The Kynix Components

 CatalogDescriptionCAD ModelsPin ConfigurationBlock DiagramFeaturesApplicationsDatasheetProduct AttributesManufacturerUsing WarningDescriptionThe LT3092 is a programmable 2-terminal current source. It requires only two resistors to set an output current between 0.5mA and 200mA. A multitude of analog techniques lend themselves to actively programming the output current. The LT3092 is stable without input and output capacitors, offering high DC and AC impedance. This feature allows operation in intrinsically safe applications. The SET pin features 1% initial accuracy and low temperature coefficient. Current regulation is better than 10ppm/V from 1.5V to 40V. The LT3092 can operate in a 2-terminal current source configuration in series with signal lines. It is ideal for driving sensors, remote supplies, and as a precision current limiter for local supplies. Internal protection circuitry includes reverse-battery and reverse-current protection, current limiting and thermal limiting. The LT3092 is offered in the 8-lead TSOT-23, 3-lead SOT-223 and 8-lead 3mm × 3mm DFN packages. CAD Models Figure:  PCB Symbol  Figure:  Footprint  Figure:  3D Model Pin Configuration Figure:  Pin Configuration Block Diagram Figure:  Block Diagram FeaturesProgrammable 2-Terminal Current SourceMaximum Output Current: 200mAWide Input Voltage Range: 1.2V to 40VInput/Output Capacitors Not RequiredResistor Ratio Sets Output CurrentInitial Set Pin Current Accuracy: 1%Reverse-Voltage ProtectionReverse-Current Protection<0.001%/V Line Regulation TypicalCurrent Limit and Thermal Shutdown ProtectionAvailable in 8-Lead SOT-23, 3-Lead SOT-223 and 8-Lead 3mm × 3mm DFN PackagesAEC-Q100 Qualified for Automotive Applications Applications2-Terminal Floating Current SourceGND Referred Current SourceVariable Current SourceIn-Line LimiterIntrinsic Safety Circuits DatasheetLT3092ETS8#TRMPBF-Datasheet Product AttributesManufacturer:Analog Devices Inc.Product Category:Current & Power Monitors & RegulatorsProduct:Current MonitorsSupply Voltage - Max:40 VSupply Voltage - Min:1.2 VOperating Supply Current:0.3 mAAccuracy:0.01Minimum Operating Temperature:- 40 ℃Maximum Operating Temperature:+ 125 ℃Mounting Style:SMD/SMTPackage / Case:SOT-23-8Packaging:Cut TapePackaging:MouseReelPackaging:ReelOutput Current:200 mASeries:LT3092Brand:Analog DevicesInput Voltage Range:1.2 V to 40 VProduct Type:Current & Power Monitors & RegulatorsFactory Pack Quantity:500Subcategory:PMIC - Power Management ICsUnit Weight:0.007054 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. In 2012, Analog Devices led the worldwide data converter market with a 48.5% share, according to analyst firm Databeans. Using WarningNote: Please check their parameters and pin configuration before replacing them in your circuit. 

CatalogFeaturesDescriptionAbsolute Maximum RatingsThermal ResistanceElectrical CharacteristicsSource-Drain Ratings and CharacteristicsTypical Characteristics and GraphsPackage OutlinePart Marking InformationDatasheet PDF DownloadIRFP260 FAQ FeaturesAdvanced ProcessTechnologyDynamic dv/dtRating175°C OperatingTemperatureFastSwitchingFully AvalancheRatedEase ofParallelingSimple DriveRequirementsLead-FreeDescriptionFifth Generation HEXFETs from International Rectifier utilize advanced processing techniques to achieve extremely low onresistance per silicon area. This benefit, combined with the fast switching speed and ruggedized device design that HEXFET Power MOSFETs are well known for, provides the designer with an extremely efficient and reliable device for use in a wide variety of applications. The TO-247 package is preferred for commercial-industrial applications where higher power levels preclude the use of TO-220 devices. The TO-247 is similar but superior to the earlier TO-218 package because of its isolated mounting hole.Absolute Maximum Ratings ParameterMax.UnitsID @ TC = 25°CContinuous Drain Current, VGS @ 10V50 AID @ TC = 100°CContinuous Drain Current, VGS @ 10V35IDMPulsed Drain Current ➀200PD @TC = 25°CPower Dissipation300W Linear Derating Factor2.0W/°CVGSGate-to-Source Voltage±20VEASSingle Pulse Avalanche Energy560mJIARAvalanche Current➀50AEARRepetitive Avalanche Energy➀30mJdv/dtPeak Diode Recovery dv/dt ➂10V/nsTJTSTGOperating Junction andStorage Temperature Range-55 to +175 °C Soldering Temperature, for 10 seconds300 (1.6mm from case ) Mounting torque, 6-32 or M3 srew10 lbf•in (1.1N•m) Thermal Resistance ParameterTyp.Max.UnitsRqJCJunction-to-Case–––0.50 °C/WRqCSCase-to-Sink, Flat, Greased Surface0.24–––RqJAJunction-to-Ambient–––40Electrical Characteristics ParameterMin.Typ.Max.UnitsConditionsV(BR)DSSDrain-to-Source Breakdown Voltage200––––––VVGS = 0V, ID = 250µADV(BR)DSS/DTJBreakdown Voltage