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Integrated Circuits (ICs)

BQ7692003PWR Battery Monitor: Datasheet, Applications [FAQ]

CatalogDescriptionCAD ModelsPin DiagramBlock DiagramFeaturesApplicationsDatasheetSpecificationsManufacturerUsing WarningFAQDescriptionThe BQ769x0 family of robust analog front-end (AFE) devices serves as part of a complete pack monitoring and protection solution for next-generation, high-power systems, such as light electric vehicles, power tools, and uninterruptible power supplies. The BQ769x0 is designed with low power in mind: Subblocks within the IC may be enabled or disabled to control the overall chip current consumption, and a SHIP mode provides a simple way to put the pack into  an ultra-low power state. CAD Models Figure: Symbol  Figure: PCB Footprints  Figure: 3D Models Pin Diagram Figure: Pin Diagram Block Diagram Figure: Block Diagram FeaturesAFE monitoring features– Pure digital interface– Internal ADC measures cell voltage, dietemperature, and external thermistor– A separate, internal ADC measures pack current (coulomb counter)– Directly supports up to three thermistors (103AT)Hardware protection features– Overcurrent in Discharge (OCD)– Short Circuit in Discharge (SCD)– Overvoltage (OV)– Undervoltage (UV)– Secondary protector fault detectionAdditional features– Integrated cell balancing FETs– Charge, discharge low-side NCH FET drivers– Alert interrupt to host microcontroller– 2.5-V or 3.3-V output voltage regulator– No EEPROM programming necessary– High supply voltage absolute maximum (up to 108 V)– Simple I2C compatible interface (CRC option)– Random cell connection tolerant ApplicationsLight electric vehicles (LEV): eBikes, eScooters, pedelec, and pedal-assist bicyclesPower tools and garden toolsBattery backup units (BBUS), energy storage systems (ESS), and uninterruptible power supply (UPS) systemsOther industrial battery packs (≥10S) DatasheetYou can download the datasheet the link given below.BQ7692003PWR-Datasheet SpecificationsTYPEDESCRIPTIONCategoryIntegrated Circuits (ICs)Power Management (PMIC)Battery ManagementMfrTexas InstrumentsPackageTape & Reel (TR)Cut Tape (CT)Digi-ReelProduct StatusActiveFunctionBattery MonitorBattery ChemistryMulti-ChemistryNumber of Cells3 ~ 5Fault ProtectionOver Current, Over/Under Voltage, Short CircuitInterfaceI2COperating Temperature-40℃ ~ 85℃ (TA)Mounting TypeSurface MountPackage / Case20-TSSOP (0.173", 4.40mm Width)Supplier Device Package20-TSSOPBase Product NumberBQ76920 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. FAQWhat does a battery monitor do?A battery monitor measures battery voltage and current flow into & out of a battery bank and uses these measurements to accurately track the amount of charge left in the battery bank. What are the different types of battery monitors?There are two types of battery monitors, shunt-based and voltage-based. The most simple type is the voltage-based monitor and frequently comes standard on most mobile power applications. This type of monitor just measures the real-time voltage of the battery and uses it to estimate its state of charge. What is a battery monitor sensor?Battery Monitor ‪webabcd‬ ‪Utilities & tools‬ Live tile widget to show battery % and time remaining Lock screen widget to show battery % and time remaining. It allows you to easily access your Wifi, Bluetooth, Cellular, Airplane Mode and Location settings. 
