The Kynix Components

CatalogDescriptionDiagram of Host Board Connector Block Pin Numbers and NamesHost-Module InterfaceRegulatory ComplianceDigital Diagnostic FunctionsFeaturesApplicationsDatasheetSpecificationsManufacturerUsing WarningFAQDescriptionFinisar’s FTLX8574D3BCV 1G/10G Dual-Rate SFP+ transceivers are designed for use in 1-Gigabit and 10-Gigabit Ethernet links over multimode fiber. They are compliant with SFF-84311, IEEE 802.3-2012 10GBASE-SR/SW2 and 1000BASE-SX3 . Digital diagnostics functions are available via a 2-wire serial interface, as specified in SFF- 84724 . The FTLX8574D3BCV is a “limiting module”, i.e., it employs a limiting receiver. Host board designers using an EDC PHY IC should follow the IC manufacturer’s recommended settings for interoperability with an SFP+ limiting module. This product is for applications specifically designed for 10G SFP+ ports and 1G/10G SFP+ ports and not native 1G SFP ports. The optical transceiver is compliant per the RoHS Directive 2011/65/EU5. See Finisar Application Note AN-20386 for more details. Diagram of Host Board Connector Block Pin Numbers and Names Figure: Diagram of Host Board Connector Block Pin Numbers and Names Host-Module Interface Figure: Host-Module Interface Regulatory ComplianceFinisar transceivers are Class 1 Laser Products and comply with US FDA regulations.These products are certified by TÜV and CSA to meet the Class 1 eye safety requirements of EN (IEC) 60825 and the electrical safety requirements of EN (IEC) 60950. Copies of certificates are available at Finisar Corporation upon request. Digital Diagnostic FunctionsFinisar FTLX8574D3BCV SFP+ transceivers support the 2-wire serial communication protocol as defined in the SFF-8472. It is very closely related to the E2 PROM defined in the GBIC standard, with the same electrical specifications.The standard SFP+ serial ID provides access to identification information that describes the transceiver’s capabilities, standard interfaces, manufacturer, and other information. Additionally, Finisar SFP+ transceivers provide a enhanced digital diagnostic monitoring interface, which allows real-time access to device operating parameters such as transceiver temperature, laser bias current, transmitted optical power, received optical power and transceiver supply voltage. It also defines a sophisticated system of alarm and warning flags, which alerts end-users when particular operating parameters are outside of a factory set normal range. SFF-8472 defines a 256-byte memory map in E2 PROM that is accessible over a 2-wire serial interface at the 8 bit address 1010000X (A0h). The digital diagnostic monitoring interface makes use of the 8 bit address 1010001X (A2h), so the originally defined serial ID memory map remains unchanged. The interface is identical to, and is thus fully backward compatible with both the GBIC Specification and the SFP Multi Source Agreement. The complete interface is described in Finisar Application Note AN-2030: “Digital Diagnostics Monitoring Interface for SFP Optical Transceivers”. The operating and diagnostics information is monitored and reported by a Digital Diagnostics Transceiver Controller (DDTC) inside the transceiver, which is accessed through a 2-wire serial interface. When the serial protocol is activated, the serial clock signal (SCL, Mod Def 1) is generated by the host. The positive edge clocks data into the SFP transceiver into those segments of the E2 PROM that are not write-protected. The negative edge clocks data from the SFP transceiver. The serial data signal (SDA, Mod Def 2) is bi-directional for serial data transfer. The host uses SDA in conjunction with SCL to mark the start and end of serial protocol activation. The memories are organized as a series of 8-bit data words that can be addressed individually or sequentially. For more information, please see the SFF-8472 documentation and Finisar Application Note AN-2030. FeaturesHot-pluggable SFP+ footprintSupports rate selectable 1.25 Gb/s or 9.95 to 10.3 Gb/s bit ratesPower dissipation < 1WRoHS-6 compliant (lead-free)Commercial temperature range -5°C to 70°CSingle 3.3V power supplyMaximum link length of 400m on OM4 MMFUncooled 850nm VCSEL laserReceiver limiting electrical interfaceDuplex LC