Temp. Coefficient–––0.26–––V/°CReference to 25°C, ID = 1mARDS(on)Static Drain-to-Source On-Resistance––––––0.04LVGS = 10V, ID = 28A     VGS(th)Gate Threshold Voltage2.0–––4.0VVDS = VGS, ID = 250µAgfsForward Transconductance27––––––SVDS = 50V, ID = 28A  IDSSDrain-to-Source Leakage Current––––––25µAVDS = 200V, VGS = 0V––––––250VDS = 160V, VGS = 0V, TJ = 150°CIGSSGate-to-Source Forward Leakage––––––100nAVGS = 20VGate-to-Source Reverse Leakage––––––-100VGS = -20VQgTotal Gate Charge––––––234 nCID = 28A VDS = 160VVGS = 10V  QgsGate-to-Source Charge––––––38QgdGate-to-Drain ("Miller") Charge––––––110td(on)Turn-On Delay Time–––17––– nsVDD = 100V ID = 28A RG = 1.8LVGS = 10V     trRise Time–––60–––td(off)Turn-Off Delay Time–––55–––tfFall Time–––48–––LDInternal Drain Inductance–––5.0––– nHBetween lead, D6mm (0.25in.)from package Gand center of die contact SLSInternal Source Inductance–––13–––CissInput Capacitance–––4057––– pFVGS = 0V VDS = 25Vƒ = 1.0MHzCossOutput Capacitance–––603–––CrssReverse Transfer Capacitance–––161–––Source-Drain Ratings and Characteristics ParameterMin.Typ.Max.UnitsConditionsISContinuous Source Current(Body Diode)––––––50 AMOSFET symbol Dshowing theintegral reverse Gp-n junction diode. SISMPulsed Source Current(Body Diode)➀––––––200VSDDiode Forward Voltage––––––1.3VTJ = 25°C, IS = 28A, VGS = 0V  trrReverse Recovery Time–––268402nsTJ = 25°C, IF = 28Adi/dt = 100A/µs  QrrReverse Recovery Charge–––1.92.8mCtonForward Turn-On TimeIntrinsic turn-on time is negligible (turn-on is dominated by LS+LD) Typical Characteristics and Graphs     Package OutlinePart Marking InformationDatasheet PDF DownloadYou can download the datasheet of IRFP260 from the link given below.IRFP260-DatasheetIRFP260 FAQWhat is power MOSFET and its types?Power MOSFET is a type of MOSFET which is specially meant to handle high levels of power. These exhibit high switching speed and can work much better in comparison with other normal MOSFETs in the case of low voltage levels. However its operating principle is similar to that of any other general MOSFET.Why power MOSFET is vertical?The vertical orientation eliminates crowding at the gate and offers larger channel widths. In addition, thousands of these transistor "cells" are combined into one in order to handle the high currents and voltage required of such devices.What is the construction of power MOSFET?A power MOSFET actually consists of a parallel connection of thousands of basic MOSFET cells on the same single chip of silicon. When gate circuit voltage is zero, and VDD is present , n−−p− junctions are reverse biased and no current flows from drain to source. 

CatalogMPU9250 DescriptionMPU9250 Related Video InstructionMPU9250 CAD ModelsMPU9250 Pin ConfigurationMPU9250 Block DiagramMPU9250 FeaturesMPU9250 ApplicationsMPU9250 DatasheetMPU9250 SpecificationsMPU9250 ManufacturerUsing WarningMPU9250 FAQMPU9250 DescriptionMPU-9250 is a multi-chip module (MCM) consisting of two dies integrated into a single QFN package. One die houses the 3-Axis gyroscope and the 3-Axis accelerometer . The other die houses the AK8963 3-Axis magnetometer from Asahi Kasei Microdevices Corporation. Hence, the MPU-9250 is a 9-axis MotionTracking device that combines a 3-axis gyroscope, 3-axis accelerometer.  3-axis magnetometer and a Digital Motion Processor (DMP) all in a small 3x3x1mm package available as a pin-compatible upgrade from the MPU-6515. With its dedicated I2 C sensor bus  , the MPU-9250 directly provides complete 9-axis MotionFusion output. The MPU-9250 MotionTracking device, with its 9-axis integration, on-chip MotionFusion , and run-time calibration firmware , enables manufacturers to eliminate the costly and complex selection, qualification, and system level integration of discrete devices, guaranteeing optimal motion performance for consumers. MPU-9250 is also designed to interface with multiple non-inertial digital sensors, such as pressure sensors , on its auxiliary I2C port. MPU9250 Related Video InstructionVideo: MPU9250 module with Arduino Tutorials -Accelerometer, gyroscope and Magnetometer sensorMPU9250 Video Description:In this video you will learn about the MPU9250 Gyroscope, Accelerometer, Magnetometer sensor with library installation and code explanation. MPU9250 CAD Models Figure: PCB Symbol  Figure: Footprint  Figure: 3D Model MPU9250 Pin Configuration Figure: Pin Configuration MPU9250 Block Diagram Figure: Block Diagram MPU9250 FeaturesGyroscope FeaturesThe triple-axis MEMS gyroscope in the MPU-9250 includes a wide range of features:Digital-output X-, Y-, and Z-Axis angular rate sensors (gyroscopes) with a user-programmable fullscale range of ±250, ±500, ±1000, and ±2000°/sec and integrated 16-bit ADCs Digitally-programmable low-pass filterGyroscope