Allen On 2025-04-23   2072
Integrated Circuits (ICs)

ADG732BSUZ-REEL Analog Multiplexer: Datasheet, Applications [FAQ]

CatalogDescriptionCAD ModelsPin ConfigurationFunctional Block DiagramsFeaturesApplicationsDatasheetSpecificationsManufacturerUsing WarningFAQDescriptionThe ADG726/ADG732 are monolithic, complementary metal oxide semiconductor (CMOS) 32-channel and dual 16-channel analog multiplexers. The ADG732 switches one of 32 inputs (S1 to S32) to a common output, D, as determined by the 5-bit binary address lines A0, A1, A2, A3, and A4. The ADG726 switches one of 16 inputs as determined by the 4-bit binary address lines A0, A1, A2, and A3. On-chip latches facilitate microprocessor interfacing. The ADG726 may also be configured for differential operation by tying CSA and CSB together. An EN input is used to enable or disable the devices. When disabled, all channels are switched off.PurchaseADG732BSUZ-REELCAD Models Figure: Symbol  Figure: PCB Footprints  Figure: 3D Model Pin Configuration Figure: Pin Configuration Functional Block Diagrams Figure: Functional Block Diagrams Features1.8 V to 5.5 V single-supply operation±2.5 V dual-supply operationOn resistance: 4 Ω at 25°C (+5 V single supply/±2.5 V dual supply)0.5 Ω on-resistance flatness at 25°C (+5 V single supply/ ±2.5 V dual supply)Rail-to-rail operationTransition times: 23 ns typical at 25°CSingle 32-to-1 channel multiplexerDual/differential 16-to-1 channel multiplexerTTL-/CMOS-compatible inputs48-lead TQFP or 48-lead, 7 mm × 7 mm LFCSP ApplicationsOptical applicationsData acquisition systemsCommunication systemsRelay replacementAudio and video switchingBattery-powered systemsMedical instrumentationAutomatic test equipment (ATE) DatasheetYou can download the datasheet the link given below.ADG732BSUZ-REEL-Datasheet SpecificationsTYPEDESCRIPTIONCategoryIntegrated Circuits (ICs)InterfaceAnalog Switches, Multiplexers, DemultiplexersMfrAnalog Devices Inc.PackageTape & Reel (TR)Cut Tape (CT)Digi-ReelProduct StatusActiveMultiplexer/Demultiplexer Circuit1.334027778Number of Circuits1On-State Resistance (Max)5.5OhmVoltage - Supply, Single (V+)1.8V ~ 5.5VVoltage - Supply, Dual (V±)±2.5V-3db Bandwidth18MHzCharge Injection1pCChannel Capacitance (CS(off), CD(off))13pF, 275pFCurrent - Leakage (IS(off)) (Max)250pACrosstalk-72dB @ 1MHzOperating Temperature-40℃ ~ 125℃ (TA)Mounting TypeSurface MountPackage / Case48-TQFPSupplier Device Package48-TQFP (7x7)Base Product NumberADG732 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 is multiplexer used for?Multiplexers can be used to increase the total data transmitted over the network by allowing several connections over a single channel. This increases the efficiency of transmitting various signal types. What are the advantages of multiplexer?The advantage of multiplexing is that we can transmit a large number of signals to a single medium. This channel can be a physical medium like a coaxial, metallic conductor or a wireless link and will have to handle multiple signals at a time. Thus the cost of transmission can be reduced. What is the difference between analog and digital multiplexer?An analog multiplexer can handle both analog as well as digital (on/off) signals, whereas a digital multiplexer can handle digital signals only. Analog multiplexers transfer the analog signal, and as such they may change the signal somewhat because of frequency dependence and because of internal resistance. 
