The Kynix Components

CatalogProduct OverviewFPF2700MX CAD ModelsFPF2700MX Pin ConfigurationFPF2700MX Block DiagramFPF2700MX FeaturesFPF2700MX ApplicationsFPF2700MX Application DiagramFPF2700MX DatasheetFPF2700MX SpecificationsFPF2700MX ManufacturerUsing WarningFPF2700MX FAQ Product OverviewThe AccuPower™FPF270X series is a family of current limit load switches that provide full protection to systems and loads from excess current conditions. Minimum current limit is adjustable from 0.4A to 2.0A. The FPF270X contains a slew-rate-controlled N-channel MOSFET and slew-rated turn-on to prevent power bus disturbances from being caused by “hot plugging” loads or momentary excess load demands. The input voltage range is 2.8V to 36V. Loads can be activated or deactivated with a low-voltage logic-compatible ON pin. Fault conditions can be monitored using the error flag pin and/or the power-good pin.  Each member of the FPF270X family serves a category of load-fault response. All devices clamp the load current so that it cannot exceed an externally programmed current level. An over temperature feature provides further device protection in case of excessive levels of power dissipation. FPF2700 responds to an overload condition that lasts longer than a fixed blanking period by turning off the load, followed by a retry after the auto-restart time.  FPF2701 responds to an overload condition that lasts longer than a fixed blanking period by latching off the load. The load remains off unless either the ON pin is toggled or the input voltage cycles through UVLO.  FPF2702 is intended to be used with external fault management. Like the FPF2700 and FPF2701, it sets the fault signal pin LOW when it activates current clamping. This device is intended for applications where external fault management coordinates the overload response with the FPF2702.  The FPF270X is available in a space-saving, Lead and Halogen free, 8-lead, MLP 3x3mmand SO8 packages. FPF2700MX CAD ModelsFigure: FPF2700MX PCB Symbol  Figure: FPF2700MX Footprint  Figure: FPF2700MX 3D Models FPF2700MX Pin ConfigurationFigure: FPF2700MX Pin Configuration FPF2700MX Block DiagramFigure: FPF2700MX Block DiagramFPF2700MX Features8V to 36V Input Voltage Range Typical RDS(ON)=88mW4A to 2A Adjustable Current Limit (Min.)Slew Rate Controlled ESD Protected, above 2000V HBMThermal ShutdownActive LOWEnableUVLO ProtectionPower-Good Output FPF2700MX ApplicationsMotor DrivesDigital CamerasConsumer ElectronicsIndustrialComputingHard Disk Drives Telecom Equipment FPF2700MX Application DiagramFigure: FPF2700MX Typical Application FPF2700MX DatasheetYou can download the datasheet from the link given below:FPF2700MX Datasheet FPF2700MX SpecificationsProduct AttributeAttribute ValueManufacturer:onsemiProduct Category:Power Switch ICs - Power DistributionType:Load SwitchNumber of Outputs:1 OutputCurrent Limit:0.4 A to 2 AOn Resistance - Max:140 mOhmsOn Time - Max:2.7 msOff Time - Max:100 usOperating Supply Voltage:2.8 V to 36 VOperating Temperature:-40°C ~ 85°C (TA)Mounting Style:SMD/SMTPackage / Case:SOIC-8Series:FPF2700Brand:onsemi / FairchildPd - Power Dissipation:1.25 WProduct Type:Power Switch ICs - Power DistributionSubcategory:Switch ICsSupply Voltage - Max:36 VSupply Voltage - Min:2.8 VUnit Weight:0.008127 oz FPF2700MX 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. FPF2700MX 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?The core of a load switch is the pass transistor that is often a MOSFET to pass the power supply to the load to be controlled. The load switch is used to turn on/off the loads. Therefore, its performance is determined by the two distinct periods, the ON time and OFF time. Is a switch a load in a circuit?An electric switch is a device that interrupts the electron flow in a circuit. Circuits consist of a source of power and load. A load is a power-powered device. The function of an electric switch is to regulate the current between the load and source of power. 