operating current : 3.2mASleep mode current: 8µAFactory calibrated sensitivity scale factorSelf-test Accelerometer FeaturesThe triple-axis MEMS accelerometer  in MPU-9250 includes a wide range of features:Digital-output triple-axis accelerometer with a programmable full scale range of ±2g, ±4g, ±8g and ±16g and integrated 16-bit ADCsAccelerometer normal operating current : 450µALow power accelerometer mode current: 8.4µA at 0.98Hz, 19.8µA at 31.25HzSleep mode current: 8µAUser-programmable interruptsWake-on-motion interrupt for low power operation of applications processorSelf-test Magnetometer FeaturesThe triple-axis MEMS magnetometer in MPU-9250 includes a wide range of features:3-axis silicon monolithic Hall-effect magnetic sensor with magnetic concentratorWide dynamic measurement range and high resolution with lower current consumption.Output data resolution of 14 bit (0.6µT/LSB) or 16 bit (15µT/LSB)Full scale measurement range is ±4800µTMagnetometer normal operating current : 280µA at 8Hz repetition rateSelf-test function with internal magnetic source to confirm magnetic sensor operation on end products Additional FeaturesThe MPU-9250 includes the following additional features:Auxiliary master I2C bus for reading data from external sensors (e.g. pressure sensor)3.5mA operating current when all 9 motion sensing axes and the DMP  are enabledVDD supply voltage range of 2.4 – 3.6VVDDIO reference voltage for auxiliary I2C devicesSmallest and thinnest QFN package for portable devices: 3x3x1mmMinimal cross-axis sensitivity between the accelerometer.  gyroscope and magnetometer axes512 byte FIFO buffer enables the applications processor to read the data in burstsDigital-output temperature sensorUser-programmable digital filters for gyroscope, accelerometer , and temp sensor10,000 g shock tolerant400kHz Fast Mode I2C for communicating with all registers1MHz SPI serial interface for communicating with all registers20MHz SPI serial interface for reading sensor and interrupt registersMEMS structure hermetically sealed and bonded at wafer levelRoHS and Green compliant MPU9250 ApplicationsTouchAnywhere technology (for ''no touch” UI Application Control / Navigation)MotionCommand technology (for Gesture Short-cuts)Motion-enabled game and application frameworkLocation based services, points of interest, and dead reckoningHandset and portable gamingMotion-based game controllers3D remote controls for Internet connected DTVs and set top boxes, 3D miceWearable sensors for health, fitness and sports MPU9250 DatasheetYou can download the datasheet from the link given below.MPU9250-Datasheet MPU9250 SpecificationsManufacturer Part Number:MPU9250Rohs Code:YesPart Life Cycle Code:ObsoletePackage Description:HQCCNReach Compliance Code:compliantHTS Code:8542.39.00.01Manufacturer:InvenSense IncRisk Rank:7.98Analog IC - Other Type:ANALOG CIRCUITJESD-30 Code:S-XQCC-N24Length:3 mmNumber of Functions:1Number of Terminals:24Operating Temperature-Max:85 °COperating Temperature-Min:-40 °CPackage Code:HQCCNPackage Shape:SQUAREPackage Style:CHIP CARRIER, HEAT SINK/SLUGSeated Height-Max:1.05 mmSupply Voltage-Max (Vsup):3.6 VSupply Voltage-Min (Vsup):2.4 VSupply Voltage-Nom (Vsup):2.5 VSurface Mount:YESTemperature Grade:INDUSTRIALTerminal Pitch:0.4 mmTerminal Position:QUAD MPU9250 ManufacturerInvenSense Inc. is the provider of the MotionTracking sensor system on chip (SoC) which functions as a gyroscope for consumer electronic devices such as smartphones, tablets, wearables, gaming devices, optical image stabilization, and remote controls for Smart TVs. InvenSense provides the motion controller in the Nintendo Wii game controller and the Oculus Rift DK1. Using WarningNote: Please check their parameters and pin configuration before replacing them in your circuit. MPU9250 FAQWhat size package is the MPU-9250 available as a pin-compatible upgrade from the MPU-6515?3x3x1mm. What is one of the additional features of the MPU-9250?Auxiliary master I2C bus. What is the Auxiliary master I2C bus for reading data from external sensors?Pressure sensor. Whats an MCM package?A multi-chip module (MCM) is an electronic package consisting of multiple integrated circuits (ICs) assembled into a single device. An MCM works as a single component and is capable of handling an entire function. ... The module can be encapsulated by a plastic molding and is mounted on the printed circuit board. What are the characteristics of the multichip module?A multichip module (MCM) package consists of a multilevel structure containing a repetition of several layers of conductors. Compared to lithography, electrochemical microfabrication produces thick conductors with lateral dimensions in the submicrometer range for advanced MCM packages. 