Allen On 2022-10-29   2067
Integrated Circuits (ICs)

LM7171 Feedback Amplifier: Datasheet, Applications, Circuits

The LM7171 is a high speed voltage feedback amplifier that has the slewing characteristic of a current feedback amplifier.CatalogProduct OverviewLM7171 Simplified Schematic DiagramLM7171 Package DimensionsLM7171 FeaturesLM7171 Slew RateComponent Selection and Feedback ResistorLM7171 Product AttributesLM7171 ApplicationsLM7171 Circuit OperationLM7171 Application CircuitsAlternate PartsComponent DatasheetUsing WarningsLM7171 ManufacturerProduct OverviewLM7171 Voltage Feedback AmplifierThe LM7171 is a true voltage feedback amplifier. It can be used in all traditional voltage feedback amplifier configurations. The LM7171 is stable for gains as low as +2 or −1. It provides a very high slew rate at 4100V/µs and a wide unity-gain bandwidth of 200 MHz while consuming only 6.5 mA of supply current. It is ideal for video and high speed signal processing applications such as HDSL and pulse amplifiers. With 100 mA output current, the LM7171 can be used for video distribution, as a transformer driver or as a laser diode driver.Operation on ±15V power supplies allows for large signal swings and provides greater dynamic range and signal-tonoise ratio. The LM7171 offers low SFDR and THD, ideal for ADC/DAC systems. In addition, the LM7171 is specified for ±5V operation for portable applications.The LM7171 is built on National’s advanced VIP™ III (Vertically integrated PNP) complementary bipolar process.LM7171 Simplified Schematic DiagramLM7171 Simplified Schematic DiagramLM7171 Package DimensionsLM7171 Package DimensionsLM7171 Features(Typical Unless Otherwise Noted)• Easy-to-use voltage feedback topology• Very high slew rate: 4100 V/µs• Wide unity-gain bandwidth: 200 MHz• −3 dB frequency @ AV = +2: 220 MHz• Low supply current: 6.5 mA• High open loop gain: 85 dB• High output current: 100 mA• Differential gain and phase: 0.01%, 0.02˚• Specified for ±15V and ±5V operationLM7171 Slew RateThe slew rate of LM7171 is determined by the current available to charge and discharge an internal high impedance node capacitor. This current is the differential input voltage divided by the total degeneration resistor RE. Therefore, the slew rate is proportional to the input voltage level, and the higher slew rates are achievable in the lower gain configurations. A curve of slew rate versus input voltage level is provided in the “Typical Performance Characteristics”.When a very fast large signal pulse is applied to the input of an amplifier, some overshoot or undershoot occurs. By placing an external resistor such as 1 kΩ in series with the input of LM7171, the bandwidth is reduced to help lower the overshoot.Component Selection and Feedback ResistorIt is important in high speed applications to keep all component leads short. For discrete components, choose carbon composition-type resistors and mica-type capacitors. Surface mount components are preferred over discrete components for minimum inductive effect.Large values of feedback resistors can couple with parasitic capacitance and cause undesirable effects such as ringing or oscillation in high speed amplifiers. For LM7171, a feedback resistor of 510Ω gives optimal performance.LM7171 Product AttributesSpecificationsValuesAmplifier TypeVoltage FeedbackGain Bandwidth220 MHzSlew Rate4.1 V/msInput Offset Voltage1 mVInput Bias Current10 uAAmplifiers1Common Mode Rejection Ratio (CMRR)105 dBPower Supply Rejection Ratio (PSRR)90 dBVoltage Gain85 dBInput Voltage Noise Density14 nV/√HzOutput Current per Channel105 mASupply Current8.5 mASingle Supply Voltage Min.5.5 VSingle Supply Voltage Max.36 VDual Supply Voltage Min.2.75 VDual Supply Voltage Max.18 VOperating Temperature Min.-40 °COperating Temperature Max.85 °CPackage TypeSOICPins8Mounting TypeSurface MountMSLLevel-1PackagingTubeLength5 mmWidth4 mmHeight1.5 mmPower Supply TypeDual/SingleReflow Temperature(Max)260 °CLow-BiasNoJESD-30 CodeR-PDSO-G8JESD-609 Codee0Rohs CodeNoRisk Rank5.25Package Description0.150 INCH, SOIC-8LM7171 ApplicationsHDSL and ADSL drivers• Multimedia broadcast systems• Professional video cameras• Video amplifiers• Copiers/scanners/fax• HDTV amplifiers• Pulse amplifiers and peak detectors• CATV/fiber optics signal processingLM7171 Circuit OperationThe class AB input stage in LM7171 is fully symmetrical and has a similar slewing characteristic to the current feedback amplifiers. In the LM7171 Simplified Schematic, Q1 through Q4 form the equivalent of the current feedback input buffer, RE the equivalent of the feedback resistor, and stage A buffers the inverting input. The triple-buffered output stage isolates the gain stage from the load to provide low output impedance.LM7171 Application CircuitsCompensating for Input Capacitance Power Supply Bypassing Fast Instrumentation Amplifier Multivibrator Pulse Width Modulator Video Line DriverAlternate Parts✔️LMV932MA, JL148BZA, LPV358MMX, LM4250CM, CLC400AJ-MLS/NOPB, LM324J/NOPB, LM101AH, LM7171AMWG-QML, LM7372IMA, LF353N✔️LM6171 vs LM7171 vs LM6172Component DatasheetLM7171 PDFUsing WarningsPlease check their parameters and pin configuration before replacing them in your circuit.LM7171 ManufacturerTexas Instruments Inc. (TI) is an American technology company that designs and manufactures semiconductors and various integrated circuits, which it sells to electronics designers and manufacturers globally. Its headquarters are in Dallas, Texas, United States. TI is one of the top ten semiconductor companies worldwide, based on sales volume. Texas Instruments's focus is on developing analog chips and embedded processors, which accounts for more than 80% of their revenue. TI also produces TI digital light processing (DLP) technology and education technology products including calculators, microcontrollers and multi-core processors. To date, TI has more than 43,000 patents worldwide.