Product OverviewThe STM32F103VBT6 is a 32-bit medium-density performance line Microcontroller Unit offers two 12-bit ADCs and 3 general purpose 16-bit timers plus one PWM timer, as well as standard and advanced communication interfaces up to two I²Cs and SPIs, three USARTs, an USB and a CAN. It incorporates the high performance ARM® Cortex®-M3 32bit RISC core operating at a 72MHz frequency, high-speed embedded memories and an extensive range of enhanced I/Os and peripherals connected to two APB buses. The 100-pin general-purpose microcontroller unit (MCU) feature 128kB flash memory. This blog will introduce STM32F103VBT6 systematically from its features, pinout to its specifications, applications, also including STM32F103VBT6 datasheet and so much more. CatalogProduct OverviewSTM32F103VBT6 FeaturesSTM32F103VBT6 PinoutSTM32F103VBT6 ApplicationsSTM32F103VBT6 CAD ModelsSTM32F103VBT6 Block DiagramSTM32F103VBT6 Circuit DiagramSTM32F103VBT6 PackageSTM32F103VBT6 SpecificationSTM32F103VBT6 ManufacturerSTM32F103VBT6 DatasheetUsing WarningsSTM32F103VBT6 FAQ STM32F103VBT6 FeaturesPOR, PDR and programmable voltage detectorPLL for CPU clockLow power - Sleep, stop and standby modesVBAT supply for RTC and backup registersDual-sample and hold capabilityDebug mode - Serial wire debug (SWD) and JTAG interfaces2 Watchdog timersSysTick timer - 24-bit down counterCRC calculation unit, 96-bit unique ID STM32F103VBT6 PinoutThe following figure is the diagram of STM32F103VBT6 pinout. STM32F103VBT6 Pinout STM32F103VBT6 ApplicationsThe STM32F103xx medium-density performance line microcontroller family are suitable for a wide range of applications such as motor drives, application control, medical and handheld equipment, PC and gaming peripherals, GPS platforms, industrial applications, PLCs, inverters, printers, scanners, alarm systems, video intercoms, and HVACs. STM32F103VBT6 CAD ModelsThe followings are STM32F103VBT6 Symbol, Footprint, and 3D Model. STM32F103VBT6 Symbol STM32F103VBT6 Footprint STM32F103VBT6 3D Model STM32F103VBT6 Block DiagramThe following figure shows the block diagram of STM32F103VBT6. STM32F103VBT6 Block Diagram STM32F103VBT6 Circuit DiagramThe following is the the typical application with a 32.768 kHz crystal . STM32F103VBT6 Circuit Diagram STM32F103VBT6 PackageThe following diagram shows the STM32F103VBT6 package. STM32F103VBT6 Package STM32F103VBT6 SpecificationProduct AttributeAttribute ValueFamily NameSTM32FPackage TypeLQFPMounting TypeSurface MountPin Count100Device CoreARM Cortex M3Data Bus Width32bitProgram Memory Size128 kBMaximum Frequency72MHzRAM Size20 kBUSB Channels1 x DeviceNumber of PWM Units1 x 16 bitNumber of SPI Channels2Typical Operating Supply Voltage2 → 3.6 VNumber of UART Channels0Number of Ethernet Channels0Instruction Set ArchitectureRISCNumber of CAN Channels1Number of ADC Units2Number of Timers3Number of I2C Channels2Number of PCI Channels0Program Memory TypeFlashDimensions14.2 x 14.2 x 1.45mmPulse Width Modulation1 (16 bit) (Motor Control)Maximum Number of Ethernet Channels0Timers3 x 16 bitNumber of USART Channels3Number of LIN Channels0Height1.45mmTimer Resolution16bitMinimum Operating Temperature-40 °CWidth14.2mmADCs16 x 12 bitLength14.2mmMaximum Operating Temperature+85 °C STM32F103VBT6 ManufacturerSTMicroelectronics is a global independent semiconductor company and a leader in developing and delivering semiconductor solutions across the spectrum of microelectronics applications. An unrivaled combination of silicon and system expertise, manufacturing strength, Intellectual Property (IP) portfolio, and strategic partners positions, STMicroelectronics is at the forefront of System-on-Chip (SoC) technology and its products play a key role in enabling today's convergence trends. STM32F103VBT6 DatasheetYou can download STM32F103VBT6 datasheet from the link given below:STM32F103VBT6 Datasheet Using WarningsNote: Please check their parameters and pin