CatalogKSZ8895MQXIA Product OverviewKSZ8895MQXIA CAD ModelsKSZ8895MQXIA Pin ConfigurationKSZ8895MQXIA Block DiagramKSZ8895MQXIA FeaturesKSZ8895MQXIA ApplicationsKSZ8895MQXIA Package OutlineKSZ8895MQXIA DatasheetKSZ8895MQXIA SpecificationsKSZ8895MQXIA ManufacturerUsing Warning KSZ8895MQXIA Product OverviewFive 10/100 physical layer transceivers, five media access control (MAC) units, and a Layer 2 controlled switch are all included in the KSZ8895MQXIA. The system has three operating modes. The five-port integrated switch mode is the first mode. The second switch has five ports, the fifth of which is separated from the physical port. Through a media independent interface (MII/RMII), the fifth MAC is accessible in this mode. This is helpful for setting up a built-in broadband router. The third approach recovers usage of the fifth PHY by using the dual MII/RMII functionality. As a result, it is possible to configure a second broadband gateway such that the P5-MII/RMII port can be used to access the fifth PHY. It is possible for the KSZ8895MQXIA to be used in either a managed or unmanaged design. In a controlled configuration, the KSZ8895MQX/RQX/FQX/MLX are entirely under the control of the host processor over the SPI bus or the MDC/MDIO interface. Through I/O strapping or EEPROM programming at system reset time, an unmanaged design is accomplished. The KSZ8895MQXIA supports Auto MDI/MDIX and IEEE 802.3 10BASE-T, 100BASE-TX on all copper ports. On port 4, the KSZ8895FQX supports 100BASE-FX, and on port 3, either copper or fiber can be configured as the default. The KSZ8895MQXIA can be connected to a microprocessor via its SW-MII/RMII interfaces for any application or utilized as a fully managed five-port switch. Patented analog circuitry and DSP technology improve physical signal transmission and reception, increase design efficiency, enable lower power consumption, and provide excellent electrical noise immunity. The main differences between the KS8995MQ/RQ/FMQ and the KSZ8895MQX/RQX/FQX are the increased power savings, the lack of a restriction on the transformer's center taps, the request that the center taps of the transformer's RX and TX not be tied together for power savings, and the addition of the Microchip LinkMD feature in the switches. The KSZ8895MQX/RQX/FQX and KSZ8895MQ/RQ/FMQ are fully compatible. KSZ8895MQXIA CAD Models  Figure: PCB Symbol  Figure: Footprint   Figure: 3D Models KSZ8895MQXIA Pin Configuration  Figure: Pin Configuration KSZ8895MQXIA Block Diagram  Figure: Block Diagram KSZ8895MQXIA FeaturesLow-Power DissipationFull-Chip Hardware Power-DownFull-Chip Software Power-Down and Per PortSoftware Power-DownEnergy-Detect Mode Support <100 mW Full-ChipPower Consumption When All Ports Have NoActivityVery-Low Full-Chip Power Consumption (<0.5W) in Standalone 5-Port, without Extra Power Consumption on TransformersDynamic Clock Tree Shutdown FeatureVoltages: Single 3.3V Supply with 3.3V VDDIO and Internal 1.2V LDO Controller Enabled, or External 1.2V LDO Solution- Analog VDDAT 3.3V Only- VDDIO Support 3.3V, 2.5V, and 1.8V- Low 1.2V Core PowerCommercial Temperature Range: 0°C to +70°CIndustrial Temperature Range: –40°C to +85°CAvailable in 128-pin PQFP and 128-pin LQFP, Lead-Free PackagesIntegrated 5-Port 10/100 Ethernet SwitchNew Generation Switch with Five MACs and FivePHYs that are Fully Compliant with the IEEE802.3u StandardPHYs Designed with Patented Enhanced MixedSignal TechnologyNon-Blocking Switch Fabric Ensures Fast PacketDelivery by Utilizing a 1K MAC Address Lookup Table and a Store-and-Forward ArchitectureOn-Chip 64Kbyte Memory for Frame Buffering(Not Shared with 1K Unicast Address Table)Full-Duplex IEEE 802.3x Flow Control (PAUSE) with Force Mode OptionHalf-Duplex Back Pressure Flow ControlHP Auto MDI/MDI-X and IEEE Auto Crossover SupportSW-MII Interface Supports Both MAC Mode and PHY Mode7-Wire Serial Network Interface (SNI) Support forLegacy MACPer Port LED Indicators for Link, Activity, and 10/100 SpeedRegister Port Status Support for Link, Activity,Full-/Half-Duplex and 10/100 SpeedLinkMD® Cable Diagnostic CapabilitiesOn-Chip Terminations and Internal Biasing Technology for Cost Down and Lowest Power ConsumptionSwitch Monitoring FeaturesPort Mirroring/Monitoring/Sniffing: Ingress and/or Egress Traffic to Any Port or MIIMIB Counters for Fully Compliant Statistics Gathering; 34 MIB Counters Per PortLoopback Support for MAC, PHY, and RemoteDiagnostic of FailureInterrupt for the Link Change on Any PortsQoS/CoS Packet Prioritization SupportPer Port, 802.1p and DiffServ-Based1/2/4-Queue QoS Prioritization SelectionProgrammable Weighted Fair Queuing for RatioControlRe-Mapping of 802.1p Priority Field Per Port BasisAdvanced Switch FeaturesIEEE 802.1q VLAN Support for up to 128 ActiveVLAN Groups (Full-Range 4096 of VLAN IDs)Static MAC Table Supports up to 32 EntriesVLAN ID Tag/Untagged Options, Per Port BasisIEEE 802.1p/q Tag Insertion or Removal on a PerPort Basis Based on Ingress Port (Egress)Programmable Rate Limiting at the Ingress and Egress on a Per Port BasisJitter-Free Per Packet Based Rate Limiting SupportBroadcast Storm Protection with Percentage Control (Global and Per Port Basis)IEEE 802.1d Rapid Spanning Tree Protocol RSTP SupportTail Tag Mode (1 Byte Added Before FCS) Support at Port 5 to Inform the Processor Which Ingress Port Receives the Packet1.4 Gbps High-Performance Memory Bandwidthand Shared Memory Based Switch Fabric withFully Non-Blocking