The Kynix Components

CatalogProduct OverviewFRDM-K64F Related Video IntroductionFRDM-K64F PinoutFRDM-K64F Main Components PlacementFRDM-K64F Block DiagramFRDM-K64F Reset CircuitFRDM-K64F FeaturesFRDM-K64F ApplicationsFRDM-K64F DatasheetFRDM-K64F SpecificationsFRDM-K64F ManufacturerUsing WarningFRDM-K64F FAQ Product OverviewThe NXP Freedom development platform is a set of software and hardware tools for evaluation and development. It is ideal for rapid prototyping of microcontroller-based applications. The NXP Freedom K64 hardware, FRDM-K64F is a simple, yet sophisticated design featuring a Kinetis K series microcontroller, built on the ARM® Cortex®-M4 core. FRDM-K64F can be used to evaluate the K64, K63, and K24 Kinetis K series devices. It features the MK64FN1M0VLL12 MCU, which boast the maximum operation frequency of 120 MHz, 1 MB of flash, 256 KB RAM, a full-speed USB controller, Ethernet controller, secure digital host controller, and analog and digital peripherals. The FRDM-K64F hardware is form-factor compatible with the ArduinoTM R3 pin layout, providing a broad range of expansion board options. The onboard interface includes a six axis digital accelerometer & magnetometer, RGB LED. SDHC, add-on Bluetooth module, add-on RF module, and Ethernet. The FRDM-K64F platform features OpenSDAv2, the NXP open-source hardware embedded serial and debug adapter running an open-source bootloader. This circuit offers several options for serial communication, flash programming. and run-control debugging. OpenSDAv2 is an mbedTM HDK -compatible debug interface preloaded with the open-source CMSIS DAP Interface firmware (mbed interface) for rapid prototyping and product development, with a focus on connected Internet of Things devices. FRDM-K64F Related Video IntroductionFRDM-K64F Video Description: Video showing configuring the FRDM-K64F as a USB host and the FRDM-K66F as a USB-CDC device. After building with GCC and loading the firmware to the boards the operation of the USB connection between the two boards is demonstrated. FRDM-K64F Pinout The MK64FN1M0VLL12 microcontroller is packaged in a 100-pin LQFP. Some pins are utilized in onboard circuitry, but some are directly connected to one of the four I/O headers. The pins on the K64 microcontroller are named for their general purpose input/output port pin function. For example, the first pin on Port A is referred as PTA1. The name assigned to the I/O connector pin is same as of the K64 pin connected to it, if applicable. Figure: FRDM-K64F Pinout FRDM-K64F Main Components PlacementFigure: FRDM-K64F Main Components Placement FRDM-K64F Block DiagramFigure: FRDM-K64F Block Diagram FRDM-K64F Reset CircuitThe RESET signal on the K20 is connected externally to a pushbutton, named SW1, and also to the OpenSDAv2 circuit. The reset button can be used to force an external reset event on the target MCU. The reset button can also be used to force the OpenSDAv2 circuit into boot loader mode.Figure: FRDM-K64F Reset Circuit FRDM-K64F FeaturesSupports:— Accelerometer only (roll, pitch and tilt)— Magnetometer only (2D auto)— Gyro only— Accelerometer plus magnetometer (eCompass)— Accelerometer plus gyro (gaming)— Accelerometer plus magnetometer plus gyroscope sensorsIncludes Freescale’s award-winning magnetic compensationsoftware— Provides geomagnetic field strength, hard- and soft-iron corrections, and quality-of-fit indicationVery low power consumption— 3 mA 9-axis fusion IDD on Kinetis ARM® Cortex® M0+ devices at 25 Hz fusion rate/200 Hz sensor rate— 0.6mA 9-axis fusion IDD on Kinetis ARM Cortex M4F devices at 25 Hz fusion rate/200 Hz sensor rateProgrammable sensor sample and fusion ratesSupports multiple 