configuration before replacing them in your circuit. STM32F103VBT6 FAQWhat is ARM STM?The Arm CoreSight System Trace Macrocell (STM) is a trace source that enables real-time instrumentation of software with no impact on system behavior or performance. What is a microcontroller used for?In the office, microcontrollers are used in computer keyboards, monitors, printers, copiers, fax machines, and telephone systems to name a few. In your home, microcontrollers are used in microwave ovens, washers and dryers, security systems, lawn sprinkler station controllers, and music/video entertainment components. What are examples of microcontroller?The examples of 8-bit microcontrollers are Intel 8031/8051, PIC1x, and Motorola MC68HC11 families. The 16-bit microcontroller performs greater precision and performance as compared to the 8-bit. Where are microcontrollers used in everyday life?Devices used in the kitchen and around the house such as refrigerators, TVs, radios, washing machines, dishwashers and even humidifiers frequently use microcontrollers. Any electronic consumer product that has a key entry for operation has a microcontroller inside. All electronic watches have microcontrollers. What is difference between microprocessor and microcontroller?Microprocessor consists of only a Central Processing Unit, whereas Micro Controller contains a CPU, Memory, I/O all integrated into one chip. The microprocessor uses an external bus to interface to RAM, ROM, and other peripherals, on the other hand, Microcontroller uses an internal controlling bus.

CatalogDescriptionFunctional DiagramAssembly DiagramOutline DrawingFeaturesTypical ApplicationsMounting & Bonding Techniques for Millimeterwave GaAs MMICsHandling PrecautionsMountingWire BondingDatasheetSpecificationsManufacturerUsing WarningFAQDescriptionThe HMC462 is a GaAs MMIC pHEMT Low Noise Distributed Amplifier which operates between 2 and 20 GHz. The amplifier provides 15 dB of small signal gain, 2.5 dB noise figure, and up to +15.5 dBm of output power at 1dB compression. Gain flatness is excellent at ±0.3 dB from 8 - 14 GHz making the HMC462 ideal for EW, ECM, and Radar applications. The HMC462 requires a single supply of +5V @ 63 mA and is the self biased version of the HMC463. The wideband amplifier I/Os are internally matched to 50 Ohms facilitating integration into Multi-Chip Modules (MCMs). All data is measured with the chip in a 50 Ohm test fixture connected via 0.025 mm (1 mil) diameter wire bonds of 0.31 mm (12 mils) length. Functional Diagram Figure: Functional Diagram Assembly Diagram Figure: Assembly Diagram Outline Drawing Figure: Outline Drawing FeaturesNoise Figure: 2 dBGain: 15 dBP1dB +15.5 dBmSelf-Biased: +5V @ 63 mA50 Ohm Matched Input/OutputDie Size: 3.0 x 1.3 x 0.1 mm Typical ApplicationsThe HMC462 is ideal for:Test InstrumentationMicrowave Radio & VSATMilitary & SpaceTelecom InfrastructureFiber Optics Mounting & Bonding Techniques for Millimeterwave GaAs MMICs The die should be attached directly to the ground plane eutectically or with conductive epoxy (see HMC general Handling, Mounting, Bonding Note). 50 Ohm Microstrip transmission lines on 0.127mm (5 mil) thick alumina thin film substrates are recommended for bringing RF to and from the chip. If 0.254mm (10 mil) thick alumina thin film substrates must be used, the die should be raised 0.150mm (6 mils) so that the surface of the die is coplanar with the surface of the substrate. One way to accomplish this is to attach the 0.102mm (4 mil) thick die to a 0.150mm (6 mil) thick molybdenum heat spreader (moly-tab) which is then attached to the ground plane. Microstrip substrates should be located as close to the die as possible in order to minimize bond wire length. Typical die-to-substrate spacing is 0.076mm to 0.152 mm (3 to 6 mils). Handling Precautions Follow these precautions to avoid permanent damage. Storage: All bare die are placed in either Waffle or Gel based