ConfigurationDual MII with MAC 5 and PHY 5 on Port 5, SW5-MII/RMII for MAC 5 and P5-MII/RMII for PHY 5Enable/Disable Option for Huge Frame Size up to2000 Bytes Per FrameIGMP v1/v2 Snooping (IPv4) Support for MulticastPacket FilteringIPv4/IPv6 QoS SupportSupport Unknown Unicast/Multicast Address andUnknown VID Packet FilteringSelf-Address FilteringComprehensive Configuration Register AccessSerial Management Interface (MDC/MDIO) to All PHYs Registers and SMI Interface (MDC/MDIO) to All RegistersHigh-Speed SPI (up to 25 MHz) and I2C MasterInterface to all Internal RegistersI/O Pins Strapping and EEPROM to ProgramSelective Registers in Unmanaged Switch ModeControl Registers Configurable on the Fly (Port-Priority, 802.1p/d/q, AN…) KSZ8895MQXIA ApplicationsSOHO Residential GatewayBroadband Gateway/Firewall/VPNIntegrated DSL/Cable ModemWireless LAN Access Point + GatewayStandalone 10/100 5-Port SwitchTypicalVoIP PhoneSet-Top/Game BoxIndustrial ControlIPTV POF KSZ8895MQXIA Package Outline  Figure: Package Outline KSZ8895MQXIA DatasheetYou can download the datasheet from the link given below: KSZ8895MQXIA Datasheet KSZ8895MQXIA SpecificationsTypeDescriptionCategoryIntegrated Circuits (ICs)InterfaceControllersMfrMicrochip TechnologySeries-PackageTrayProduct StatusActiveProtocolEthernetFunctionSwitchInterfaceI²C, SPIStandards10/100 Base-T/TXVoltage - Supply1.8V, 2.5V, 3.3VCurrent - Supply129mAOperating Temperature-40°C ~ 85°CPackage / Case128-BFQFPSupplier Device Package128-PQFP (14x20)Base Product NumberKSZ8895 KSZ8895MQXIA ManufacturerAmerican company Microchip Technology Inc., which is publicly traded, produces integrated circuits for microcontrollers, mixed-signal devices, analog devices, and Flash-IP. Its offerings include linear, interface, and wireless products, as well as microcontrollers (PIC, dsPIC, AVR, and SAM), serial EEPROM devices, serial SRAM devices, embedded security devices, radio frequency (RF) devices, temperature, power, and battery management analog devices. Using WarningNote: Please check their parameters and pin configuration before replacing them in your circuit.

 CatalogDescriptionCAD ModelsPin ConfigurationBlock DiagramFeaturesApplicationsDatasheetProduct AttributesManufacturerUsing WarningDescriptionThe AD9364 is a high performance, highly integrated radio frequency (RF) Agile Transceiver designed for use in 3G and 4G base station applications. Its programmability and wideband capability make it ideal for a broad range of transceiver applications. The device combines an RF front end with a flexible mixed-signal baseband section and integrated frequency synthesizers, simplifying design-in by providing a configurable digital interface to a processor. The AD9364 operates in the 70 MHz to 6.0 GHz range, covering most licensed and unlicensed bands. Channel bandwidths from less than 200 kHz to 56 MHz are supported. The direct conversion receiver has state-of-the-art noise figure and linearity. The receive (Rx) subsystem includes independent automatic gain control (AGC), dc offset correction, quadrature correction, and digital filtering, thereby eliminating the need for these functions in the digital baseband. The AD9364 also has flexible manual gain modes that can be externally controlled. Two high dynamic range ADCs digitize the received I and Q signals and pass them through configurable decimation filters and 128-tap FIR filters to produce a 12-bit output signal at the appropriate sample rate. CAD Models Figure: PCB Symbol  Figure: Footprint  Figure: 3D Model Pin Configuration Figure: Pin Configuration Block Diagram Figure: Block Diagram FeaturesRF 1 × 1 transceiver with integrated 12-bit DACs and ADCsBand: 70 MHz to 6.0 GHzSupports time division duplex (TDD) and frequency division      duplex (FDD) operationTunable channel bandwidth (BW): <200 kHz to 56 MHz3-band receiver: 3 differential or 6 single-ended inputsSuperior receiver sensitivity with a noise figure of <2.5 dBRx gain controlReal-time monitor and control signals for manual gainIndependent automatic gain control2-band differential output transmitterHighly linear broadband transmitterTx EVM: ≤−40 dBTx noise: ≤−157 dBm/Hz noise floorTx monitor: ≥66 dB dynamic range with 1 dB accuracyIntegrated fractional-N synthesizers      2.4 Hz maximum local oscillator (LO) step sizeMultichip synchronizationCMOS/LVDS digital interface ApplicationsPoint to point communication systemsFemtocell/picocell/microcell base stationsGeneral-purpose radio systems DatasheetYou can download the datasheet from the link given below:AD9364BBCZ-Datasheet Product AttributesManufacturer:Analog Devices Inc.Product Category:RF TransceiverType:LTE, WiMAXFrequency Range:70 MHz to 6 GHzSupply Voltage - Min:1.267 VSupply Voltage - Max:1.33 VOutput Power:8 dBmMinimum Operating Temperature:- 40 ℃Maximum Operating Temperature:+ 85 ℃Interface Type:4-WirePackage / Case:BGA-144Packaging:TraySeries:AD9364Technology:SiBrand:Analog DevicesMounting Style:SMD/SMTMaximum Operating Frequency:6 GHzMoisture Sensitive:YesNumber of Receivers:1Number of Transmitters:1Product Type:RF TransceiverFactory Pack Quantity:184Subcategory:Wireless & RF Integrated CircuitsUnit Weight:0.029630 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. In 2012, Analog Devices led the worldwide data converter market with a 48.5% share, according to analyst firm Databeans. Using WarningNote: Please check their parameters and pin configuration before replacing them in your circuit. 