3D frames of reference (aerospace NED,Android and Windows 8)Library is coded in standard C99 ANSI CCompatible with the Freescale Sensor Fusion Toolbox for Androidand WindowsSupported by Freescale CodeWarrior, Kinetis Design Studio andProcessor Expert toolsOut-of-the box support for the following Freedom DevelopmentPlatforms with FRDM-FXS-MULTxfamily of sensor boards— Cortex M0+: FRDM-KL25Z / FRDM-KL26Z / FRDM-KL46Z— Cortex M4: FRDM-K20D50M— Cortex M4F: FRDM-K64F / FRDM-K22F (KDS only)Library version 5.00 includes bonus bare-metal implementationsfor tilt and eCompass. FRDM-K64F ApplicationsNotebook, tablet and smartphone sensor fusionGaming, motion control, head-mounted displays, wearableelectronicsAir mouse, remote controlNavigation, eCompass, IoT (Internet of Things) sensor datamanagement FRDM-K64F DatasheetYou can download the datasheet from the link given below:FRDM-K64F Datasheet FRDM-K64F SpecificationsTypeDescriptionCategoryDevelopment Boards, Kits, ProgrammersEvaluation Boards - Embedded - MCU, DSPPart StatusActiveBoard TypeEvaluation PlatformTypeMCU 32-BitCore ProcessorARM® Cortex®-M4PlatformFreedomUtilized IC / PartK24, K63, K64, mbed-Enabled DevelopmentMounting TypeFixedContentsBoard(s), Cable(s)Interconnect SystemArduino R3 ShieldSuggested Programming EnvironmentMbed-Enabled FRDM-K64F ManufacturerNXP 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 WarningNote: Please check their parameters and pin configuration before replacing them in your circuit. FRDM-K64F FAQWhat is FRDM-K64F?The Freedom-K64F is an ultra-low-cost development platform for Kinetis® K64, K63, and K24 MCUs. Form-factor compatible with the Arduino® UNO Rev3 pin layout. How is sensor fusion done?Sensor fusion is the ability to bring together inputs from multiple radars, lidars and cameras to form a single model or image of the environment around a vehicle. The resulting model is more accurate because it balances the strengths of the different sensors. Why sensor fusion is required?A sensor fusion scheme increases the stability of the lane detection system and makes the system more reliable. Moreover, a vision-based lane detection system and an accurate digital map help reduce the position errors from GPS, which lead to a more accurate vehicle localization and lane keeping. 

CatalogTPS22929DDBVR DescriptionTPS22929DDBVR Related Video InstructionTPS22929DDBVR CAD ModelsTPS22929DDBVR Pin ConfigurationTPS22929DDBVR Block DiagramTPS22929DDBVR FeaturesTPS22929DDBVR ApplicationsTPS22929DDBVR DatasheetTPS22929DDBVR SpecificationsTPS22929DDBVR ManufacturerUsing WarningTPS22929DDBVR FAQTPS22929DDBVR DescriptionThe TPS22929D is a small, low ron load switch with controlled turn on. The device contains a P-channel MOSFET that can operate over an input voltage range of 1.4 V to 5.5 V. The switch is controlled by an on/off input (ON)， which is capable of interfacing directly with low-voltage control signals. The TPS22929D is active high enable. The TPS22929D contains a 150-0 on-chip load resistor for quick output discharge when the switch is turmed off. The rise time of the device is intermally controlled in order to avoid inrush current. The TPS22929D device provides circuit breaker functionality by latching off the power-switch during reverse voltage situations. An internal reverse voltage comparator disables the power-switch when the output voltage (Vout) is driven higher than the input (VIN) to quickly (10 μs typ) stop the flow of current towards the input side of the switch. Reverse current is always active， even when the power-switch is disabled. Additionally, under-voltage lockout (UVLO) protection turns the switch off if the input voltage is too