connectorBuilt-in digital diagnostic functions Applications1000BASE-SX 1G Ethernet10GBASE-SR/SW 10G Ethernet DatasheetYou can download the datasheet from the link given below:FTLX8574D3BCV-Datasheet SpecificationsProduct Category:Fiber Optic Transmitters, Receivers, TransceiversProduct:TransceiversWavelength:850 nmData Rate:10.3 GBdFiber Type:MultimodeRise Time:28 psEmitting Source:VCSELOperating Supply Voltage:3.3 VMinimum Operating Temperature:- 5 ℃Maximum Operating Temperature:+ 70 ℃Application:Ethernet, Fibre ChannelConnector Type:LCTransmission Distance:400 mBrand:II-VI / FinisarMounting Style:Snap-InPackage / Case:56.5 mm x 13.7 mm x 8.5 mmProduct Type:Fiber Optic Transmitters, Receivers, TransceiversFactory Pack Quantity:10Subcategory:Fiber OpticTradename:FinisarUnit Weight:1.064404 oz ManufacturerFinisar Corporation is a manufacturer of optical communication components and subsystems. In 2008, Finisar merged with Optium Corporation. Using WarningNote: Please check their parameters and pin configuration before replacing them in your circuit. FAQAre SFP+ transceivers universal?SFP and SFP+ modules look exactly the same. And as they have the same size, your SFP transceiver will fit seamlessly into an SFP+ switch port and vice versa. However, the connection won't work as you expect it to. Or, worse even, it won't work at all. What does a SFP+ transceiver do?SFP+ is a faster version of the same form factor. It supports speeds up to 10Gbps, and it typically works across shorter distances.QSFP (quad small form-factor pluggable) is another transceiver with a range of support options. Ethernet, InfiniBand, SONET and fiber channels are all supported. Can I use SFP+ transceiver in SFP slot?When use SFP and SFP+ modules in your network, make sure the speed of both ends of the fiber link is the same. SFP modules may can be used in SFP+ slot, but a SFP can never be connected to a SFP+ module. 

Product OverviewThe AD623 is an integrated single-supply instrumentation amplifier that delivers rail-to-rail output swing on a 3 V to 12 V supply. The AD623 offers superior user flexibility by allowing single gain set resistor programming and by conforming to the 8-lead industry standard pinout configuration. With no external resistor, the AD623 is configured for unity gain (G = 1), and with an external resistor, the AD623 can be programmed for gains up to 1000. This blog will introduce AD623 systematically from its features, pinout to its specifications, applications, also including AD623 datasheet and so much more.CatalogProduct OverviewRelated Video IntroductionAD623 FeaturesAD623 PinoutLM3900 Pin ConfigurationAD623 ApplicationsAD623 AlternativesHow to use AD623 ICAD623 Block DiagramAD623 Circuit DiagramAD623 PackageAD623 SpecificationAD623 ManufacturerAD623 DatasheetUsing WarningsAD623 FAQ Related Video Introduction Video: Instrumentation Amplifiers XXX Video Description: This video highlights a special configuration of 3 op-amps, known as an instrumentation amplifier. It explains how the circuit works, how its gain is controlled, and why it is useful for amplifying difficult-to-attain signals in instrumentation equipment. AD623 FeaturesEasy to useRail-to-rail output swingInput voltage range extends 150 mV below ground(single supply)Low power, 550 µA maximum quiescent currentGain set with one external resistorGain range: 1 to 1000High accuracy dc performance0.10% gain error (G = 1)0.35% gain error (G > 1)Noise: 35 nV/√Hz RTI noise at 1 kHzOptimal dynamic specifications800 kHz bandwidth (G = 1)20 µs settling time to 0.01% (G = 10) AD623 PinoutThe following figure is the diagram of AD623 pinout. AD623 Pinout LM3900 Pin ConfigurationPin NumberPin NameDescription1Gain (-Rg)Inverting Gain Terminal connected to resistor to set gain value2Inverting Input (IN-)The Inverting input pin of the Op-Amp3Non- Inverting Input (IN-)The Non - Inverting Input Pin of Amplifier4Power (-Vs)Negative supply terminal 5ReferenceOutput reference input. Normally connected to common6OutputAmplifier output pin7Power (+Vs)Positive supply terminal 8Gain (+Rg)Non - Inverting Gain Terminal connected to resistor to set gain value AD623 ApplicationsLow power medical instrumentationTransducer interfacesThermocouple amplifiersIndustrial process controlsDifference