Catalog FeaturesGeneral DescriptionProduct HighlightsPin ConfigurationsAbsolute Maximum RatingsTheory of OperationPerformance Over TemperatureOutput Current CharacteristicsDynamic PerformanceNoise Filtering Using the Strobe TerminalPrecision High Current SupplyPrecision DAC ReferenceAD584 DatasheetAD584 FAQ FeaturesFour programmable output voltages  10.000 V, 7.500 V, 5.000 V, and 2.500 VLaser-trimmed to high accuraciesNo external components requiredTrimmed temperature coefficient  15 ppm/°C maximum, 0°C to 70°C (AD584K)   15 ppm/°C maximum, −55°C to +125°C (AD584T)Zero output strobe terminal provided2-terminal negative reference: capability (5 V and above)Output sources or sinks currentLow quiescent current: 1.0 mA maximum10 mA current output capabilityMIL-STD-883 compliant versions available General DescriptionThe AD584 is an 8-terminal precision voltage reference offering pin programmable selection of four popular output voltages: 10.000 V, 7.500 V, 5.000 V and 2.500 V. Other output voltages, above, below, or between the four standard outputs, are available by the addition of external resistors. The input voltage can vary between 4.5 V and 30 V. Laser wafer trimming (LWT) is used to adjust the pin programmable output levels and temperature coefficients, resulting in the most flexible high precision voltage reference available in monolithic form. In addition to the programmable output voltages, the AD584 offers a unique strobe terminal that permits the device to be turned on or off. When the AD584 is used as a power supply reference, the supply can be switched off with a single, low power signal. In the off state, the current drained by the AD584 is reduced to approximately 100 µA. In the on state, the total supply current is typically 750 µA, including the output buffer amplifier.The AD584 is recommended for use as a reference for 8-, 10-, or 12-bit digital-to-analog converters (DACs) that require an external precision reference. In addition, the device is ideal for analog-to-digital converters (ADCs) of up to 14-bit accuracy, either successive approximation or integrating designs, and in general, it can offer better performance than that provided by standard self-contained references. The AD584J and AD584K are specified for operation from 0°C to +70°C, and the AD584S and AD584T are specified for the −55°C to +125°C range. All grades are packaged in a hermetically sealed, eight-terminal TO-99 metal can, and the AD584J and AD584K are also available in an 8-lead PDIP.  Product Highlights1. The flexibility of the AD584 eliminates the need to designin and inventory several different voltage references. Furthermore, one AD584 can serve as several references simultaneously when buffered properly.  2. Laser trimming of both initial accuracy and temperature coefficient results in very low errors overtemperature without the use of external components.  3. The AD584 can be operated in a 2-terminal Zener mode at a 5 V output and above. By connecting the input and the output, the AD584 can be used in this Zener configuration as a negative reference.  4. The output of the AD584 is configured to sink or source currents. This means that small reverse currents can be tolerated in circuits using the AD584 without damage to the reference and without disturbing the output voltage(10 V, 7.5 V, and 5 V outputs).  5. The AD584 is available in versions compliant with MIL-STD883. Refer to the Analog Devices current AD584/883B data sheet for detailed specifications. This can be found under the Additional Data Sheetssection of the AD584 product page. Pin ConfigurationFigure 1. 8-Pin TO-99  Figure 2. 8-Lead PDIP Absolute Maximum RatingsParameterRatingInput Voltage VIN to Ground40 VPower Dissipation at 25°C600 mWOperating Junction Temperature Range−55°C to +125°CLead Temperature (Soldering 10 sec)300°CThermal Resistance Junction-to-Ambient (H-08A)150°C/WStresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only; functional operation of the device at these or any other conditions above those indicated in the operational section of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Theory of OperationWith power applied to Pin 8 and Pin 4 and all other pins open, the AD584 produces a buffered nominal 10.0 V output between Pin 1 and Pin 4 (see Figure 3). The stabilized output voltage can be reduced to 7.5 V, 5.0 V, or 2.5 V by connecting the programming pins as shown in Table below. Output Voltage (V)Pin Programming7.5Join the 2.5 V (Pin 3) and 5.0 V (Pin 2) pins.5.0Connect the 5.0 V pin (Pin 2) to the output pin (Pin 1).2.5Connect the 2.5 V pin (Pin 3) to the output pin (Pin 1). The options shown in Table above are available without the use of any additional components. Multiple outputs using only one AD584 can be provided by buffering each voltage programming pin with a unity-gain, noninverting op amp. Figure 3. Variable Output Options The AD584 can also be programmed over a wide range of output voltages, including voltages greater than 10 V, by the addition of one or more external resistors. Figure 3 illustrates the general adjustment procedure, with approximate values given for the internal resistors of the AD584. The AD584 may be modeled as an op amp with a noninverting feedback connection, driven by a high stability 1.215 V band gap reference (see Figure 5 for schematic). When the feedback ratio is adjusted with external resistors, the output amplifier can be made to multiply the reference voltage by almost any convenient amount, making popular outputs of 10.24 V, 5.12 V, 2.56 V, or 6.3 V easy to obtain. The most general adjustment (which gives the greatest range and poorest resolution) uses R1 and R2 alone (see Figure 3). As R1 is adjusted to its upper limit, the 2.5V pin (Pin 3) is connected to the output, which reduces to 2.5 V. As R1 is adjusted to its lower limit, the output voltage rises to a value limited by R2. For example, if R2 is approximately 6 kΩ, the upper limit of the output range is approximately 20 V, even for the large values of R1. Do not omit R2; choose its value to limit the output to a value that can be tolerated by the load circuits. If R2 is zero, adjusting R1 to its lower limit results in a loss of control over the output voltage. When precision voltages are set at levels other than the standard outputs, account for the 20% absolute tolerance in the internal resistor ladder. Alternatively, the output voltage can be raised by loading the 2.5 V tap with R3 alone. The output voltage can be lowered by connecting R4 alone. Either of these resistors can be a fixed resistor selected by test or an adjustable resistor. In all cases, the resistors should have a low temperature coefficient to match the AD584 internal resistors, which have a negative temperature coefficient less than 60 ppm/°C. If both R3 and R4 are used, these resistors should have matching temperature coefficients.  