low. The TPS22929D is available in a small, space-saving 6-pin SOT23 package and is characterized for operation over the free-air temperature range of - 40℃ to 85℃. TPS22929DDBVR Related Video InstructionVideo: What is a load switchTPS22929DDBVR Video Description: This video will give a brief introduction of load switches and their equivalent discrete circuitry. TPS22929DDBVR CAD Models Figure: PCB Symbol  Figure: Footprint  Figure: 3D Model TPS22929DDBVR Pin Configuration Figure: Pin Configuration TPS22929DDBVR Block Diagram Figure: Block Diagram TPS22929DDBVR FeaturesIntegrated Single Load SwitchSmall SOT23-6 PackageInput Voltage Range: 1.4 V to 5.5 VLow ON-Resistance     - rON= 115 mQat VIN= 5 V     - rON=115mQatVIN=3.3V     - rON= 118 mQat VIN= 2.5 V     - rON= 129 mQ atVIN= 1.5 V1.8-A Continuous Switch Current (25°C)Low Threshold Control InputControlled Slew-rateUnder-Voltage Lock OutQuick Output DischargeReverse Current Protection TPS22929DDBVR ApplicationsPortable Industrial EquipmentPortable Medical EquipmentPortable Media PlayersPoint Of Sales TerminalGPS DevicesDigital CamerasPortable InstrumentationSmartphones TPS22929DDBVR DatasheetYou can download the datasheet from the link given below:TPS22929DDBVR-Datasheet TPS22929DDBVR SpecificationsProduct Category:Power Switch ICs - Power DistributionType:Load SwitchNumber of Outputs:1 OutputOutput Current:1.8 AOn Resistance - Max:150 mOhmsOn Time - Max:3315 usOff Time - Max:7.4 usOperating Supply Voltage:1.4 V to 5.5 VMinimum Operating Temperature:- 40 ℃Maximum Operating Temperature:+ 85 ℃Manufacturer:Texas InstrumentsBrand:Texas InstrumentsPd - Power Dissipation:463 mWProduct Type:Power Switch ICs - Power DistributionFactory Pack Quantity:3000Subcategory:Switch ICsMounting Style:SMD/SMTPackage / Case:SOT-23-6Series:TPS22929DSupply Voltage - Max:5.5 VSupply Voltage - Min:1.4 VUnit Weight:0.001270 ozPackaging:ReelPackaging:Cut Tape TPS22929DDBVR ManufacturerTexas Instruments Incorporated (TI) is an American technology company headquartered in Dallas, Texas, that designs and manufactures semiconductors and various integrated circuits, which it sells to electronics designers and manufacturers globally. It is one of the top 10 semiconductor companies worldwide based on sales volume.The company's focus is on developing analog chips and embedded processors, which account for more than 80% of its revenue.TI also produces TI digital light processing technology and education technology products including calculators, microcontrollers and multi-core processors. Using WarningNote: Please check their parameters and pin configuration before replacing them in your circuit. TPS22929DDBVR FAQWhat is the purpose of a load switch?Load switches connect loads to a common power supply under the control of an embedded microcontroller unit. Load switches are used to connect and disconnect a load from a source to power up or down, or to save energy when a load isn't needed. They can also be used to sequence power off-on operations. What is a MOSFET load switch?At the heart of any load switch is a MOSFET (usually an enhancement mode device) that is either integrated into a load switch integrated circuit, or for higher power handling requirements, can be a discrete device. The MOSFET passes current from the power source to the load and is turned on or off via a control signal. What is a load switch IC?The load switch IC is located between the power supply and the load. The ICs are used for power management to control the power supply to the load. Similar switches can be constructed with mechanical relays and semiconductors such as MOSFET, but load switch ICs can be miniaturized and consume less power. 