kynix On 2022-01-20   2066
Integrated Circuits (ICs)

SN74HC86N Quadruple 2-Input XOR Gates: Datasheet, CAD Models and Features

 CatalogDescriptionCAD ModelsPin ConfigurationFunctional Block DiagramFeaturesApplicationsDatasheetProduct AttributesManufacturerUsing WarningDescriptionThis device contains four independent 2-input XOR gates. Each gate performs the Boolean function Y = A ⊕ B in positive logic. CAD Models Figure: SN74HC86N PCB Symbol  Figure: SN74HC86N Footprint  Figure: SN74HC86N 3D Models Pin Configuration Figure: SN74HC86N Pin Configuration  Functional Block Diagram Figure: SN74HC86N  Functional Block Diagram FeaturesBuffered inputsWide operating voltage range: 2 V to 6 VWide operating temperature range:–40°C to +85°CSupports fanout up to 10 LSTTL loadsSignificant power reduction compared to LSTTL logic ICs Feature Description1.Balanced CMOS Push-Pull OutputsA balanced output allows the device to sink and source similar currents. The drive capability of this device may create fast edges into light loads so routing and load conditions should be considered to prevent ringing. Additionally, the outputs of this device are capable of driving larger currents than the device can sustain without being damaged. It is important for the output power of the device to be limited to avoid damage due to over-current. The electrical and thermal limits defined in the Absolute Maximum Ratings must be followed at all times. The SN74HC86 can drive a load with a total capacitance less than or equal to the maximum load listed in the Switching Characteristics - 74 connected to a high-impedance CMOS input while still meeting all of the datasheet specifications. Larger capacitive loads can be applied, however it is not recommended to exceed the provided load value. If larger capacitive loads are required, it is recommended to add a series resistor between the output and the capacitor to limit output current to the values given in the Absolute Maximum Ratings. 2.Standard CMOS InputsStandard CMOS inputs are high impedance and are typically modeled as a resistor from the input to ground in parallel with the input capacitance given in the Electrical Characteristics - 74. The worst case resistance is calculated with the maximum input voltage, given in the Absolute Maximum Ratings, and the maximum input leakage current, given in the Electrical Characteristics - 74, using ohm's law (R = V ÷ I). Signals applied to the inputs need to have fast edge rates, as defined by the input transition time in the Recommended Operating Conditions to avoid excessive current consumption and oscillations. If a slow or noisy input signal is required, a device with a Schmitt-trigger input should be used to condition the input signal prior to the standard CMOS input ApplicationsDetect phase differences in input signalsCreate a selectable inverter / buffer  DatasheetSN74HC86N-Datasheet Product AttributesPhysicalCase/PackagePDIPContact PlatingGoldMountThrough HoleNumber of Pins14Weight927.99329 mg TechnicalHigh Level Output Current-5.2 mALogic FunctionXORLow Level Output Current5.2 mAMax Operating Temperature85 ℃Max Output Current5.2 mAMax Supply Voltage6 VMin Operating Temperature-40 ℃Min Supply Voltage2 VNumber of Bits4Number of Channels4Number of Circuits4Number of Elements4Number of Gates4Number of Input Lines2Number of Inputs2Number of Output Lines1Number of Outputs1Operating Supply Voltage5 VOutput Current5.2 mAPropagation Delay21 nsQuiescent Current2 μASchedule B8542390000Schmitt Trigger InputNoTurn-On Delay Time100 ns DimensionsHeight5.08 mmLength19.3 mmThickness3.9 mmWidth6.35 mm ComplianceLead FreeLead FreeRadiation HardeningNoREACH SVHCNo SVHCRoHSCompliant ManufacturerTexas Instruments Incorporated (TI) is a global semiconductor design and manufacturing company that develops analog ICs and embedded processors. By employing the world's brightest minds, TI creates innovations that shape the future of technology. TI is helping more than 100,000 customers transform the future, today. Using WarningNote: Please check their parameters and pin configuration before replacing them in your circuit.