When only small adjustments or trims are required, the circuit  in Figure 4 offers better resolution over a limited trim range. The circuit can be programmed to 5.0 V, 7.5 V, or 10 V, and it can be adjusted by means of R1 over a range of about ±200 mV. To trim the 2.5 V output option, R2 (see Figure 4) can be reconnected to the band gap reference (Pin 6). In this configuration, limit the adjustment to ±100 mV to avoid affecting the performance of the AD584. Performance Over TemperatureEach AD584 is tested at three temperatures over the −55°C to +125°C range to ensure that each device falls within the maximum error band (see Figure 6) specified for a particular grade (that is, S and T grades); three-point measurement guarantees performance within the error band from 0°C to 70°C (that is, J and K grades). The error band guaranteed for the AD584 is the maximum deviation from the initial value at 25°C. Thus, given the grade of the AD584, the maximum total error from the initial tolerance plus the temperature variation can easily be determined. For example, for the AD584T, the initial tolerance is ±10 mV, and the error band is ±15 mV. Therefore, the unit is guaranteed to be 10.000 V ± 25 mV from −55°C to +125°C. Figure 6. Typical Temperature Characteristic Output Current CharacteristicsThe AD584 has the capability to either source or sink current and provide good load regulation in either direction; although, it has better characteristics in the source mode (positive current into the load). The circuit is protected for shorts to either positive supply or ground. Figure 7 shows the output voltage vs. the output current characteristics of the device. Source current is displayed as negative current in the figure, and sink current is displayed as positive current. The short-circuit current (that is, 0 V output) is about 28 mA; however, when shorted to 15 V, the sink current goes to approximately 20 mA. Figure 7. Output Voltage vs. Output Current (Sink and Source) Dynamic PerformanceMany low power instrument manufacturers are becoming increasingly concerned with the turn-on characteristics of the components being used in their systems. Fast turn-on components often enable the end user to keep power off when not needed and yet respond quickly when the power is turned on. Figure 8 displays the turn-on characteristic of the AD584. Figure 8 is generated from cold-start operation and represents the true turn-on waveform after an extended period with the supplies off. Figure 8 shows both the coarse and fine transient characteristics of the device; the total settling time to within ±10 mV is about 180 µs, and there is no long thermal tail appearing after the point. Figure 8. Output Settling Characteristic Noise FilteringThe bandwidth of the output amplifier in the AD584 can be reduced to filter output noise. A capacitor ranging between 0.01 µF and 0.1 µF connected between the CAP and VBG terminals further reduces the wideband and feedthrough noise in the output of the AD584, as shown in Figure 9 and Figure 10. However, this tends to increase the turn-on settling time of the device; therefore, allow for ample warm-up time.  Figure 9. Additional Noise Filtering with an External Capacitor  Figure 10. Spectral Noise Density and Total RMS Noise vs. Frequency Using the Strobe TerminalThe AD584 has a strobe input that can be used to zero the output. This unique feature permits a variety of new applications in signal and power conditioning circuits. Figure 11 illustrates the strobe connection. A simple NPN switch can be used to translate a TTL logic signal into a strobe of the output. The AD584 operates normally when there is no current drawn from Pin 5. Bringing this terminal low, to less than 200 mV, allows the output voltage to go to zero. In this mode, the AD584 is not required to source or sink current (unless a 0.7 V residual output is permissible). If the AD584 is required to sink a transient current while strobe is off, limit the strobe terminal input current by a 100 Ω resistor, as shown in Figure 11. Figure 11. Use of the Strobe Terminal The strobe terminal tolerates up to 5 µA leakage, and its driver should be capable of sinking 500 µA continuous. A low leakage, open collector gate can be used to drive the strobe terminal directly, provided the gate can withstand the AD584 output voltage plus 1 V. Precision High Current SupplyThe AD584 can be easily connected to a power PNP or power PNP Darlington device to provide much greater output current capability. The circuit shown in Figure 12 delivers a precision 10 V output with up to 4 A supplied to the load. If the load has a significant capacitive component, the 0.1 µF capacitor is required. If the load is purely resistive, improved high frequency, supply rejection results from removing the capacitor.  Figure 12. High Current Precision Supply The AD584 can also use an NPN or NPN Darlington transistor to boost its output current. Simply connect the 10 V output terminal of the AD584 to the base of the NPN booster and take the output from the booster emitter, as shown in Figure 13. The 5.0V pin or the 2.5V pin must connect to the actual output in this configuration. Variable or adjustable outputs (as shown in Figure 3 and Figure 4) can be combined with a 5.0 V connection to obtain outputs above 5.0 V.  Figure 13. NPN Output Current Booster The AD584 as a Current LimiterThe AD584 represents an alternative to current limiter diodes that require factory selection to achieve a desired current. Use of current limiting diodes often results in temperature coefficients of 1%/°C. Use of the AD584 in this mode is not limited to a set current limit; it can be programmed from 0.75 mA to 5 mA with the insertion of a single external resistor (see Figure 14). The minimum voltage required to drive the connection is 5 V. Figure 14. A Two-Component Precision Current Limiter Negative Reference Voltages from an AD584The AD584 can also be used in a 2-terminal Zener mode to provide a precision −10 V, −7.5 V, or −5.0 V reference. As shown in Figure 15, the VIN and VOUT terminals are connected together to the positive supply (in this case, ground). The AD584 COMMON pin is connected through a resistor to the negative supply. The output is now taken from the COMMON pin instead of VOUT. With 1 mA flowing through the AD584 in this mode, a typical unit shows a 2 mV increase in the output level over that produced in 3-terminal mode. Also, note that the effective output impedance in this connection increases from 0.2 Ω typical to 2 Ω. It is essential to arrange the output load and the supply resistor, RS, so that the net current through the AD584 is always between 1 mA and 5 mA (between 2 mA and 5 mA for operation beyond 85°C). The temperature characteristics and long-term stability of the device is essentially the same as that of a unit used in standard 3-terminal mode. Figure 15. 