CatalogLMV324IPT DescriptionLMV324IPT Related Video InstructionLMV324IPT CAD ModelsLMV324IPT Pin ConfigurationLMV324IPT FeaturesLMV324IPT ApplicationsLMV324IPT DatasheetLMV324IPT SpecificationsLMV324IPT ManufacturerUsing WarningLMV324IPT FAQLMV324IPT Related ProductsLMV324IPT DescriptionThe LMV321/LMV324/LMV358 family (single, dual, and quad) answers the need for low cost, general-purpose operational amplifiers. They operate with voltages as low as 2.7 V and feature both input and output rail-to-rail, 145 µA consumption current, and 1 MHz gain bandwidth product (GBP). With such a low consumption and a sufficient GBP for many applications, these op amps are well suited for any kind of battery supplied and portable equipment application. The LMV321 device is housed in the space-saving 5-pin SOT23-5 package, which simplifies board design. The SOT23-5 has two pinning configurations to answer all application requirements. LMV324IPT Related Video InstructionVideo: What is an op amp? Operational Amplifier tutorial & super spy microphone circuitLMV324IPT Video Description: the basics of how to use an op amp (operational amplifier) to amplify tiny voltages, and builds a circuit to listen to very faint sounds with a microphone.  LMV324IPT CAD Models Figure: PCB Symbol  Figure: Footprint  Figure: 3D Model LMV324IPT Pin Configuration Figure: Pin Configuration LMV324IPT FeaturesOperating range from VCC = 2.7 to 6 VRail-to-rail input and outputExtended Vicm (VDD - 0.2 V to VCC + 0.2 V)Low supply current (145 µA)Gain bandwidth product (1 MHz)ESD tolerance (2 kV) LMV324IPT ApplicationsBattery powered electronic equipmentPersonal medical care (glucose meters)Laptops LMV324IPT DatasheetYou can download the datasheet from the link given below:LMV324IPT-Datasheet LMV324IPT SpecificationsManufacturer:STMicroelectronicsProduct Category:Operational Amplifiers - Op AmpsMounting Style:SMD/SMTPackage / Case:TSSOP-14Number of Channels:4 ChannelSupply Voltage - Max:6 VGBP - Gain Bandwidth Product:1 MHzOutput Current per Channel:46 mASR - Slew Rate:450 mV/usVos - Input Offset Voltage:3 mVSupply Voltage - Min:2.7 VMinimum Operating Temperature:- 40 ℃Maximum Operating Temperature:+ 125 ℃Ib - Input Bias Current:63 nAOperating Supply Current:145 uAShutdown:No ShutdownCMRR - Common Mode Rejection Ratio:95 dBen - Input Voltage Noise Density:40 nV/sqrt HzSeries:LMV324Packaging:ReelPackaging:Cut TapeAmplifier Type:Low Power AmplifierBrand:STMicroelectronicsHeight:1 mmLength:5 mmOperating Supply Voltage:2.7 V to 6 VProduct:Operational AmplifiersProduct Type:Op Amps - Operational AmplifiersPSRR - Power Supply Rejection Ratio:70 dBFactory Pack Quantity:2500Subcategory:Amplifier ICsSupply Type:SingleVoltage Gain dB:97 dBWidth:4.4 mmUnit Weight:0.004949 oz LMV324IPT 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. LMV324IPT FAQWhat are operational amplifiers used for?Op-amps are linear devices that are ideal for DC amplification and are used often in signal conditioning, filtering or other mathematical operations (add, subtract, integration and d3. 8. ifferentiation). The operational amplifier is arguably the most useful single device in analog electronic circuitry. Why is it called operational amplifier?Originally, op-amps were so named because they were used to model the basic mathematical operations of addition, subtraction, integration, differentiation, etc. in electronic analog computers. In this sense a true operational amplifier is an ideal circuit element. What is the difference between amplifier and operational amplifier?Amplifiers can be either electronic or mechanical in common definition whereas operational amplifiers are electronic amplifiers. Amplifiers, in general, have a limited capability of amplifying DC signals but all op-amps are capable of amplifying DC signals. LMV324IPT Related ProductsSee LMV321L, LMV324L, LMV358L for newer technological versionSee TSV851, TSV852, TSV854 for enhanced performances 