kynix On 2022-04-12   2055
Integrated Circuits (ICs)

AT89C51 8-bit Microcontroller: Pinout, 8051 VS AVR Microcontrollers, and Datasheet

Overview of AT89C51Video related to AT89C51AT89C51 PinoutAT89C51 CAD ModelAT89C51 Block DiagramAT89C51 FeaturesAT89C51 EquivalentsHow to Program the AT89C51 Microcontroller?AT89C51 Programming the FlashRightly choose the Atmel Microcontroller?Difference between 8051 and AVR MicrocontrollersAT89C51 ApplicationsAT89C51 DatasheetAT89C51 Packaging informationAT89C51 FAQ  Overview of AT89C51A CMOS 8-bit microcomputer with low power consumption and high performance, the AT89C51 has 4K bytes of programmable and erasable Flash read-only memory (PEROM). The product is made with high-density nonvolatile memory technology from Atmel, and its pinout and instruction set are compliant with the industry standard MCS-51. The program memory can be updated in-system or using a typical nonvolatile memory programmer thanks to the on-chip Flash. The Atmel AT89C51 is a powerful microcomputer that offers a highly flexible and economical solution to many embedded control applications by integrating a flexible 8-bit CPU with Flash on a monolithic chip. Video related to AT89C51Video Description: This video is mainly about the detailed information about programming any IC microController such as AT89S52, AT89S51, and AT89C51. AT89C51 PinoutAT89C51 PinoutPin NumberPin NameDescription1P1.00th pin of PORT P12P1.11st pin of PORT P13P1.22nd pin of PORT P14P1.33rd pin of PORT P15P1.44th pin of PORT P16P1.55th pin of PORT P17P1.66th pin of PORT P18P1.77th pin of PORT P19RSTReset pin of the Microcontroller10(RXD) P3.00th pin of PORT P3 or Receiver pin of Microcontroller11(TXD) P3.11st pin of PORT P3 or Transmitter pin of Microcontroller12(INT0) P3.22nd pin of PORT P3 or External Interrupt 0 of MCU13(INT1) P3.33rd pin of PORT P3 or External Interrupt 1 of MCU14(T0) P3.44th pin of PORT P3 or Timer 0 interrupt of MCU15(T1) P3.55th pin of PORT P3 or Timer 1 interrupt of MCU16(WR) P3.66th pin of PORT P3 or Write to External data memory pin17(RD) P3.77th pin of PORT P3 or Read from External data memory pin18XTAL2External crystal pin 2 of Microcontroller19XTAL1External crystal pin 1 of Microcontroller20GNDGround pin of MCU21P2.0(A8)0th pin of PORT P2 or High-order Address bit 8 of MCU22P2.1(A9)1st pin of PORT P2 or High-order Address bit 9 of MCU23P2.2(A10)2nd pin of PORT P2 or High-order Address bit 10 of MCU24P2.3(A11)3rd pin of PORT P2 or High-order Address bit 11 of MCU25P2.4(A12)4th pin of PORT P2 or High-order Address bit 12 of MCU26P2.5(A13)5th pin of PORT P2 or High-order Address bit 13 of MCU27P2.6(A14)6th pin of PORT P2 or High-order Address bit 14 of MCU28P2.7(A15)7th pin of PORT P2 or High-order Address bit 15 of MCU29PSENProgram store enable pin, Read external program memory30ALE/PROGAddress Latch Enable/ Program Pulse input for flashing31EA/VPPAccess Enable voltage/Program enable voltage32P0.7(AD7)7th pin of PORT P0 or Low-order Address bit 7 of MCU33P0.6(AD6)6th pin of PORT P0 or Low -order Address bit 6 of MCU34P0.5(AD5)6th pin of PORT P0 or Low -order Address bit 5 of MCU35P0.4(AD4)6th pin of PORT P0 or Low -order Address bit 4 of MCU36P0.3(AD3)3rd pin of PORT P0 or Low -order Address bit 3 of MCU37P0.2(AD2)2nd pin of PORT P0 or Low -order Address bit 2 of MCU38P0.1(AD1)1st pin of PORT P0 or Low -order Address bit 1 of MCU39P0.0(AD0)0th pin of PORT P0 or Low -order Address bit 0 of MCU40VccSupply pin of MCU AT89C51 