amplifiersLow power data acquisition AD623 AlternativesLM4871, AD620, IC6283, JRC4558, How to use AD623 ICThe AD623 only requires a resistor to sets its gain value and hence can be easily set up. A very basic commonly used circuit for AD623 is shown below. AD623 Circuit Diagram The IC is powered using the pin 7 and pin 4, here I have used a singly supply of +5V hence the pin 4 is grounded. If a dual supply voltage is used the pin 4 will be provided with negative voltage. The non - inverting pin (pin 2) and the inverting pin (pin 3) is connected the signal which has to be amplified or compared base on the application of the Op-Amp. The Reference pin (pin 5) is normally grounded along with pin 4, the reference pin is used to direct the output towards a voltage when the difference voltage between the inverting and the non-inverting pin is 0V. The Gain of an Op-Amp can be set by simply connecting the right value of resistor across the pin +Rg (pin 8) and the pin –Rg (pin 1). Here I have connected a resistor of value 500Ω which will set the Op-Amp at a gain value of 100. AD623 Block DiagramThe following figure shows the block diagram of AD623. AD623 Block Diagram AD623 Circuit DiagramThe following is the circuit diagram to attenuate RF interference. AD623 Circuit Diagram AD623 PackageThe following diagram shows the AD623 package. AD623 Package AD623 SpecificationProduct AttributeAttribute ValueAmplifier Type:INSTRUMENTATION AMPLIFIERManufacturer:Analog Devices IncAverage Bias Current-Max (IIB):0.0275 µACommon-mode Reject Ratio-Min:70 dBInput Offset Current-Max (IIO):0.0025 µAInput Offset Voltage-Max:650 µVLength:3 mmNeg Supply Voltage Limit-Max:6 VOperating Temperature-Max:85 °CSupply Current-Max:0.625 mA AD623 ManufacturerAnalog Devices has built one of the longest standing, highest growth companies within the technology sector utilizing cultural pillars such as innovation, performance, and excellence. Acknowledged industry-wide as the world leader in data conversion and signal conditioning technology, Analog Devices serves over 100,000 customers, representing virtually all types of electronic equipment. Celebrating over 50 years as a leading global manufacturer of high-performance integrated circuits used in analog and digital signal processing applications, Analog Devices is headquartered in Norwood, Massachusetts, with design and manufacturing facilities throughout the world. Analog Devices' is included in the S&P 500 Index. AD623 DatasheetYou can download AD623 datasheet from the link given below:AD623 Datasheet Using WarningsNote: Please check their parameters and pin configuration before replacing them in your circuit. AD623 FAQWhat is AD623?The AD623 is an integrated, single- or dual-supply instrumentation amplifier that delivers rail-to-rail output swing using supply voltages from 2.7 V to 12 V. The AD623 has a wide input common-mode range and amplifies signals with common-mode voltages as low as 150 mV below ground. What is the use of instrumentation amplifier?An instrumentation amplifier is used to amplify very low-level signals, rejecting noise and interference signals. Examples can be heartbeats, blood pressure, temperature, earthquakes and so on. Therefore, the essential characteristics of a good instrumentation amplifier are as follows. What are the basic requirements of a good instrumentation amplifier?The instrumentation amplifier is intended for precise, low-level signal amplification where high input resistance, low noise and accurate closed-loop gain is required. Also, low power consumption, high slew rate and high common-mode rejection ratio are desirable for good performance. What is the common mode range of the ad623?The AD623 has a wide input common-mode range and amplifies signals with common-mode voltages as low as 150 mV below ground. The AD623 maintains optimal performance with dual and single polarity power supplies. Is there an external resistor for the ad623?The AD623 offers user flexibility by allowing single gain set resistor programming and by conforming to the 8-lead industry standard pinout configuration. With no external resistor, the AD623 is configured for unity gain (G = 1), and with an external resistor, the AD623 can be programmed for gains of up to 1000. 