Product Overview The MCP6002 is a dual general purpose op amp offering rail-to-rail input and output over the 1.8 to 6V operating range. This amplifier has a typical GBWP of 1 MHz with typical quiescent current of 100 microamperes. The MCP6002 is available in 8-lead PDIP, SOIC and MSOP packages.   This blog will introduce MCP6002 systematically from its features, pinout to its specifications, applications, also including MCP6002 datasheet and so much more.   Catalog Product Overview Related Video Introduction MCP6002 Features MCP6002 Pinout MCP6002 Applications MCP6002 Design Aids MCP6002 Typical Application MCP6002 CAD Models MCP6002 Test Circuit Diagram MCP6002 Package MCP6002 Specification MCP6002 Manufacturer MCP6002 Datasheet Using Warnings MCP6002 FAQ   Related Video Introduction   Video: Electronic Basics #21: Op Amp (Operational Amplifier)   MCP6002 Video Description: In this episode of Electronic Basics I will explain the three golden rules when working with Op Amps and how to use them in order to understand and build all kind of Op Amp circuits. The main focus will be the noninverting and inverting amplifier and the comparator circuit.   MCP6002 Features Available in 5-Lead SC-70 and 5-Lead SOT-23 PackagesGain Bandwidth Product: 1 MHz (typical)Rail-to-Rail Input/OutputSupply Voltage: 1.8V to 6.0VSupply Current: IQ = 100 µA (typical)Phase Margin: 90° (typical)Temperature Range: - Industrial: -40°C to +85°C - Extended: -40°C to +125°C Available in Single, Dual and Quad Packages   MCP6002 Pinout The following figure is the diagram of MCP6002 pinout.   MCP6002 Pinout   MCP6002 Applications AutomotivePortable EquipmentPhotodiode AmplifierAnalog FiltersNotebooks and PDAsBattery-Powered Systems   MCP6002 Design Aids SPICE Macro ModelsFilterLab® SoftwareMindi™ Circuit Designer and Analog SimulatorMicrochip Advanced Part Selector (MAPS)Analog Demonstration and Evaluation BoardsApplication Notes   MCP6002 Typical Application The following is the typical application of MCP6002.   Noninverting Amplifier   MCP6002 CAD Models The followings are MCP6002 Symbol, Footprint, and 3D Model.   MCP6002 Symbol   MCP6002 Footprint   MCP6002 3D Model   MCP6002 Test Circuit Diagram The circuit used for most DC and AC tests is shown in the following picture.   AC and DC Test Circuit for Most Specifications   MCP6002 Package The following diagram shows the MCP6002 package.   MCP6002 Package   MCP6002 Specification Aol (dB)112CMRR Min (dB)76GBWP (kHz)1000Ib (pA)1Input Voltage Noise Density (nV/rt(Hz))28Iq Max (uA)170Iq Typical (µA)100Isc (mA)23Operating Voltage Max. (V)6Operating Voltage Min. (V)1.8PM (deg)90PSRR Min (dB)86# Per Package2Rail-to-RailIn/OutSlew Rate (V/µs)0.6Unity Gain StableTRUEDelta Vos/ Delta Ta (uV/°C)2VOS Max. (uV)4500   MCP6002 Manufacturer Microchip Technology Inc. is a leading provider of microcontroller, mixed-signal, analog and Flash-IP solutions, providing low-risk product development, lower total system cost and faster time to market for thousands of diverse customer applications worldwide. Headquartered in Chandler, Arizona, Microchip offers outstanding technical support along with dependable delivery and quality.   MCP6002 Datasheet You can download MCP6002 datasheet from the link given below: MCP6002 Datasheet   Using Warnings Note: Please check their parameters and pin configuration before replacing them in your circuit.   MCP6002 FAQ What is op amp used for? In the most basic circuit, op-amps are used as voltage amplifiers, which can be broadly divided into noninverting and inverting amplifiers. Voltage followers (also simply called buffers) are a type of commonly used noninverting amplifiers. Op-amps are also used as differential amplifiers, integrator circuits, etc.   What is the difference between amplifiers and op-amps? Amplifiers can be either electronic or mechanical in common definition whereas operational amplifiers are electronic amplifiers. Amplifiers, in general, have a limited capability of amplifying DC signals but all op-amps are capable of amplifying DC signals.   Why op-amps are better than transistors? An Op Amp is often a much better quality amplifier using discrete components and most wide variety of application then transistor. In comparison with transistor it is building block, need to bias it and put it into a gain configuration. A single transistor can not give you differential gain.