ESD protective containers, and then sealed in an ESD protective bag for shipment. Once the sealed ESD protective bag has been opened, all die should be stored in a dry nitrogen environment. Cleanliness: Handle the chips in a clean environment. DO NOT attempt to clean the chip using liquid cleaning systems. Static Sensitivity: Follow ESD precautions to protect against > ± 250V ESD strikes. Transients: Suppress instrument and bias supply transients while bias is applied. Use shielded signal and bias cables to minimize inductive pickup. General Handling: Handle the chip along the edges with a vacuum collet or with a sharp pair of bent tweezers. The surface of the chip may have fragile air bridges and should not be touched with vacuum collet, tweezers, or fingers. Mounting The chip is back-metallized and can be die mounted with AuSn eutectic preforms or with electrically conductive epoxy. The mounting surface should be clean and flat. Eutectic Die Attach: A 80/20 gold tin preform is recommended with a work surface temperature of 255 ℃ and a tool temperature of 265 ℃. When hot 90/10 nitrogen/hydrogen gas is applied, tool tip temperature should be 290 ℃. DO NOT expose the chip to a temperature greater than 320 ℃ for more than 20 seconds. No more than 3 seconds of scrubbing should be required for attachment. Epoxy Die Attach: Apply a minimum amount of epoxy to the mounting surface so that a thin epoxy fillet is observed around the perimeter of the chip once it is placed into position. Cure epoxy per the manufacturer’s schedule. Wire Bonding Ball or wedge bond with 0.025mm (1 mil) diameter pure gold wire. Thermosonic wirebonding with a nominal stage temperature of 150℃ and a ball bonding force of 40 to 50 grams or wedge bonding force of 18 to 22 grams is recommended. Use the minimum level of ultrasonic energy to achieve reliable wirebonds. Wirebonds should be started on the chip and terminated on the package or substrate. All bonds should be as short as possible <0.31mm (12 mils). DatasheetYou can download the datasheet from the link given below:HMC462-Datasheet SpecificationsManufacturer:Analog Devices Inc.Product Category:RF AmplifierMounting Style:SMD/SMTType:Low Noise AmplifiersTechnology:GaAsOperating Frequency:2 GHz to 20 GHzP1dB - Compression Point:15.5 dBmGain:15 dBOperating Supply Voltage:5 VNF - Noise Figure:2 dBOIP3 - Third Order Intercept:26 dBmOperating Supply Current:63 mAMinimum Operating Temperature:- 55 ℃Maximum Operating Temperature:+ 85 ℃Series:HMC462GPackaging:Gel PackBrand:Analog DevicesFrequency Range:2 GHz to 20 GHzInput Return Loss:19 dBNumber of Channels:1 ChannelPd - Power Dissipation:2.2 WProduct Type:RF AmplifierFactory Pack Quantity:25Subcategory:Wireless & RF Integrated CircuitsTest Frequency:8 GHz to 16 GHzUnit Weight:0.035838 oz ManufacturerAnalog 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 WarningNote: Please check their parameters and pin configuration before replacing them in your circuit. FAQWhat does a low noise amplifier do?A low-noise amplifier (LNA) is commonly found in all receivers. Its role is to boost the received signal a sufficient level above the noise floor so that it can be used for additional processing. The noise figure of the LNA therefore directly limits the sensitivity of the receiver. Why low noise amplifier is not kept at the indoor unit?For low noise, the amplifier needs to have a high amplification in its first stage. Therefore JFETs and HEMTs are often used. The LNA boosts the antenna signal to compensate for the feedline losses going from the (outdoor) antenna to the (indoor) receiver. What is the difference between low noise amplifier and power amplifier?Power amplifier is optimized for power gain. It does not have to be differential, for example. Types: audio amplifiers, video amplifiers, buffers, RF, etc. Low-noise amplifier (LNA) is optimized for low input noise, either voltage noise Vn or current noise In. 

