A2TPMI337IRAG9OCA中文资料

FLEX I/O ControlNet Redundant Media Adapter 2Publication 1794-5.18 – September 1996European Union Directive ComplianceIf this product has the CE mark it is approved for installation within the European Union and EEA regions. It has been designed and tested to meet the following directives.EMC DirectiveThis product is tested to meet Council Directive 89/336/EECElectromagnetic Compatibility (EMC) and the following standards, in whole or in part, documented in a technical construction file:•EN 50081-2EMC – Generic Emission Standard, Part 2 – Industrial Environment•EN 50082-2EMC – Generic Immunity Standard, Part 2 – Industrial EnvironmentThis product is intended for use in an industrial environment.Low V oltage DirectiveThis product is tested to meet Council Directive 73/23/EEC Low V oltage,by applying the safety requirements of EN 61131–2 Programmable Controllers, Part 2 – Equipment Requirements and Tests.For specific information required by EN 61131-2, see the appropriate sections in this publication, as well as the following Allen-Bradley publications:•Industrial Automation Wiring and Grounding Guidelines For Noise Immunity, publication 1770-4.1•Guidelines for Handling Lithium Batteries, publication AG-5.4This equipment is classified as open equipment and must be mounted in an enclosure during operation to provide safety protection.FLEX I/O ControlNet Redundant Media Adapter 3Publication 1794-5.18 – September 19961.Position the ControlNet adapter module (A) on a 35 x 7.5mm DIN rail(B) (A-B pt. no. 199-DR1; 46277-3; EN 50022) at a slight angle.2.Hook the lip on the rear of the adapter (A) onto the top of the DIN rail(B ), and rotate the adapter module onto the rail.3.Press the adapter module down onto the DIN rail until flush. Lockingtab (C) will snap into position and lock the adapter module to the DIN rail.4.If the adapter module does not lock in place, use a screwdriver orsimilar device to move the locking tab down while pressing theadapter module flush onto the DIN rail and release the locking tab to lock the adapter module in place. If necessary, push up on the locking tab to lock.5.Connect the adapter wiring as shown under “Wiring” later in thisdocument.!ATTENTION: Make certain that the hook on theterminal base is properly hooked into the adapter. Failureto lock the hook into the adjacent base/adapter can result in loss of communication on the backplane.plete the adapter mounting as shown below.FLEX I/O ControlNet Redundant Media Adapter 4Publication 1794-5.18 – September 1996Wiring1.Connect the ControlNet network cable to connector, terminal A .2.Connect the redundant ControlNet network cable to connector B .3.Connect 24V common to the left side of the upper connector,terminal C .4.Connect +24V dc input to the left side of the lower connector,terminal D .5.Connections E and F are used to pass 24V dc power (F) and 24Vcommon (E) to the next module in the series (if required).6.Set the network address using the 2-position thumbwheel switch G .Valid settings range from 01 to 99. Press either the + or – buttons to change the number.IndicatorsFLEX I/O ControlNet Redundant Media Adapter 5Comm A Comm B StatusComm A and Comm B SimultaneouslyComm A or Comm B (individually)Status IndicatorFLEX I/O ControlNet Redundant Media Adapter 6 ArrayPublication 1794-5.18 – September 1996FLEX I/O ControlNet Redundant Media Adapter 7Publication 1794-5.18 – September 19961770-4.1, “Industrial Automation Wiring and Grounding Guidelines.”Mounting DimensionsInches(Millimeters)(87H x 94W x 69D)A B = DIN rail = Secure DIN rail approximately every 200mmFLEX I/O ControlNet Redundant Media Adapter 8Publication 1794-5.18 – September 1996With major offices worldwide.World Headquarters,Allen-Bradley ,1201 South Second Street,Milwaukee, WI 53204 USA,T el: (1) 414 382-2000 Fax: (1) 414 382-4444Publication 1794-5.18 – September 1996PN955117–39Copyright 1996 Allen-Bradley Company, Inc. Printed in USA。