2-Terminal, −5 V Reference The AD584 can also be used in 2-terminal mode to develop a positive reference. VIN and VOUT are tied together and to the positive supply through an appropriate supply resistor. The performance characteristics are similar to those of a negative 2-terminal connection. The only advantage of this connection over the standard 3-terminal connection is that a lower primary supply can be used, as low as 0.5 V above the desired output voltage. This type of operation requires considerable attention to load and to the primary supply regulation to ensure that the AD584 always remains within its regulating range of 1 mA to 5 mA (2 mA to 5 mA for operation beyond 85°C). 10 V Reference with Multiplying CMOS DACs or ADCs The AD584 is ideal for application with the AD7533 10-bit multiplying CMOS DAC, especially for low power applications. It is equally suitable for the AD7574 8-bit ADC. In the standard hook-up, as shown in Figure 16, the standard output voltages are inverted by the amplifier/DAC configuration to produce converted voltage ranges. For example, a +10 V reference produces a 0 V to −10 V range. If an OP1177 amplifier is used, total quiescent supply current is typically 2 mA.  Figure 16. Low Power 10-Bit CMOS DAC Application The AD584 is normally used in the −10 V mode with the AD7574 to give a 0 V to +10 V ADC range. This is shown in Figure 17. Bipolar output applications and other operating details can be found in the data sheets for the CMOS products.  Figure 17. AD584 as −10 V Reference for CMOS ADC Precision DAC ReferenceThe AD565A, like many DACs, can operate with an external 10 V reference element (see Figure 19). This 10 V reference voltage is converted into a reference current of approximately 0.5 mA via the internal 19.95 kΩ resistor (in series with the external 100 Ω trimmer). The gain temperature coefficient of the AD565A is primarily governed by the temperature tracking of the 19.95 kΩ resistor and the 5 kΩ/10 kΩ span resistors; this gain temperature coefficient is guaranteed to 3 ppm/°C. Therefore, using the AD584K (at 5 ppm/°C) as the 10 V reference guarantees a maximum full-scale temperature coefficient of 18 ppm/°C more than the commercial range. The 10 V reference also supplies the normal 1 mA bipolar offset current through the 9.95 kΩ bipolar offset resistor. The bipolar offset temperature coefficient thus depends only on the temperature coefficient matching of the bipolar offset resistor to the input reference resistor and is guaranteed to 3 ppm/°C. Figure 18 demonstrates the flexibility of the AD584 applied to another popular digital-to-analog configuration.  Figure 18. Current Output, 8-Bit Digital-to-Analog Configuration  Figure 19. Precision 12-Bit DAC AD584 DatasheetYou can download the datasheet of AD584 from the link given below:AD584 Datasheet AD584 FAQWhat is a precision voltage reference?A voltage reference is a precision device specifically designed to maintain a constant output voltage, even as parameters such as ambient temperature or supply voltage change. The precision of a voltage reference enables its use in several differ- ent types of applications beyond a data converter. How do you find the reference voltage?The reference voltage, 2.56 V, is represented by the maximum conversion value, 1024, so the scaling factor is 1024/2.56 = 400 bits per volt. The input is therefore divided by this factor to obtain a display in volts. What provides a stable reference voltage?Zener diodes are sometimes referred to as reference diodes as they are able to provide a stable reference voltage for many electronics circuits. What is reference voltage automotive?A reference voltage is sent to the sensor from the on-board computer. The sensor's resistance decreases as the engine increases. The temperature of the vehicle can be determined by the computer. When the engine is at operating temperature. How does a 5 volt reference circuit work?The foundational concept is simple: a 5-volt reference flows through a sensor containing a resistance that varies according to changes in temperature, pressure or position. Due to this variable resistance, the signal return voltage to the ECM is always less than the reference voltage. What is the use of reference voltage in ADC?ADCs convert analog inputs that can vary from zero volts on up to a maximum voltage level that is called the reference voltage. The reference voltage determines the ceiling of what the ADC can convert, and is essentially the yardstick against which every proportion and result is measured. What is primary requirement of voltage reference?A voltage reference is an electronic component or circuit that produces a constant DC (direct-current) output voltage regardless of variations in external conditions such as temperature, barometric pressure, humidity, current demand, or the passage of time. How does a 3 wire automotive sensor work?A three-wire sensor has 3 wires present. Two power wires and one load wire. The power wires will connect to a power supply and the remaining wire to some type of load. The load is a device that is being controlled by the sensor. What is a low reference signal?Low reference is a ground circuit but it is sourced through the PCM. The PCM treats it to provide a “clean ground” Normally low reference provides a ground for the electronics in the coil and the coil windings as a load device utilize chassis ground. What is a reference wire?The reference wire is used to determine ambient air temperature as a reference point for the hot wire. The Wheatstone Bridge increases or decreases amperage, in the range of 500 ma to 1,200 ma, to maintain the sensing wire's temperature 100° C above that of the ambient reference wire.