CAD ModelAT89C51 SymbolAT89C51 Footprint AT89C51 Block DiagramAT89C51 Block Diagram AT89C51 FeaturesFully Static Operation: 0 Hz to 24 MHzThree-level Program Memory Lock128 x 8-bit Internal RAM32 Programmable I/O LinesTwo 16-bit Timer/CountersSix Interrupt SourcesProgrammable Serial ChannelLow-power Idle and Power-down Modes AT89C51 EquivalentsAT89S52ATtiny45ATMega328PATMega8ATMEga32ATtiny88 How to Program the AT89C51 Microcontroller?With several software programs on the market, Atmel microcontrollers can be programmed. To mention a few, the most popular platforms are Arduino and Keil uVision. Keil is advised if you intend to implement substantial programming and growth with community support. An IDE (Integrated Development Environment), where the programming is done, is required to program the Atmel microcontroller. a compiler, where our software is transformed into HEX files, which are readable by MCUs. Our hex file is dumped into our MCUs using an IPE (Integrated Programming Environment).The most popular programmer is the USBASP, which must be purchased separately, and it allows us to upload or dump our code into Atmel IC. Additionally, it will save a ton of time to simulate your program on software before running it on hardware. Therefore, you may mimic your programs using tools like Labcenter's ISIS proteus.The following is an AT89C51 programming circuit:  AT89C51 Programming the FlashThe on-chip Flash memory array of the AT89C51 is often shipped in an erased condition (contents = FFH) and prepared for programming. Either a low-voltage (VCC) or high-voltage (12 volt) program enable signal is accepted by the programming interface. The AT89C51 can be easily programmed inside the user's system using the low-voltage programming mode, whilst the high-voltage programming mode is compatible with standard Flash or EPROM programmers from third parties.Both the high-voltage and low-voltage programming modes are active when the AT89C51 leaves the factory. The following table lists the corresponding top-side marking and device signature codes. Rightly choose the Atmel Microcontroller?Microchip offers a wide range of PIC and Atmel family microcontrollers. After Microchip bought Atmel, their collection has recently gotten larger. Each MCU has unique benefits and drawbacks. Before choosing an MCU for a project, one must take into account a number of factors. The following are merely recommendations that may aid with MCU selection.Make that your MCU can support communication protocols like UART, SPI, I2C, CAN, etc. if your project calls for them. More than one module of the same protocol can be supported by some MCUs.Check which MCU modules you might need based on the sensors and actuators utilized in your project. For instance, if you are reading a lot of analog voltages, check that the MCU has enough ADC channels and a resolution that supports it. The table above contains information on each module.If cost and size are constraints, you can pick tiny 8-pin MCUs like the Attiny1614. These are also considerably less expensive.Think about the system's operating voltage. Choose a 5V MCU if they are 5V. A 3.3V MCU can be chosen in these cases since some sensors or devices operate and communicate on this voltage.If you're a newbie learning microcontrollers, picking an MCU with a strong online community and a variety of applications will be a wise decision. The AT89S52 or ATmega328 from Atmel are both viable options. Difference between 