TASCAM TEAC Professional Division MX-242424-Bit 24-Track Hard Disk RecorderWelcomeCongratulations on your purchase of the MX-2424 24-track 24-bit Hard Disk Recording system. While we share your excitement, we ask that you please review the following before using the MX-2424.Contents of the box•MX-2424 Owners Manual•MX-2424 Owners Manual Updates•SCSI Instructions•Option Installation Instructions•MX-2424 CD-ROM•Smart Media Card•Power cable for front bay drive•Demo song track sheet•MX-2424 Welcome Letter•This Read Me documentWhat is this? Contents of the box explained•Manuals & Instructions: Stuff you should read!•MX-2424 CD-ROM: Contains all the manuals in electronic PDF format, the current version of MX-OS MX-2424 Operating System and ViewNet MX for both Macintosh and Windows.•Smart Media Card: This is used for updating the version of MX-OS in your MX-2424. It is delicate so keep it in its box in a safe place. Refer to the Owner’s Manual section on MX-OS Operations.•Drive Power cable: Use this cable to connect the power from the MX-2424 motherboard to a drive installed in the front bay. Refer to the Option Installation Instructions for details.•Demo song track sheet: There is a pre-loaded demo song in the MX-2424 to listen to and check the connections to your mixer. To load it press PROJ twice, select it with the Arrow keys and press YES.•MX-2424 Welcome Letter: More stuff to read!•This Read Me document: It’s the thing you’re reading…Where to go for support and software updatesSCSI Drive SupportBefore installing any additional SCSI devices, please review the SCSI Instructions.Hard DrivesBackup DrivesThe MX-2424 has the ability to backup data to a SCSI DVD-RAM or Travan tape drive. The following model numbers are supported:Brand Model Type of Device CapacityHitachi GF-2050DVD-RAM9.4GBHitachi GF-1050DVD-RAM 5.2GBPanasonic LF-D103U DVD-RAM 5.2GBCreative Technology RAM1220S DVD-RAM 5.2GBSeagate Hornet NS-20Travan10GBBackup MediaDVD-RAMMedia which adheres to the following requirements may be used for DVD-RAM backup on the MX-2424:• 5.2GB Double Sided•9.4GB Double Sided (Hitachi GF-2050 only)•Rewritable•Type 1Travan•10GB (Uncompressed) Travan Tape MediaTypes of BackupThree types of backup are supported on the MX-2424 using DVD-RAM drives:•FAT-32 Initialized•MacHFS initialized (Only using DVD-RAM Tune-Up on the Mac)•Mac HFS+ initialized (Only using DVD-RAM Tune-Up on the Mac)•Un-initializedWhen a FAT-32 formatted DVD-RAM disk is created on the MX-2424 it will identify is as a FAT-32 volume. Such a disk can be mounted on a PC.An un-initialized DVD-RAM disk will mount on the MX-2424 as a backup (BU) volume. The MX-2424 will back up data to such a disk using an advanced backup program capable of spanning single projects across multiple disks. These disks will not mount or be readable on a computer.It is possible to audition a pair of tracks from a FAT-32, HFS or HFS+ formatted DVD-RAM disk by loading the project directly from the DVD-RAM disk.Mounting a SCSI Hard Drive on a computerWith support for removable drives it is possible to take audio drives back and forth between the MX-2424 and a computer for backup or sharing of audio files between the MX-2424 and a computer-based DAW. MacintoshRequired software:•FWB Hard Disk Toolkit 3.0 or higherThe MX-2424 has the ability to initialize SCSI drives using Menu 710. However, this initialization process does not install a Mac driver onto the disk. The following steps must be taken in order to mount on a Maca disk that has been initialized on the MX-2424:1.Connect the drive to the