Product OverviewThe LD39200 provides 2 A of maximum current with an input voltage range from 1.25 V to 6.0 V, and a typical dropout voltage of 130 mV.It is stable with ceramic capacitors on the output (10 µF).Typical power supply rejection ratio is 70 dB at 1 kHz and starts to roll off at 20 kHz.The enable logic control function puts the LD39200 in shutdown mode, reducing the total current consumption to 10 nA (typ.).Power Good flag is available on a dedicated pin.The device also includes reverse current protection, short-circuit constant current limit and thermal protection.Typical applications are for Telecom infrastructure and consumer. This blog will introduce LD39200DPUR systematically from its features, pinout to its specifications, applications, also including LD39200DPUR datasheet and so much more. CatalogProduct OverviewLD39200DPUR FeaturesLD39200DPUR PinoutLD39200DPUR ApplicationsLD39200DPUR CAD ModelsLD39200DPUR Application SchematicLD39200DPUR Block DiagramLD39200DPUR PackageLD39200DPUR SpecificationLD39200DPUR ManufacturerLD39200DPUR DatasheetUsing WarningsLD39200DPUR FAQ LD39200DPUR FeaturesInput voltage from 1.25 V to 6.0 VUltra low drop: 130 mV (typ.) at 2 A load1 % output accuracy at 25 °C, 2 % in full temperature rangeHigh PSRR: 70 dB at 1 kHzReverse current protection2 A guaranteed output currentAvailable in fixed and adjustable output voltage version from 0.5 V with 100 mV stepPower GoodInternal current and thermal limitOperating junction temperature range: -40 °C to 125 °CDFN6 (3 x 3 mm) and DFN8 (4 x 4 mm) packages LD39200DPUR PinoutThe following figure is the diagram of LD39200DPUR pinout. LD39200DPUR Pinout LD39200DPUR ApplicationsTelecom infrastructureMedium power POL LD39200DPUR CAD ModelsThe followings are LD39200DPUR Symbol, Footprint, and 3D Model. LD39200DPUR Symbol LD39200DPUR Footprint LD39200DPUR 3D Model LD39200DPUR Application SchematicThe following is the LD39200DPUR typical application schematic. LD39200DPUR Application Schematic LD39200DPUR Block DiagramThe following figure shows the block diagram of LD39200DPUR. LD39200DPUR Block Diagram LD39200DPUR PackageThe following diagram shows the LD39200DPUR package. LD39200DPUR Package LD39200DPUR SpecificationAttributeValueBrandSTMicroelectronicsRegulator TypeLow Dropout VoltageMaximum Output Current2 AOutput Voltage0.8 → 4.5 VNumber of Outputs1Line Regulation0.1 %/VAccuracy±3 %Load Regulation0.4 %/AMounting TypeSurface MountPackage TypeDFNQuiescent Current3 mAPin Count8Output TypeAdjustableDimensions4.1 x 4.1 x 0.95 mmHeight0.95 mmWidth4.1 mmMinimum Operating Temperature-40 °CMinimum Input Voltage1.25 VMaximum Operating Temperature+125 °CLength4.1 mmMaximum Input Voltage6 V LD39200DPUR ManufacturerSTMicroelectronics is a global independent semiconductor company and a leader in developing and delivering semiconductor solutions across the spectrum of microelectronics applications. An unrivaled combination of silicon and system expertise, manufacturing strength, Intellectual Property (IP) portfolio, and strategic partners positions, STMicroelectronics is at the forefront of System-on-Chip (SoC) technology and its products play a key role in enabling today's convergence trends. LD39200DPUR DatasheetYou can download LD39200DPUR datasheet from the link given below:LD39200DPUR Datasheet Using WarningsNote: Please check their parameters and pin configuration before replacing them in your circuit. LD39200DPUR FAQWhat are LDO voltage regulators?An LDO regulator is a linear regulator that can operate at a very low potential difference between the input and output voltage. A linear regulator is a type of power supply IC that can output a steady voltage from an input voltage and is used in a variety of electronic devices. How does a LDO regulator work?The working principle of LDO regulator is just like that of an ordinary linear voltage regulator. The essential components of an LDO voltage regulator are a reference voltage source, error amplifier and series pass element (BJT or MOSFET). What is the use of LDO regulator?LDO regulators are used to derive lower output voltages from a main supply or battery. The output voltage is ideally stable with line and load variations, immune to changes in ambient temperature, and stable over time.