8051 and AVR MicrocontrollersMicrocontrollers in the 8051 family are 8-bit devices. It is a low-cost, entry-level micro-controller that is utilized worldwide for the majority of simple applications. It also uses little power. The 1981 was the year that Intel developed it. The main applications for this micro-controller are in autos, medical equipment, and energy management systems.The Atmel Corporation created the AVR microcontroller in 1996. It also goes by the name Advanced Virtual RISC and is based on the RISC Instruction Set Architecture (ISA). The first microcontroller from the AVR series was the AT90S8515. The most popular and affordable type of controller is the AVR micro-controller. Numerous robotic applications make use of it.8051 MicrocontrollerAVR Microcontroller8051 micro-controller has 8 bit bus width.AVR micro-controller has 8 bit but some are 32 bit bus width.Micro-controllers are from Intel company.Micro-controllers are from Atmel comapny.8051 micro-controller is based on von neuman architecture.AVR micro-controller is based on Modified Harvard architecture.8051 micro-controller uses CISC Instruction Set Architecture.AVR micro-controller uses RISC Instruction Set Architecture.It uses SPI, I2C, UART, USART communication protocol.It uses UART, USART, LIN, CAN, Ethernet, SPI, I2S communication protocols.It consumes average power.It consumes low power.Its family includes 8051 variants.Its family includes Atmega, Tiny, Xmega, special purpose AVR.It has vast community support.It has very good communication support.It uses ROM, SRAM, FLASH memory.It uses Flash, SRAM, EEPROM memory.Its speed is 12 clock per instruction cycle.Its speed is 1 clock per instruction cycle.Popular micro-controllers are AT89C51, P89v51, etc.Popular micro-controllers are Atmega8, 16, 32, Arduino Community. AT89C51 ApplicationsMultiple DIY ProjectsVery good choice if you are learning ATmelProjects requiring Multiple I/O interfaces and communicationsReplacement for Arduino ModuleIdeal for more advanced level A/D applications in automotive, industrial, appliances and consumer applications. AT89C51 DatasheetThe following is the Datasheet about the AT89C51 :AT89C51 Datasheet AT89C51 Packaging informationAT89C51 Packaging information AT89C51 FAQWhat is AT89C51?A CMOS 8-bit microcomputer with low power consumption and high performance, the AT89C51 has 4K bytes of programmable and erasable Flash read-only memory (PEROM). The product is made with high-density nonvolatile memory technology from Atmel, and its pinout and instruction set are compliant with the industry standard MCS-51. Is AT898051 and AT8989c51 the same?Intel only created the architecture known as the 8051. It is employed in 89c51 as well as 89c52. The flash memory and timer are the main distinctions between them. What is the difference between AT89C51 and AT89S51?The main distinction between the 89c51 and 89s51 is that all S series chips, including the 89s51, may be programmed by both the parallel port and ISP port. But only a parallel programmer can be used to program the 89c51. Is AVR or 8051 better?The first microcontroller from the AVR series was the AT90S8515. The most popular and affordable type of controller is the AVR micro-controller. How many pins 89c51 micro controller has?An ancient 8-bit microcontroller from the Atmel family is the AT89C51. Since it utilizes the well-liked 8051 architecture, most novices still use it today. It has a 4Kb flash memory and a 40 pin IC chip.