CatalogATTINY45-20SU DescriptionATTINY45-20SU CAD ModelsATTINY45-20SU Pin ConfigurationATTINY45-20SU Block DiagramATTINY45-20SU FeaturesATTINY45-20SU DatasheetATTINY45-20SU SpecificationsATTINY45-20SU ManufacturerUsing WarningATTINY45-20SU FAQATTINY45-20SU DescriptionThe ATtiny25/45/85 is a low-power CMOS 8-bit microcontroller based on the AVR enhanced RISC architecture. By executing powerful instructions in a single clock cycle, the ATtiny25/45/85 achieves throughputs approaching 1 MIPS per MHz allowing the system designer to optimize power consumption versus processing speed. ATTINY45-20SU CAD Models Figure: PCB Symbol  Figure: Footprint  Figure: 3D Model ATTINY45-20SU Pin Configuration Figure: Pin Configuration ATTINY45-20SU Block Diagram Figure: Block Diagram ATTINY45-20SU FeaturesHigh Performance, Low Power AVR 8-Bit MicrocontrollerAdvanced RISC Architecture        – 120 Powerful Instructions        – Most Single Clock Cycle Execution        – 32 x 8 General Purpose Working Registers        – Fully Static OperationNon-volatile Program and Data Memories        – 2/4/8K Bytes of In-System Programmable Program Memory FlashEndurance: 10,000 Write/Erase Cycles        – 128/256/512 Bytes In-System Programmable EEPROMEndurance: 100,000 Write/Erase Cycles        – 128/256/512 Bytes Internal SRAM        – Programming Lock for Self-Programming Flash Program and EEPROM Data SecurityPeripheral Features        – 8-bit Timer/Counter with Prescaler and Two PWM Channels        – 8-bit High Speed Timer/Counter with Separate Prescaler2 High Frequency PWM Outputs with Separate Output Compare RegistersProgrammable Dead Time Generator        – USI – Universal Serial Interface with Start Condition Detector        – 10-bit ADC4 Single Ended Channels2 Differential ADC Channel Pairs with Programmable Gain (1x, 20x)Temperature Measurement        – Programmable Watchdog Timer with Separate On-chip Oscillator        – On-chip Analog ComparatorSpecial Microcontroller Features        – debugWIRE On-chip Debug System        – In-System Programmable via SPI Port        – External and Internal Interrupt Sources        – Low Power Idle, ADC Noise Reduction, and Power-down Modes        – Enhanced Power-on Reset Circuit        – Programmable Brown-out Detection Circuit        – Internal Calibrated OscillatorI/O and Packages        – Six Programmable I/O Lines        – 8-pin PDIP, 8-pin SOIC, 20-pad QFN/MLF, and 8-pin TSSOP (only ATtiny45/V)Operating Voltage        – 1.8 - 5.5V for ATtiny25V/45V/85V        – 2.7 - 5.5V for ATtiny25/45/85Speed Grade        – ATtiny25V/45V/85V: 0        – 4 MHz @ 1.8 - 5.5V, 0 - 10 MHz @ 2.7 - 5.5V        – ATtiny25/45/85: 0        – 10 MHz @ 2.7 - 5.5V, 0 - 20 MHz @ 4.5 - 5.5VIndustrial Temperature RangeLow Power Consumption        – Active Mode:1 MHz, 1.8V: 300 µA        – Power-down Mode:0.1 µA at 1.8V ATTINY45-20SU DatasheetYou can download the datasheet from the link given below:ATTINY45-20SU-Datasheet ATTINY45-20SU SpecificationsManufacturer:MicrochipProduct Category:8-bit Microcontrollers - MCUSeries:ATtiny45Mounting Style:SMD/SMTPackage / Case:SOIC-8Core:AVRProgram Memory Size:4 kBData Bus Width:8 bitADC Resolution:10 bitMaximum Clock Frequency:20 MHzNumber of I/Os:6 I/OData RAM Size:256 BOperating Supply Voltage:2.7 V to 5.5 VMinimum Operating Temperature:- 40 CMaximum Operating Temperature:+ 85 CPackaging:ReelPackaging:Cut TapePackaging:MouseReelBrand:Microchip Technology / AtmelData RAM Type:SRAMHeight:2.16 mmInterface Type:SPILength:5.35 mmMoisture Sensitive:YesNumber of ADC Channels:4 ChannelNumber of Timers/Counters:1 TimerProcessor Series:tinyAVRProduct:MCUProduct Type:8-bit Microcontrollers - MCUProgram Memory Type:FlashFactory Pack Quantity:2000Subcategory:Microcontrollers - MCUTradename:AVRWidth:5.4 mmUnit Weight:0.019048 oz ATTINY45-20SU ManufacturerAtmel Corporation was a designer and manufacturer of semiconductors before being subsumed by Microchip Technology in 2016. Atmel was founded in 1984. The company focused on embedded systems built around microcontrollers. Using WarningNote: Please check their parameters and pin configuration before replacing them in your circuit. ATTINY45-20SU FAQHow do I program ATtiny45?Programming ATtiny45, ATtiny85, ATtiny44 or ATtiny84Download and install the latest Arduino IDE (Link)Download ATTINY Library for Arduino, and Unzip it (Link)Go to your Arduino Sketch book folder (the folder where the Arduino IDE stores your sketches. ...Create a new sub-folder called “hardware” in the sketchbook folder. What is ATTINY45 microcontroller?ATtiny45 is a high-performance, low-power Atmel 8-bit AVR RISC-based microcontroller combines 4KB ISP flash memory, 256-Byte EEPROM, 256B SRAM, 6 general purpose I/O lines, 32 general purpose working registers, one 8-bit timer/counter with compare modes, one 8-bit high speed timer/counter, USI, internal and external. What is the use of AVR microcontroller?It contain on chip central processing unit (CPU), Read only memory (ROM), Random access memory (RAM), input/output unit, interrupts controller etc. Therefore a microcontroller is used for high speed signal processing operation inside an embedded system. 