Macintosh SCSI port. Verify that proper termination and SCSI cabling rulesare followed and boot up the computer system.unch FWB Hard Disk Toolkit. In Device View, under the Device pull down menu, choose the“Update Driver” function.3.Click “Yes” to update the driver.4.Reboot the computer system. This is an FWB requirement – failure to do so will corrupt the disk.5.Once rebooted, the drive will mount and may be used as a standard Mac volume. Note that once thismounting process is performed and the volume has been updated with FWB drivers, there is no need to repeat the above steps in order to mount the drive on a Mac until the drive has been initialized again on the MX-2424.Note: A hard disk formatted to Mac OS Standard on a Macintosh may be taken to the MX-2424 for reliable use. Such a disk does not need to be initialized on the MX-2424 and may be taken back and forth between the two systems without any further driver installation or initialization.NOTE:The MX-2424 does not support hard disks partitioned on the Macintosh.Disk initialization on the MX-2424 will remove Mac driver software.General Tips and Reminders•It is recommended that projects be started at the 01:00:00:00 mark. This is to prevent crossing the 00:00:00:00 point during operation.•Always un-mount disks before turning the unit off by pressing SHIFT+MOUNT.•Un-mount backup media (BU format) from DVD-RAM/Travan drives when recording.•The Render feature is intended to enhance drive performance for sessions with heavy edit density. The Render function can also be used in the rare occurrence that an “Out of Audio Memory” error isencountered.Future EnhancementsWhile the MX-2424 contains an impressive feature set as it is, here are some of the enhancements to be released in the near future:•Waveform editing。

RAC AC/DC ConverterFeaturesRegulated Converter• Wide input range 85-305VAC• Standby mode optimized (eco design Lot 6)• High efficiency over the entire load range • Operating temperature range: -40°C to +90°C • Overvoltage and overcurrent protected• EMC compliant without external components • Encapsulated module with pins or wiredDescriptionThe RAC05-K/277 series are multipurpose 5 watt AC/DC power supplies for enhanced mains input conditions from 90VAC up to 305VAC with an extra wide operating temperature range from -40°C to +90°C. These modules are designed to supply worldwide applications in automation, Industry 4.0, IoT, household and smart buildings. For worldwide use they come with international safety certifications for industrial, domestic and ITE as well as household standards. With both PCB-mount and wired packages, fully protected outputs, and EMC class B emissions compliance without any external components, these are the easiest to use modular power solutions in the industry.E224736RAC05-__ SK/277/WModel NumberingOrdering Examples:RAC05-05SK/277 5 Watt 5Vout Single Output THT version RAC05-24SK/277 5 Watt 24Vout Single Output THT version RAC05-05SK/277/W 5 Watt 5Vout Single Output Wired version RAC05-12SK/277/W5 Watt 12Vout Single Output Wired versionS inglenom. Output PowerOutput Voltage5 Watt Single OutputRAC05-K/277Selection GuidePart Input Output Output Efficiency Max. CapacitiveNumber Voltage Range Voltage Current typ (1) Load (2)[VAC] [VDC] [mA] [%] [µF]RAC05-3.3SK/277 85-305 3.3 1510 77 10000RAC05-05SK/277 85-305 5 1000 80 8000RAC05-12SK/277 85-305 12 416 83 1500RAC05-15SK/277 85-305 15 330 83 1000RAC05-24SK/277 85-305 24 210 84 330Notes:Note1: Efficiency is tested at nominal input and full load at +25°C ambient Note2: Max Cap Load is tested at nominal input and full resistive loadW ired Notes:Note3: add suffix …W“ for wired versionwithout suffix, standard THT versionUL62368-1 certified EN62368-1 certified IEC/EN60335-1 