kynix On 2022-12-09   2051
Integrated Circuits (ICs)

LIS3MDL Magnetometer: Datasheet, Features, Pinout [Video&FAQ]

Product OverviewThe LIS3MDL is an ultra low-power high performance three axis magnetic sensor. The self-test capability allows the user to check the functioning of the sensor in the final application. The device may be configured to generate interrupt signals for magnetic field detection. The LIS3MDL includes an I²C serial bus interface that supports standard and fast mode 100 kHz and 400 kHz and SPI serial standard interface. The LIS3MDL is available in a small thin plastic land grid array package (LGA) and is guaranteed to operate over an extended temperature range of -40°C to +85°C. Video: New Products 3/11/2020 featuring LSM6DSOX + LIS3MDL - Precision 9 DoF IMU - STEMMA QT / Qwiic CatalogProduct OverviewLIS3MDL FeaturesLIS3MDL PinoutLIS3MDL ApplicationsLIS3MDL Block DiagramLIS3MDL Symbol and FootprintLIS3MDL Schematic DiagramLIS3MDL SpecificationLIS3MDL VS LIS2MDLLIS3MDL ManufacturerLIS3MDL DatasheetUsing WarningsLIS3MDL FAQ LIS3MDL FeaturesWide supply voltage, 1.9 V to 3.6 VIndependent IO supply (1.8 V)±4/ ±8/ ±12/ ±16 gauss selectable magnetic full-scaleContinuous and single conversion mode16-bit data outputInterrupt generatorSelf-testI²C/SPI digital output interfacePower-down mode/ low-power modeECOPACK® RoHS and "Green" compliant LIS3MDL PinoutThe pin configuration of LIS3MDL is shown in the picture below. LIS3MDL Pinout LIS3MDL ApplicationsMagnetometersCompasses LIS3MDL Block DiagramThe following figure shows the block diagram of LIS3MDL. LIS3MDL Block Diagram LIS3MDL Symbol and FootprintFollowings are LIS3MDL Symbol and Footprint. LIS3MDL Symbol LIS3MDL Footprint LIS3MDL Schematic Diagram LIS3MDL Schematic Diagram The above schematic shows the additional components the carrier board incorporates to make the LIS3MDL easier to use, including the voltage regulator that allows the board to be powered from a single 2.5-5.5 V supply and the level-shifter circuit that allows for I²C and SPI communication at the same logic voltage level as VIN. LIS3MDL SpecificationAxisX, Y, ZCurrent - Supply (Max)270µA (Typ)FeaturesSelectable ScaleMounting TypeSurface MountOperating Temperature-40°C ~ 85°C (TA)Output TypeI²C, SPIPackage / Case12-VFLGAResolution16 bSensing Range±0.4mT, ±0.8mT, ±1.2mT, ±1.6mTVoltage - Supply1.9V ~ 3.6V LIS3MDL VS LIS2MDL LIS3MDLLIS2MDLAxisX, Y, ZX, Y, ZCurrent - Supply (Max)270µA (Typ)-FeaturesSelectable ScaleSelectable ScaleMounting TypeSurface MountSurface MountOperating Temperature-40°C ~ 85°C (TA)-40°C ~ 85°C (TA)Output TypeI²C, SPII²C, SPIPackage / Case12-VFLGA12-WFLGAResolution16 b16 bSensing Range±0.4mT, ±0.8mT, ±1.2mT, ±1.6mT Voltage - Supply1.9V ~ 3.6V1.71V ~ 3.6V LIS3MDL ManufacturerST is a global semiconductor leader delivering intelligent and energy-efficient products and solutions that power the electronics at the heart of everyday life. ST’s products are found everywhere today, and together with our customers, we are enabling smarter driving and smarter factories, cities and homes, along with the next generation of mobile and Internet of Things devices. By getting more from technology to get more from life, ST stands for life.augmented. LIS3MDL DatasheetYou can download this datasheet for LIS3MDL-Datasheet from the link given below:LIS3MDL Datasheet Using WarningsNote: Please check their parameters and pin configuration before replacing them in your circuit. LIS3MDL FAQ① Is the lis3mdl an ultra low power magnetic sensor?The LIS3MDL is an ultra-low-power high-performance three-axis magnetic sensor. ② How do you calibrate a magnetic sensor?Open the Google Maps app, making sure that your blue circular device location icon is in view. Tap on the location icon to bring up more information about your location. At the bottom, tap the “Calibrate Compass” button. This will bring up the compass calibration screen. ③ What is the performancerating of the lis3mdl?The parameter performanceRating is an integer between 0 and 3, assigned as follows: Switches the LIS3MDL in or out of low-power mode. In low-power mode, the output data rate is dropped to 0.625Hz and the system performs the minimum number of averages in its calculations. ④ How does the lis3mdl communicate with the CS pin?To communicate with the LIS3MDL in SPI mode, the CS pin (which the board pulls to VDD through a 10 kΩ resistor) must be driven low before the start of an SPI command and allowed to return high after the end of the command. ⑤ Is there a SPI interface for the lis3mdl?A detailed explanation of the SPI interface on the LIS3MDL can be found in its datasheet (2MB pdf). We have written a basic Arduino library for the LIS3MDL that makes it easy to interface this sensor with an Arduino or Arduino-compatible board like an A-Star.
kynix On 2022-03-16   2050

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