Catalog Product Overview STM32F411CEU6 Related Video Introduction STM32F411CEU6 CAD Models STM32F411CEU6 Pin Configuration STM32F411CEU6 Block Diagram STM32F411CEU6 Features STM32F411CEU6 Applications STM32F411CEU6 Datasheet STM32F411CEU6 Specifications STM32F411CEU6 Manufacturer Using Warning STM32F411CEU6 FAQ   Product Overview The STM32F411XC/XE devices are based on the high-performance Arm® Cortex® -M4 32-bit RISC core operating at a frequency of up to 100 MHz. The Cortex®-M4 core features a Floating point unit (FPU) single precision which supports all Arm single-precision data processing instructions and data types. It also implements a full set of DSP instructions and a memory protection unit (MPU) which enhances application security.   The STM32F411xC/xE belongs to the STM32 Dynamic Efficiency™ product line (with products combining power efficiency, performance and integration) while adding a new innovative feature called Batch Acquisition Mode (BAM) allowing to save even more power consumption during data batching. The STM32F411xC/xE incorporate high-speed embedded memories (up to 512 Kbytes of Flash memory, 128 Kbytes of SRAM), and an extensive range of enhanced I/Os and peripherals connected to two APB buses, two AHB bus and a 32-bit multi-AHB bus matrix. All devices offer one 12-bit ADC, a low-power RTC, six general-purpose 16-bit timers including one PWM timer for motor control, two general-purpose 32-bit timers. They also feature standard and advanced communication interfaces.   STM32F411CEU6 Related Video Introduction STM32F411CEU6 Video Description: Some viewers wrote that they could not install sensors and modules. Please watch this video for installation.   STM32F411CEU6 CAD Models Figure: STM32F411CEU6 PCB Symbol       Figure: STM32F411CEU6 Footprint       Figure: STM32F411CEU6 3D Models   STM32F411CEU6 Pin Configuration Figure: STM32F411CEU6 Pin Configuration   STM32F411CEU6 Block Diagram Figure: STM32F411CEU6 Block Diagram   STM32F411CEU6 Features Dynamic Efficiency Line with BAM (BatchAcquisition Mode) – 1.7 V to 3.6 V power supply – - 40°C to 85/105/125 °C temperature range   Core: Arm® 32-bit Cortex®-M4 CPU with FPU,Adaptive real-time accelerator (ARTAccelerator™) allowing 0-wait state execution from Flash memory, frequency up to 100 MHz, memory protection unit, 125 DMIPS/1.25 DMIPS/MHz (Dhrystone 2.1), and DSP instructions   Memories – Up to 512 Kbytes of Flash memory – 128 Kbytes of SRAM   Clock, reset and supply management – 1.7 V to 3.6 V application supply and I/Os – POR, PDR, PVD and BOR – 4-to-26 MHz crystal oscillator – Internal 16 MHz factory-trimmed RC – 32 kHz oscillator for RTC with calibration – Internal 32 kHz RC with calibration   Power consumption – Run: 100 µA/MHz (peripheral off) – Stop (Flash in Stop mode, fast wakeup time): 42 µA Typ @ 25C; 65 µA max @25 °C – Stop (Flash in Deep power down mode, slow wakeup time): down to 9 µA @ 25 °C; 28 µA max @25 °C – Standby: 1.8 µA @25 °C / 1.7 V without RTC; 11 µA @85 °C @1.7 V – VBAT supply for RTC: 1 µA @25 °C   1×12-bit, 2.4 MSPS A/D converter: up to 16channels   General-purpose DMA: 16-stream DMAcontrollers with FIFOs and burst support   Up to 11 timers: up to six 16-bit, two 32-bittimers up to 100 MHz, each with up to fourIC/OC/PWM or pulse counter and quadrature (incremental) encoder