certified EN62233 certifiedIEC/EN61558-1 certified IEC/EN61558-2-16 certified EN55032 compliantEN55014-1(-2) compliant CB ReportSpecifications(measured @ Ta= 25°C, nom. Vin, full load and after warm-up unless otherwise stated)Specifications (measured @ Ta= 25°C, nom. Vin, full load and after warm-up unless otherwise stated)REGULATIONSParameterConditionValueOutput Accuracy ±1.0% typ.Line Regulation low line to high line, full load±0.5% typ. Load Regulation (7)10% to 100% load 1.0% typ.Transient Response25% load step change4.0% max.recovery time500µs typ.PROTECTIONSParameterTypeValueInput Fuse (8)internal T1A, slow blowShort Circuit Protection (SCP)below 100m Whiccup, automatic restart Over Voltage Protection (OVP)125% - 195%, latch of modeOver Voltage Category OVC IIOver Current Protection (OCP)125% - 195%, hiccup modeClass of EquipmentClass IIIsolation Voltage (safety certified) (9)I/P to O/P1 minute4.2kVACIsolation Resistance Isolation Voltage 500VDC 1G W min.Isolation Capacitance 100pF max.Insulation Grade reinforced Leakage Current0.25mA max.continued on next pageDeviation vs. Load(at 115VAC, 230VAC, 277VAC)10.50-0.5-1D e v i a t i o n [%]102030405060708090100Output Load [%]10.5-0.5-1D e v i a t i o n [%]0102030405060708090100Output Load [%]RAC05-05SK/277RAC05-12SK/277Notes:Note8: Refer to local safety regulations if input over-current protection is also required Note9: For repeat Hi-Pot testing, reduce the time and/or the test voltageNotes:Note7: Operation below 10% load will not harm the converter, but specifications may not be metSpecifications(measured @ Ta= 25°C, nom. Vin, full load and after warm-up unless otherwise stated)Specifications(measured @ Ta= 25°C, nom. Vin, full load and after warm-up unless otherwise stated)SAFETY AND CERTIFICATIONSCertificate Type (Safety)Report / File Number StandardAudio/Video, information and communication technology equipment - Part 1: Safety requirements E491408-A6004-ULUL62368-1, 2nd Edition, 2014-12-01CAN/CSA-C22.2 No. 62368-1-14, 2nd Edt., 2014-12Audio/Video, information and communication technology equipment -Part 1: Safety requirements (CB Scheme)E491408-A6007-CB-1IEC62368-1:2014 2nd EditionAudio/Video, information and communication technology equipment -Part 1: Safety requirements (LVD)EN62368-1:2014 + A11:2017Household and similar electrical appliances - Safety -Part 1: General requirementsLCS190308001CS IEC60335-1:2010 + A2:2016 + C1:2016, 5th Edt.EN60335-1:2012 + A13:2017Measurement methods for electromagnetic fields of household appliances and similarapparatus with regard to human exposureEN62233:2008Safety of power transformers, power supplies, reactors and similar products for sup-ply voltages up to 1100 V (CB Scheme)50230493 001IEC61558-1:2005 2nd Edition + A1:2009Safety of power transformers, power supplies, reactors and similar products for sup-ply voltages up to 1100 V Part 2: Particular requirements (CB Scheme)IEC61558-2-16:2009 1st Edition + A1:2013 Safety of power transformers, power supplies, reactors and similar products for sup-ply voltages up to 1100 VEN61558-1:2005 + A1:2009 Safety of power transformers, power supplies, reactors and similar products for sup-ply voltages up to 1100 V Part 2: Particular requirementsEN61558-2-16:2009 + A1:2013 RoHS2RoHS-2011/65/EU + AM-2015/863 EMC Compliance Conditions Standard / Criterion Low-voltage power supplies DC output - Part 3: Electromagnetic compatibility EN61204-3: 2018, Class B Electromagnetic compatibility of multimedia equipment - Emission requirements (11)EN55032:2015, Class B Electromagnetic compatibility - Requirements for household appliances, electric toolsand similar apparatus - Part 1: EmissionEN55014-1:2006 + A2:2011 I nformation technology equipment - Immunity characteristics - Limits