Catalog Function Description FT232RQ Related Video Introduction FT232RQ CAD Models FT232RQ Pinout FT232RQ Block Diagram FT232RQ Schematic Symbol FT232RQ Features FT232RQ Applications FT232RQ Datasheet FT232RQ Specifications FT232RQ Manufacturer Using Warning FT232RQ FAQ Function Description The FT232R is a USB to serial UART interface device which simplifies USB to serial designs and reduces external component count by fully integrating an external EEPROM, USB termination resistors and an integrated clock circuit which requires no external crystal, into the device. It has been designed to operate efficiently with a USB host controller by using as little as possible of the total USB bandwidth available.   FT232RQ Related Video Introduction FT232RQ Video Description: Add USB to your embedded design or project easily with FT232 based solutions from FTDI Chip. Watch Gavin Moore, Customer Engineering Support Team Leader at FTDI Chip show you how easy it is to convert UART to USB on your board with FT232 based cables, modules and ICs.   FT232RQ CAD Models   Figure: PCB Symbol     Figure: Footprint     Figure: 3D Model   FT232RQ Pinout   Figure: FT232RQ Pinout FT232RQ Block Diagram   Figure: FT232RQ Block Diagram   FT232RQ Schematic Symbol   Figure: FT232RQ Schematic Symbol   FT232RQ Features Single chip USB to asynchronous serial data transfer interface.Entire USB protocol handled on the chip. No USB specific firmware programming required.Fully integrated 1024 bit EEPROM storing device descriptors and CBUS I/O configuration.Fully integrated USB termination resistors.Fully integrated clock generation with no external crystal required plus optional clock output selection enabling a glue-less interface to external MCU or FPGA.Data transfer rates from 300 baud to 3 Mbaud (RS422, RS485, RS232 ) at TTL levels. 128 byte receive buffer and 256 byte transmit buffer utilising buffer smoothing technology to allow for high data throughput.FTDI‟s royalty-free Virtual Com Port (VCP) and Direct (D2XX) drivers eliminate the requirement for USB driver development in most cases.Unique USB FTDIChip-ID feature.Configurable CBUS I/O pins.Transmit and receive LED drive signals.UART interface support for 7 or 8 data bits, 1 or 2 stop bits and odd / even / mark / space / no parityFIFO receive and transmit buffers for high data throughput.Synchronous and asynchronous bit bang interface options with RD# and WR# strobes.Device supplied pre-programmed with unique USB serial number.Supports bus powered, self powered and high-power bus powered USB configurations.Integrated +3.3V level converter for USB I/O.Integrated level converter on UART and CBUS for interfacing to between +1.8V and +5V logic.True 5V/3.3V/2.8V/1.8V CMOS drive output and TTL input.Configurable I/O pin output drive strength.Integrated power-on-reset circuit.Fully integrated AVCC supply filtering - no external filtering required.UART signal inversion option.+3.3V (using external oscillator) to +5.25V (internal oscillator) Single Supply Operation.Low operating and USB suspend current.Low USB bandwidth consumption.UHCI/OHCI/EHCI host controller compatible.USB 2.0 Full Speed compatible.-40°C to 85°C extended operating temperature range.Available in compact Pb-free 28 Pin SSOP and QFN-32 packages (both RoHS compliant).   FT232RQ Applications USB to RS232/RS422/RS485 ConvertersUpgrading Legacy Peripherals to USBCellular and Cordless Phone USB data transfer cables and interfacesInterfacing MCU/PLD/FPGA based designs to USBUSB Audio and Low Bandwidth Video data transferPDA to USB data transferUSB Smart Card ReadersUSB InstrumentationUSB Industrial ControlUSB MP3 Player InterfaceUSB FLASH Card Reader and WritersSet Top Box PC - USB interfaceUSB Digital Camera InterfaceUSB Hardware ModemsUSB Wireless ModemsUSB Bar Code ReadersUSB Software and Hardware Encryption Dongles   FT232RQ Datasheet You can download the datasheet from the link given below: FT232RQ-Datasheet   FT232RQ Specifications Manufacturer:FTDIProduct Category:USB Interface ICSeries:FT232Product:USB ControllersType:Bridge, USB to UARTMounting Style:SMD/SMTPackage / Case:QFN-EP-32Standard:USB 2.0Speed:High Speed (HS), Full Speed (FS)Data Rate:12 Mb/sSupply Voltage - Min:3.3 VSupply