Product OverviewThe TEA5767HN is a single-chip electronically tuned FM stereo radio for low-voltage applications with fully integrated Intermediate Frequency (IF) selectivity and demodulation. The radio is completely adjustment-free and only requires a minimum of small and low cost external components. The radio can be tuned to the European, US, and Japanese FM bands. This blog will introduce TEA5767HN systematically from its features, pinout to its specifications, applications, also including TEA5767HN datasheet and so much more. CatalogProduct OverviewRelated Video IntroductionTEA5767HN FeaturesTEA5767HN PinoutTEA5767HN CAD ModelsTEA5767HN Circuit DiagramTEA5767HN PackageTEA5767HN SpecificationTEA5767HN ManufacturerTEA5767HN DatasheetUsing WarningsTEA5767HN FAQ Related Video Introduction Video: TEA5767 FM radio with amplifier - IC Station Review TEA5767 Video Description: This is the review of a TEA5767 digital FM tuner chip with a built in amplifier from icstation.com. As it is called in the listing: "FM Stereo Radio Module 5V TEA5767 76-108MHZ FM Radio Module High Stability Low Noise + Cable Antenna" TEA5767HN Features■ High sensitivity due to integrated low-noise RF input amplifier■ FM mixer for conversion to IF of the US/Europe (87.5 MHz to 108 MHz) and Japanese(76 MHz to 91 MHz) FM band■ Preset tuning to receive Japanese TV audio up to 108 MHz■ RF Automatic Gain Control (AGC) circuit■ LC tuner oscillator operating with low cost fixed chip inductors■ FM IF selectivity performed internally■ No external discriminator needed due to fully integrated FM demodulator■ Crystal reference frequency oscillator; the oscillator operates with a 32.768 kHz clockcrystal or with a 13 MHz crystal and with an externally applied 6.5 MHz referencefrequency■ Phase-locked loop (PLL) synthesizer tuning system TEA5767HN PinoutThe following figure is the diagram of TEA5767HN pinout. TEA5767HN Pinout TEA5767HN CAD ModelsThe followings are TEA5767HN Symbol, Footprint, and 3D Model. TEA5767HN Symbol TEA5767HN Footprint TEA5767HN 3D Model TEA5767HN Circuit DiagramThe following is the application and test diagram of TEA5767HN. TEA5767HN Circuit Diagram TEA5767HN PackageThe following diagram shows the TEA5767HN package. TEA5767HN Package TEA5767HN SpecificationProduct AttributeAttribute ValueManufacturer:NXPDemodulation Type:FMOperating Temperature-Max:75 °COperating Temperature-Min:-10 °COutput Voltage-Nom (FM):75 mVPeak Reflow Temperature (Cel):260Supply Voltage-Max (Vsup):5 VSupply Voltage-Min (Vsup):2.5 VTime@Peak Reflow Temperature-Max (s):40Width:6 mm TEA5767HN ManufacturerNXP Semiconductors enables secure connections and infrastructure for a smarter world, advancing solutions that make lives easier, better and safer. As the world leader in secure connectivity solutions for embedded applications, NXP is driving innovation in the secure connected vehicle, end-to-end security and privacy and smart connected solutions markets. TEA5767HN DatasheetYou can download TEA5767HN datasheet from the link given below:TEA5767HN Datasheet Using WarningsNote: Please check their parameters and pin configuration before replacing them in your circuit. TEA5767HN FAQWhat is stereo FM radio?To transmit stereo music, FM is enhanced by stereo multiplexing which carries both L and R audio channel content. With the digital age, Radio Data System (RDS) enables FM to carry text information such as traffic, weather, and radio station information which can be displayed on the end-user's device interface. How does stereo FM radio work?In FM broadcasting, the frequency of the carrier wave is modulated to encode the sound. A radio receiver extracts the original program sound from the modulated radio signal and reproduces the sound in a loudspeaker. What is the pilot signal for stereo FM?In FM stereo broadcasting, a pilot tone of 19 kHz indicates that there is stereophonic information at 38 kHz (19×2, the second harmonic of the pilot). The receiver doubles the frequency of the pilot tone and uses it as a frequency and phase reference to demodulate the stereo information.