and methods of measurement EN55024:2010 + A1:2015 Electromagnetic compatibility - Requirements for household appliances, electric toolsand similar apparatus - Part 2: ImmunityEN55014-2:2015ESD Electrostatic discharge immunity testAir: ±2, 4, 8kVContact: ±2, 4kVEN61000-4-2: 2009, Criteria BRadiated, radio-frequency, electromagnetic field immunity test 10V/m, 80MHz-1GHz3V/m, 1.4GHz-2GHz1V/m, 2GHz-2.7GHzEN61000-4-3: 2006 + A1, 2009, Criteria AFast Transient and Burst Immunity AC and DC Port: ±2kV EN61000-4-4: 2012, Criteria BSurge Immunity AC In Port (L-N): ±1kVDC Output Port: ±0.5kVEN61000-4-5: 2014 +A1:2017, Criteria BImmunity to conducted disturbances, induced by radio-frequency fields AC and DC Port: 10V EN61000-4-6: 2014, Criteria A Power Magnetic Field Immunity50Hz, 30A/m EN61000-4-8: 2010, Criteria AVoltage Dips and InterruptionsVoltage Dips: 30%Voltage Dips: 60%Voltage Dips: 100%Interruptions: >95%EN61000-4-11:2004 + A1:2017, Criteria CEN61000-4-11:2004 + A1:2017, Criteria CEN61000-4-11:2014 + A1:2017, Criteria BEN61000-4-11: 2014 + A1:2017,Criteria CVoltage Fluctuations and Flicker in Public Low-Voltage Systems <=16A per phase EN61000-3-3: 2013 Limitations on the amount of electromagnetic interference allowed from digital and electronic devices FCC 47 CFR Part 15 Supbart B, Class B Methods of Measurement of Radio-Noise Emissions from Low-Voltage Electrical andElectronic Equipment in the Range of 9 kHz to 40 GHzANSI C63.4-2014, Class BNotes:Note11: If output is connected to GND, please contact RECOM tech support for adviceSpecifications(measured @ Ta= 25°C, nom. Vin, full load and after warm-up unless otherwise stated)Specifications (measured @ Ta= 25°C, nom. Vin, full load and after warm-up unless otherwise stated)The product information and specifications may be subject to changes even without prior written notice.The product has been designed for various applications; its suitability lies in the responsibility of each customer. The products are not authorized for use in safety-critical applications without RECOM’s explicit written consent. A safety-critical application is an application where a failure may reasonably be expected to endanger or cause loss of life, inflict bodily harm or damage property. The applicant shall indemnify and hold harmless RECOM, its affiliated companies and its representatives against any damage claims in connection with the unauthorizeduse of RECOM products in such safety-critical applications.PACKAGING INFORMATIONParameterTypeValuePackaging Dimension (LxWxH)THT wiredtube tray466.0 x 30.4 x 29.3mm 468.0 x 198.0 x 46.0mmPackaging Quantity THT wired12pcs 24pcsStorage Temperature Range -40°C to +85°C Storage Humiditynon-condensing 20% to 90% RH max.。

TECHNICAL DATAFluke ii900 Sonic Industrial ImagerSOUNDSIGHT™ TECHNOLOGYACOUSTIC IMAGING Blended live SoundMap™ with visual imageSENSITIVITY Detects 0.005 CFM leak at 100PSI from up to 32.8 feet*FREQUENCY RANGE from 2kHz to 52kHzMAXIMUM OPERATING DISTANCE Up to 164 feet (50 meters)*DISPLAY 7 inch 1280 x 800 LCD with capacitive touchscreen Leaks in compressed air, gas and vacuum systems hit both production uptime and the operations bottom line.While this is a known issue, locating air leaks has been a time-con-suming and tedious–until now. With the Fluke ii900 Sonic Industrial Imager your maintenance team can quickly pinpoint the location of compressed air and vacuum leaks. With minimal training, your maintenance technicians can begin checking for air leaks during their typical maintenance routine–even during peak operation hours.This industrial imager offers a new way to locate issues using sound. It is an intuitive, simple to use tool that can isolate the frequency of leaks or vacuums, even in extremely noisy production environ-ments. A leak location is determined by discerning the direction from which a sound originates by the time delays that occur as the sound passes over an array of microphones. A SoundMap™ is displayed in color over a visual image allowing for easy visual location. With the full array of microphones, it is easy to scan a large area and even capture leaks from a distance.Finally a better way, quick, simple compressed air, gas and vacuum leak identification.