high efficiency.  

CatalogProduct OverviewHCF4094YM013TR Related Video IntroductionHCF4094YM013TR CAD ModelsHCF4094YM013TR Pin ConnectionsHCF4094YM013TR Logic DiagramHCF4094YM013TR Functional DiagramHCF4094YM013TR Input equivalent circuitHCF4094YM013TR FeaturesHCF4094YM013TR ApplicationsHCF4094YM013TR DatasheetHCF4094YM013TR SpecificationsHCF4094YM013TR ManufacturerUsing WarningHCF4094YM013TR FAQ Product OverviewThe HCF4094 is a monolithic integrated circuit fabricated in metal oxide semiconductor technology available in an SO-16 package. The HCF4094 is an 8-stage, serial shift register having a storage latch associated with each stage for strobing data from the serial input to parallel buffered 3-state outputs. The parallel outputs may be connected directly to common bus lines. Data are shifted on positive clock transition. The data in each shift register stage are transferred to the storage register when the STROBE input is high. Data in the storage register appear at the outputs whenever the OUTPUT-ENABLE signal is high. Two serial outputs are available for cascading a number of HCF4094 devices. Data are available at the QS serial output terminal on positive clock edges to allow for high speed operation in a cascaded system in which the clock rise time is fast. The same serial information, available at the Q’S terminal on the next negative clock edge, provides a means for cascading HCF4094 devices when the clock rise time is slow. HCF4094YM013TR Related Video IntroductionHCF4094YM013TR Video Description: Shift registers are devices that are quite popular when using micro controllers as they can be used to expand the number of inputs or outputs available. In this lesson, Karen explains how serial and parallel data are used and shifted through these devices. HCF4094YM013TR CAD ModelsFigure: HCF4094YM013TR PCB Symbol   Figure: HCF4094YM013TR Footprint   Figure: HCF4094YM013TR 3D Models HCF4094YM013TR Pin ConnectionsFigure: HCF4094YM013TR Pin Connections Pin DescriptionPin noSymbolName and function2DATAData input1STROBEStrobe input3CLOCKClock input9, 10QS, Q’SSerial outputs4, 5, 6, 7, 14, 13, 12, 11Q1 to Q8Parallel outputs15OUTPUT ENABLEOutput enable input8VSSNegative supply voltage16VDDPositive supply voltage HCF4094YM013TR Logic DiagramFigure: HCF4094YM013TR Logic Diagram HCF4094YM013TR Functional DiagramFigure: HCF4094YM013TR Functional Diagram HCF4094YM013TR Input equivalent circuit Figure: HCF4094YM013TR Input equivalent circuit HCF4094YM013TR Features3- state parallel outputs for connection tocommon busSeparate serial outputs synchronous to bothpositive and negative clock edges for cascadingMedium speed operation 5 MHz at 10 VQuiescent current specified up to 20 VStandardized symmetrical outputcharacteristics5 V, 10 V, and 15 V parametric ratingsInput leakage current II= 100 nA (max.) at VDD = 18 V, TA = 25℃100% tested for quiescent currentESD performance– HBM: 1 kV– MM: 200 V– CDM: 1 kV HCF4094YM013TR ApplicationsAutomotiveIndustrialComputerConsumer HCF4094YM013TR DatasheetYou can download the datasheet from the link given below:HCF4094YM013TR Datasheet HCF4094YM013TR SpecificationsProduct AttributeAttribute ValueManufacturer:STMicroelectronicsProduct Category:Counter Shift RegistersCounting Sequence:Serial to ParallelNumber of Circuits:16Number of Bits:8 bitPackage / Case:SOIC-16Logic Family:HCFLogic Type:Shift RegisterNumber of Input Lines:3Output Type:3-StatePropagation Delay Time:420 nsSupply Voltage - Min:3 VSupply Voltage - Max:20 VOperating Temperature:-40°C ~ 125°CQualification:AEC-Q100Brand:STMicroelectronicsFunction:8 Stage Shift and Store Bus RegisterInput Type:SerialMoisture Sensitive:YesMounting Style:SMD/SMTNumber of Output Lines:8Operating Supply Voltage:20 VProduct Type:Counter Shift RegistersSeries:HCF4094Factory Pack Quantity:2500Subcategory:Logic ICsUnit Weight:0.007079 oz HCF4094YM013TR ManufacturerSTMicroelectronics is a French-Italian multinational electronics and semiconductors manufacturer headquartered in Plan-les-Ouates near Geneva, Switzerland. The company resulted from the merger of two government-owned semiconductor companies in 1987: "Thomson Semiconducteurs" of France and "SGS Microelettronica" of Italy. It is commonly called "ST", and it is Europe's largest semiconductor chip maker based on revenue. While STMicroelectronics corporate headquarters and the headquarters for EMEA region are based in the Canton of Geneva, the holding company, STMicroelectronics N.V. is incorporated in the Netherlands. Using WarningNote: Please check their parameters and pin configuration before replacing them in your circuit. HCF4094YM013TR FAQWhat are counter shift registers?Shift register counters are a sequence of a certain number of core registers that are connected together to provide a clock-driven data shift. The most common of these are called Johnson counters and ring counters. What is counter register?A counter register is a sequential circuit with n + 1 inputs and n outputs. It differs from an ordinary counter in that it can also function as a register. It differes from a register in that when not explictly loaded, it works as a counter, rather than maintaining its previous value. What is the difference between counters and shift registers?A counter is a special case of a register. Shift registers are a type of sequential logic circuit, mainly for storage of digital data. They are a group of flip-flops connected in a chain so that the output from one flip-flop becomes the input of the next flip-flop. 