CatalogProduct Overview2N7002 CAD Models2N7002 Pin Configuration2N7002 Block Diagram2N7002 Features2N7002 Applications2N7002 Datasheet2N7002 Specifications2N7002 ManufacturerUsing Warning2N7002 FAQ Product OverviewThese N-channel enhancement mode field effect transistors are produced using ON Semiconductor's proprietary, high cell density, DMOS technology. These products have been designed to minimize on-state resistance while providing rugged, reliable, and fast switching performance. They can be used in most applications requiring up to 400 mA DC and can deliver pulsed currents up to 2 A. These products are particularly suited for low-voltage, low-cur-rent applications, such as small servo motor control, power MOSFET gate drivers, and other switching applications. 2N7002 CAD ModelsFigure: 2N7002 PCB Symbol  Figure: 2N7002 Footprint 2N7002 Switching Test CircuitFigure: 2N7002 Switching Test Circuit 2N7002 Switching WaveformsFigure: 2N7002 Switching Waveforms 2N7002 FeaturesHigh Density Cell Design for Low RDS(ON)Voltage Controlled Small Signal SwitchRugged and ReliableHigh Saturation Current Capability 2N7002 DatasheetYou can download the datasheet from the link given below:2N7002 Datasheet 2N7002 SpecificationsProduct AttributeAttribute ValueManufacturer:onsemiProduct Category:MOSFETTechnology:SiMounting Style:SMD/SMTPackage / Case:SOT-23-3Transistor Polarity:N-ChannelNumber of Channels:1 ChannelVds - Drain-Source Breakdown Voltage:60 VId - Continuous Drain Current:115 mARds On - Drain-Source Resistance:7.5 OhmsVgs - Gate-Source Voltage:- 20 V, + 20 VVgs th - Gate-Source Threshold Voltage:2.5 VOperating Temperature:-55°C ~ 150°C (TJ)Pd - Power Dissipation:200 mWChannel Mode:EnhancementBrand:onsemi / FairchildConfiguration:SingleForward Transconductance - Min:0.08 SHeight:1.2 mmLength:2.9 mmProduct:MOSFET Small SignalProduct Type:MOSFETSeries:2N7002Subcategory:MOSFETsTransistor Type:1 N-ChannelWidth:1.3 mmPart # Aliases:2N7002_NLUnit Weight:0.000282 oz 2N7002 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. Using WarningNote: Please check their parameters and pin configuration before replacing them in your circuit. 2N7002 FAQWhat is a 2N7002?The 2N7002 is a low voltage, low current Logic Level N-channel MOSFET. Because of its low on-state resistance and low input capacitance it is used in power management applications. The MOSFET can be easily controlled by 3.3V or 5V system voltage since it has low threshold voltage. What is a maximum operation voltage for the 2N7002?Packaged in a TO-92 enclosure, both the 2N7000 and BS170 are 60 V devices. The 2N7000 can switch 200 mA. The BS170 can switch 500 mA, with a maximum on-resistance of 5 Ω at 10 V Vgs. The 2N7002 is a similar part with the same electrical characteristics as the 2N7000 but different package. What are the differences between 2N7002 and 2N7000?The 2N7002 is a similar part with the same electrical characteristics as the 2N7000 but different package. The 2N7002 is in a TO-236 package, also known as "small outline transistor" SOT-23 surface-mount, which is the most commonly used three-lead surface-mount package. 