input, two watchdog timers (independent and window) and a SysTick timer   Debug mode – Serial wire debug (SWD) & JTAG interfaces – Cortex®-M4 Embedded Trace Macrocell™   Up to 81 I/O ports with interrupt capability – Up to 78 fast I/Os up to 100 MHz – Up to 77 5 V-tolerant I/Os   Up to 13 communication interfaces – Up to 3 x I2C interfaces (SMBus/PMBus) – Up to 3 USARTs (2 x 12.5 Mbit/s, 1 x 6.25 Mbit/s), ISO 7816 interface, LIN, IrDA, modem control) – Up to 5 SPI/I2Ss (up to 50 Mbit/s, SPI or I2S audio protocol), SPI2 and SPI3 with muxed full-duplex I2S to achieve audio class accuracy via internal audio PLL or external clock – SDIO interface (SD/MMC/eMMC) – Advanced connectivity: USB 2.0 full-speed device/host/OTG controller with on-chip PHY   CRC calculation unit   96-bit unique ID   RTC: subsecond accuracy, hardware calendar   All packages (WLCSP49, LQFP64/100,UFQFPN48, UFBGA100) are ECOPACK®2   STM32F411CEU6 Applications Motor drive and application controlMedical equipmentIndustrial applications: PLC, inverters, circuit breakersPrinters, and scannersAlarm systems, video intercom, and HVACHome audio appliancesMobile phone sensor hub   STM32F411CEU6 Datasheet You can download the datasheet from the link given below: STM32F411CEU6 Datasheet   STM32F411CEU6 Specifications Product AttributeAttribute ValueManufacturer:STMicroelectronicsProduct Category:ARM Microcontrollers - MCUSeries:STM32F411CEMounting Style:SMD/SMTPackage / Case:UFQFPN-48Core:ARM Cortex M4Program Memory Size:512 kBData Bus Width:32 bitADC Resolution:12 bitMaximum Clock Frequency:100 MHzNumber of I/Os:36 I/OData RAM Size:128 kBOperating Supply Voltage:1.7 V to 3.6 VOperating Temperature:-40°C ~ 85°C (TA)Packaging:TrayAnalog Supply Voltage:1.7 V to 3.6 VBrand:STMicroelectronicsData RAM Type:RAMInterface Type:I2C, SPI, USART, USBLength:7 mmMoisture Sensitive:YesNumber of ADC Channels:16 ChannelProcessor Series:STM32F411xEProduct:MCU+FPUProduct Type:ARM Microcontrollers - MCUProgram Memory Type:FlashSubcategory:Microcontrollers - MCUSupply Voltage - Max:3.6 VSupply Voltage - Min:1.7 VTradename:STM32Watchdog Timers:Watchdog TimerWidth:7 mmUnit Weight:0.583678 oz   STM32F411CEU6 Manufacturer STMicroelectronics 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 Warning Note: Please check their parameters and pin configuration before replacing them in your circuit.   STM32F411CEU6 FAQ What is a microcontroller? A microcontroller (MCU for microcontroller unit) is a small computer on a single metal-oxide-semiconductor (MOS) integrated circuit (IC) chip. A microcontroller contains one or more CPUs (processor cores) along with memory and programmable input/output peripherals.   What is the main function of microcontroller? Microcontroller is a compressed micro computer manufactured to control the functions of embedded systems in office machines, robots, home appliances, motor vehicles, and a number of other gadgets. A microcontroller is comprises components like - memory, peripherals and most importantly a processor.   How is a microcontroller made? A microcontroller is a single chip microcomputer made through VLSI fabrication. A microcontroller also called an embedded controller because the microcontroller and its support circuits are often built into, or embedded in, the devices they control.  