Voltage - Max:5.25 VOperating Supply Current:25 mAMinimum Operating Temperature:- 40 ℃Maximum Operating Temperature:+ 85 ℃Packaging:ReelPackaging:Cut TapePackaging:MouseReelBrand:FTDIInterface Type:UARTMoisture Sensitive:YesOperating Supply Voltage:1.8 V to 5.25 VProduct Type:USB Interface ICFactory Pack Quantity:6000Subcategory:Interface ICsTradename:R-CHIPUnit Weight:0.005997 oz   FT232RQ Manufacturer Future Technology Devices International Limited, commonly known by its acronym FTDI, is a Scottish privately held semiconductor device company, specialising in Universal Serial Bus (USB) technology.It develops, manufactures, and supports devices and their related cables and software drivers for converting RS-232 or TTL serial transmissions to and from USB signals, in order to provide support for legacy devices with modern computers.The company also provides application-specific integrated circuit (ASIC) design services, and consultancy services for product design, specifically in the realm of electronic devices.   Using Warning Note: Please check their parameters and pin configuration before replacing them in your circuit.   FT232RQ FAQ What is FT232R? The FT232R is a USB to serial UART interface with optional clock generator output, and the new FTDIChip-ID™ security dongle feature. ... USB to serial designs using the FT232R have been further simplified by fully integrating the external EEPROM, clock circuit and USB resistors onto the device.   Can USB be used with UART? The USB to UART Bridge Controller (CY7C64225) is a fully integrated USB to UART controller that provides USB connectivity to devices with a UART interface. The device includes a USB 2.0 Full-Speed Controller, Voltage Regulator and internal EEPROM in a 28-pin SSOP package.   What is FT232R USB UART driver? The FT232R is a USB to serial UART interface with optional clock generator output, and the new FTDIChip-ID™ security dongle feature. ... USB to serial designs using the FT232R have been further simplified by fully integrating the external EEPROM, clock circuit and USB resistors onto the device.   What is USB and UART? A USB to UART bridge adds a serial port to your computer. To communicate over the UART, you have to read and write to the correct serial port. If you can't find the correct port, you probably have trouble with drivers or the USB connection to your bridge.   What is a UART used for? A UART is usually an individual (or part of an) integrated circuit (IC) used for serial communications over a computer or peripheral device serial port. One or more UART peripherals are commonly integrated in microcontroller chips. Specialised UARTs are used for automobiles, smart cards and SIMs.  

Product OverviewThe STM32F105xx and STM32F107xx connectivity line family incorporates the high-performance ARM Cortex -M3 32-bit RISC core operating at a 72 MHz frequency, high-speed embedded memories (Flash memory up to 256 Kbytes and SRAM 64 Kbytes), and an extensive range of enhanced I/Os and peripherals connected to two APB buses. All devices offer two 12-bit ADCs, four general-purpose 16-bit timers plus a PWM timer, as well as standard and advanced communication interfaces: up to two I²Cs, three SPIs, two I²Ss, five USARTs, an USB OTG FS and two CANs. Ethernet is available on the STM32F107xx only.The STM32F105xx and STM32F107xx connectivity line family operates in the –40 to +105 °C temperature range, from a 2.0 to 3.6 V power supply. This blog will introduce STM32F105RBT6 systematically from its features, pinout to its specifications, applications, also including STM32F105RBT6 datasheet and so much more. CatalogProduct OverviewSTM32F105RBT6 FeaturesSTM32F105RBT6 PinoutSTM32F105RBT6 ApplicationsSTM32F105RBT6 CAD ModelsSTM32F105RBT6 Block DiagramSTM32F105RBT6 Circuit DiagramSTM32F105RBT6 PackageSTM32F105RBT6 SpecificationSTM32F105RBT6 ManufacturerSTM32F105RBT6 Datasheet&Reference ManualUsing WarningsSTM32F105RBT6 FAQ STM32F105RBT6 FeaturesClock, reset and supply management (internal (8MHz factory-trimmed RC, 40kHz RC with calibration))Sleep, stop and standby modes2 x 12bit, 1µs ADC (up to 16channels) and 2 x 12bit D/A converters12channel DMA controllerSupported peripherals: timers, ADCs, DAC, I2Ss, SPIs, I2Cs