CatalogProduct OverviewFQP13N10 CAD ModelsFQP13N10 Test CircuitsFQP13N10 Mechanical DimensionsFQP13N10 FeaturesFQP13N10 DatasheetFQP13N10 SpecificationsFQP13N10 ManufacturerUsing WarningFQP13N10 FAQ Product OverviewThis N-Channel enhancement mode power MOSFET is produced using Fairchild Semiconductor's proprietary planar stripe and DMOS technology. This advanced MOSFET technology has been especially tailored to reduce on-state resistance, and to provide superior switching performance and high avalanche energy strength. These devices are suitable for switched mode power supplies, audio amplifier, DC motor control, and variable switching power applications. FQP13N10 CAD ModelsFigure: FQP13N10 PCB Symbol  Figure: FQP13N10 Footprint  Figure: FQP13N10 3D Models FQP13N10 Test CircuitsFigure: FQP13N10 Gate Charge Test Circuit & Waveform  Figure: FQP13N10 Resistive Switching Test Circuit & Waveforms  Figure: FQP13N10 Unclamped Inductive Switching Test Circuit & Waveforms FQP13N10 Mechanical DimensionsFigure: FQP13N10 Mechanical Dimensions FQP13N10 Features12.8 A, 100 V, Rps(on) = 180 mQ (Max.) @ VGs= 10 V,lD=6.4ALow Gate Charge (Typ. 12 nC)Low Crss (Typ. 20 pF)100% Avalanche Tested175°C Maximum Junction Temperature Rating FQP13N10 DatasheetYou can download the datasheet from the link given below:FQP13N10 Datasheet FQP13N10 SpecificationsProduct AttributeAttribute ValueManufacturer:onsemiProduct Category:MOSFETTechnology:SiMounting Style:Through HolePackage / Case:TO-220-3Transistor Polarity:N-ChannelNumber of Channels:1 ChannelVds - Drain-Source Breakdown Voltage:100 VId - Continuous Drain Current:12.8 ARds On - Drain-Source Resistance:180 mOhmsVgs - Gate-Source Voltage:- 25 V, + 25 VVgs th - Gate-Source Threshold Voltage:2 VQg - Gate Charge:16 nCOperating Temperature:-55°C ~ 175°C (TJ)Pd - Power Dissipation:65 WChannel Mode:EnhancementTradename:QFETPackaging:TubeBrand:onsemi / FairchildConfiguration:SingleFall Time:25 nsForward Transconductance - Min:6.8 SHeight:16.3 mmLength:10.67 mmProduct Type:MOSFETRise Time:55 nsSeries:FQP13N10Subcategory:MOSFETsTransistor Type:1 N-ChannelType:MOSFETTypical Turn-Off Delay Time:20 nsTypical Turn-On Delay Time:5 nsWidth:4.7 mmPart # Aliases:FQP13N10_NLUnit Weight:0.068784 oz FQP13N10 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. Using WarningNote: Please check their parameters and pin configuration before replacing them in your circuit. FQP13N10 FAQWhat is MOSFET and how it works?In general, the MOSFET works as a switch, the MOSFET controls the voltage and current flow between the source and drain. The working of the MOSFET depends on the MOS capacitor, which is the semiconductor surface below the oxide layers between the source and drain terminal. What is MOSFET used for?The MOSFET (Metal Oxide Semiconductor Field Effect Transistor) transistor is a semiconductor device which is widely used for switching and amplifying electronic signals in the electronic devices. The MOSFET is a three terminal device such as source, gate, and drain. What devices use MOSFET?Power MOSFETs are commonly used in automotive electronics, particularly as switching devices in electronic control units, and as power converters in modern electric vehicles. The insulated-gate bipolar transistor (IGBT), a hybrid MOS-bipolar transistor, is also used for a wide variety of applications. What is the difference between Transistor and MOSFET?The Bipolar Junction Transistor (BJT) is a current-driven device (in contrast, MOSFET is voltage-driven) that is widely used as an amplifier, oscillator, or switch, amongst other things. How MOSFET works as an amplifier?A small change in gate voltage produces a large change in drain current as in JFET. This fact makes MOSFET capable of raising the strength of a weak signal; thus acting as an amplifier. During the positive half-cycle of the signal, the positive voltage on the gate increases and produces the enhancement-mode.