CatalogProduct OverviewLF353N Related Video IntroductionLF353N CAD ModelsLF353N Pin ConnectionsLF353N Schematic DiagramLF353N FeaturesLF353N Typical ApplicationLF353N DatasheetLF353N SpecificationsLF353N ManufacturerUsing WarningLF353N FAQ Product OverviewThese circuits are high speed JFET input dual operational amplifiers incorporating well matched, high voltage JFET and bipolar transistors in a monolithic integrated circuit. The devices feature high slew rates, low input bias and offset currents, and low offset voltage temperature coefficient. LF353N Related Video IntroductionLF353N Video Description: In this video you will learn how JFET work as an Amplifier. JFET Amplifier operation is easily explained by Dr Mayur Gondalia. There are three configurations of JFET Amplifier:Common Source JFET Amplifier ConfigurationCommon Gate JFET Amplifier ConfigurationCommon Drain JFET Amplifier Configuration In this video very popular common source JFET amplifier configuration is explained in details. LF353N CAD ModelsFigure: LF353N PCB Symbol   Figure: LF353N Footprint   Figure: LF353N 3D Models LF353N Pin ConnectionsFigure: LF353N Pin Connections 1 - Output12 - Inverting input 13 - Non-inverting input 14 - VCC-5 - Non-inverting input 26 - Inverting input 27 - Output 28 - VCC+ LF353N Schematic DiagramFigure: LF353N Schematic Diagram LF353N Features■ Low power consumption■ Wide common-mode (up to VCC+) and differential voltage range■ Low input bias and offset current■ Output short-circuit protection■ High input impedance JFET input stage■ Internal frequency compensation■ Latch up free operation■ High slew rate 16 V/µs (typical) LF353N Typical ApplicationFigure: Quadruple Oscillator LF353N DatasheetYou can download the datasheet from the link given below:LF353N Datasheet LF353N SpecificationsTypeDescriptionCategoryIntegrated Circuits (ICs)Linear - Amplifiers - Instrumentation, OP Amps, Buffer AmpsPart StatusObsoleteAmplifier TypeJ-FETNumber of Circuits2Slew Rate16V/µsGain Bandwidth Product4 MHzCurrent - Input Bias20 pAVoltage - Input Offset3 mVCurrent - Supply1.4mA (x2 Channels)Current - Output / Channel40 mAVoltage - Span (Min)6 VVoltage - Span (Max)36 VOperating Temperature0°C ~ 70°CMounting TypeThrough HolePackage / Case8-DIP (0.300", 7.62mm)Supplier Device Package8-Mini DIP LF353N 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. LF353N FAQWhat is JFET input?The JFET-input and CMOS amplifiers' inputs are connected with the gates of the input differential pair transistors, which causes very small bias currents in the range of few picoamperes. Current-sensing applications measure the voltage drop caused by current flowing through a shunt resistor. How do JFETs work?A JFET is a three terminal semiconductor device in which current conduction is by one type of carrier i.e. electrons or holes. The current conduction is controlled by means of an electric field between the gate and the conducting channel of the device. The JFET has high input impedance and low noise level. What does a FET amp do?A FET amplifier is an amplifier that uses one or more field-effect transistors (FETs). The most common type of FET amplifier is the MOSFET amplifier, which uses metal–oxide–semiconductor FETs (MOSFETs). The main advantage of a FET used for amplification is that it has very high input impedance and low output impedance.