and USARTsUp to 80 fast I/O ports and serial wire debug (SWD) & JTAG interfacesUp to 10 timers with pinout remap capabilityUp to 14 communication interfaces with pinout remap capabilityCRC calculation unit, 96bit unique IDSTM32F105RBT6 PinoutThe following figure is the diagram of STM32F105RBT6 pinout. STM32F105RBT6 Pinout STM32F105RBT6 ApplicationsThe STM32F105xx and STM32F107xx connectivity line microcontroller family are suitable for a wide range of applications such as motor drives and application control, medical and handheld equipment, industrial applications, PLCs, inverters, printers, and scanners, alarm systems, video intercom, HVAC and home audio equipment. STM32F105RBT6 CAD ModelsThe followings are STM32F105RBT6 Symbol, Footprint, and 3D Model. STM32F105RBT6 Symbol STM32F105RBT6 Footprint STM32F105RBT6 3D Model STM32F105RBT6 Block DiagramThe following figure shows the block diagram of STM32F105RBT6. STM32F105RBT6 Block Diagram STM32F105RBT6 Circuit DiagramThe following is the typical application with an 8 MHz crystal. STM32F105RBT6 Circuit Diagram STM32F105RBT6 PackageThe following diagram shows the STM32F105RBT6 package. STM32F105RBT6 Package STM32F105RBT6 SpecificationProduct AttributeAttribute ValueManufacturer:STMicroelectronicsProduct Category:ARM Microcontrollers - MCUSeries:STM32F105RBMounting Style:SMD/SMTPackage / Case:LQFP-64Program Memory Size:128 kBData Bus Width:32 bitADC Resolution:12 bitMaximum Clock Frequency:72 MHzNumber of I/Os:51 I/OData RAM Size:64 kBOperating Supply Voltage:2 V to 3.6 VMinimum Operating Temperature:- 40 CMaximum Operating Temperature:+ 85 CPackaging:TrayData RAM Type:SRAMHeight:1.4 mmInterface Type:CAN, I2C, SPI, USARTLength:10 mmMoisture Sensitive:YesNumber of ADC Channels:16 ChannelNumber of Timers/Counters:10 TimerProgram Memory Type:FlashFactory Pack Quantity:960Subcategory:Microcontrollers - MCUSupply Voltage - Max:3.6 VSupply Voltage - Min:2 V STM32F105RBT6 ManufacturerSTMicroelectronics is a global independent semiconductor company and a leader in developing and delivering semiconductor solutions across the spectrum of microelectronics applications. An unrivaled combination of silicon and system expertise, manufacturing strength, Intellectual Property (IP) portfolio, and strategic partners positions, STMicroelectronics is at the forefront of System-on-Chip (SoC) technology and its products play a key role in enabling today's convergence trends. STM32F105RBT6 Datasheet&Reference ManualYou can download STM32F105RBT6 datasheet and reference manual from the link given below:STM32F105RBT6 DatasheetSTM32F105RBT6 Reference Manual Using WarningsNote: Please check their parameters and pin configuration before replacing them in your circuit. STM32F105RBT6 FAQWhat is ARM STM?The Arm CoreSight System Trace Macrocell (STM) is a trace source that enables real-time instrumentation of software with no impact on system behavior or performance. What is a microcontroller used for?In the office, microcontrollers are used in computer keyboards, monitors, printers, copiers, fax machines, and telephone systems to name a few. In your home, microcontrollers are used in microwave ovens, washers and dryers, security systems, lawn sprinkler station controllers, and music/video entertainment components. What are examples of microcontroller?The examples of 8-bit microcontrollers are Intel 8031/8051, PIC1x, and Motorola MC68HC11 families. The 16-bit microcontroller performs greater precision and performance as compared to the 8-bit. Where are microcontrollers used in everyday life?Devices used in the kitchen and around the house such as refrigerators, TVs, radios, washing machines, dishwashers and even humidifiers frequently use microcontrollers. Any electronic consumer product that has a key entry for operation has a microcontroller inside. All electronic watches have microcontrollers. What is difference between microprocessor and microcontroller?Microprocessor consists of only a Central Processing Unit, whereas Micro Controller contains a CPU, Memory, I/O all integrated into one chip. The microprocessor uses an external bus to interface to RAM, ROM, and other peripherals, on the other hand, Microcontroller uses an internal controlling bus.