Catalog MIC2026-1YM-TR Description MIC2026-1YM-TR Related Video Instruction MIC2026-1YM-TR CAD Models MIC2026-1YM-TR Package Type MIC2026-1YM-TR Block Diagram MIC2026-1YM-TR Features MIC2026-1YM-TR Applications MIC2026-1YM-TR Datasheet MIC2026-1YM-TR Specifications MIC2026-1YM-TR Manufacturer Using Warning MIC2026-1YM-TR FAQ MIC2026-1YM-TR Description The MIC2026 and MIC2076 are high-side MOSFET switches optimized for general-purpose power distribution that requires circuit protection.The MIC2026/76 are internally current limited and have thermal shutdown that protects the device and load. The MIC2076 offers “smart” thermal shutdown that reduces current consumption in fault modes. When a thermal shutdown fault occurs, the output is latched off until the faulty load is removed. Removing the load or toggling the enable input will reset the device output. Both devices employ soft-start circuitry that minimizes inrush current in applications where highly capacitive loads are employed.   A fault status output flag is asserted during overcurrent and thermal shutdown conditions. Transient faults are internally filtered.The MIC2026/76 are available in an 8-pin SOIC package.   MIC2026-1YM-TR Related Video Instruction Video: MOSFETs: High-Side vs Low-Side Switching   MIC2026-1YM-TR CAD Models   Figure: PCB Symbol     Figure: Footprint     Figure: 3D Model   MIC2026-1YM-TR Package Type   Figure: Package Type   MIC2026-1YM-TR Block Diagram   Figure: Block Diagram   MIC2026-1YM-TR Features 140 mΩ Maximum On-Resistance per Channel2.7V to 5.5V Operating Range500 mA Minimum Continuous Current per ChannelShort-Circuit Protection with Thermal ShutdownThermally Isolated ChannelsFault Status Flag with 3 ms Filter Eliminates False AssertionsUndervoltage LockoutReverse Current Flow Blocking (No “Body Diode”)Circuit Breaker Mode (MIC2076)Logic-Compatible InputsSoft-Start CircuitLow Quiescent CurrentPin-Compatible with MIC2526UL File #E179633   MIC2026-1YM-TR Applications USB PeripheralsGeneral Purpose Power SwitchingACPI Power DistributionNotebook PCsPDAsPC Card Hot Swap   MIC2026-1YM-TR Typical Application Circuit   Figure: Typical Application Circuit   MIC2026-1YM-TR Datasheet You can download the datasheet from the link given below. MIC2026-1YM-TR-Datasheet   MIC2026-1YM-TR Specifications Product Category:Power Switch ICs - Power DistributionType:High SideNumber of Outputs:2 OutputOutput Current:500 mACurrent Limit:900 mAOn Resistance - Max:140 mOhmsOn Time - Max:5 msOff Time - Max:100 usOperating Supply Voltage:2.7 V to 5.5 VMinimum Operating Temperature:- 40 ℃Maximum Operating Temperature:+ 85 ℃Mounting Style:SMD/SMTPackage / Case:SOIC-8Packaging:ReelPackaging:Cut TapePackaging:MouseReelManufacturer:MicrochipBrand:Microchip Technology / MicrelMoisture Sensitive:YesProduct:Power DistributionProduct Type:Power Switch ICs - Power DistributionFactory Pack Quantity:2500Subcategory:Switch ICsSupply Voltage - Max:5.5 VSupply Voltage - Min:2.7 VPart # Aliases:MIC2026-1YM TRUnit Weight:0.019048 oz   MIC2026-1YM-TR Manufacturer Microchip Technology Inc. is a publicly-listed American corporation that manufactures microcontroller, mixed-signal, analog and Flash-IP integrated circuits. Its products include microcontrollers (PIC, dsPIC, AVR and SAM), Serial EEPROM devices, Serial SRAM devices, embedded security devices, radio frequency (RF) devices, thermal, power and battery management analog devices, as well as linear, interface and wireless products.   Using Warning Note: Please check their parameters and pin configuration before replacing them in your circuit.   MIC2026-1YM-TR FAQ What is high side switch MOSFET? High-side means the current travels from the supply through the mosfet to the load and then to ground. Another way to put that is: Low-side = mosfet source to ground, drain to load, load to supply. High-side = mosfet drain to supply, source to load, load to ground.   What does a high side switch do? High-side switches are used to turn electrical loads ON and OFF by switching the positive (high-) side of the load supply.   When would you use a high side switch? High-side switching is the preferred switching technique in situations where short circuits to ground are likelier to occur than short circuits to the positive power line. Think for instance of cars or machines where most of the structure or body is connected to ground.   What is difference between high side and low side current sensing? The difference is based off on the location of the sense resistor. Low side sensing is between load and ground, with high side sensing between power and the load. A high side current sensor, with a precision trimmed preset gain of either 20, 50, or 100.   How do you drive a high side MOSFET? Here when the high-side MOSFET is off, a capacitor is charged from the driving voltage. The capacitor charges through the load or a supporting low-side MOFSET. When the high-side MOSFET is to be turned on/driven, the voltage on the capacitor is used to drive the high-side MOSFET.