• Do more with the same air compressors–delay the capital expense of installing an additional compressor• Ensure proper air pressure to your pneumatic equipment• Lower energy costs• Reduce leak detection time• Improve reliability in your production line• Make leak detection part of your typical maintenance routine • Train the team in a matter of minutes • Validate repairs on the spotSoundSight™ refers to the Fluke technology of converting sound waves to a visual image.*Depending on ambient conditionsSpecifications*Depending on ambient conditions2 Fluke Corporation Fluke ii900 Sonic Industrial Imager3 Fluke Corporation Fluke ii900 Sonic Industrial Imager Ordering informationFLK-ii900 Sonic Industrial Imager Included Imager; AC power supply and battery pack charger (including universal AC adapters); two rugged lithium ion smart battery packs; USB cable; rugged, hard carrying case; two rubber array covers; adjustable hand strap and adjustable neck strap.Visit your local Fluke website or contact your local Fluke representative for more information.Fluke Corporation PO Box 9090, Everett, WA 98206 U.S.A.Fluke Europe B.V. PO Box 1186, 5602 BD Eindhoven, The Netherlands Fluke. Keeping your world up and running.®For more information call: In the U.S.A. (800) 443-5853 or Fax (425) 446-5116 In Europe/M-East/Africa +31 (0)40 267 5100 or Fax +31 (0)40 267 5222 In Canada (800)-36-FLUKE or Fax (905) 890-6866 From other countries +1 (425) 446-5500 or Fax +1 (425) 446-5116 Web access: ©2019 Fluke Corporation. Specifications subject to change without notice. 3/2019 6012097b-en Modification of this document is not permitted without written permission from Fluke Corporation.Images taken with the ii900 Sonic Industrial Imager in an industrial environment.。

AT88SC0808CAAtmel CryptoMemorySUMMARY DATASHEETFeatures ∙ One of a family of devices with user memories from 1-Kbit to 8-Kbits ∙8-Kbit (1-Kbyte) EEPROM user memory∙ Eight 1-Kbit (128-byte) zones ∙ Self-timed write cycle∙ Single byte or 16-byte page write mode ∙ Programmable access rights for each zone∙ 2-Kbit configuration zone∙ 37-byte OTP (One-Time Programmable) area for user-defined codes ∙ 160-byte area for user-defined keys and passwords ∙High security features∙ 64-bit mutual authentication protocol (under license of ELVA) ∙ Cryptographic Message Authentication Codes (MAC) ∙ Stream encryption∙ Four key sets for authentication and encryption ∙ Eight sets of two 24-bit passwords ∙ Anti-tearing function∙ Voltage and frequency monitors∙Smart card features∙ ISO 7816 Class B (3V) operation∙ ISO 7816-3 asynchronous T=0 Protocol (Gemplus ®Patent) * ∙ Multiple zones, key sets and passwords for multi-application use ∙ Synchronous 2-wire serial interface for faster device initialization * ∙ Programmable 8-byte answer-to-reset register (ATR) ∙ISO 7816-2 compliant modules∙Embedded application features∙ Low voltage supply: 2.7V – 3.6V∙ Secure nonvolatile storage for sensitive system or user information ∙ 2-wire serial interface (TWI, 5V compatible) ∙ 1.0MHz compatibility for fast operation∙ Standard 8-lead plastic packages, green compliant (exceeds RoHS)∙Same pin configuration as Atmel ®AT24CXXX Serial EEPROM in SOIC and PDIP packages∙High reliability∙ Endurance: 100,000 cycles ∙ Data retention: 10 years ∙ ESD protection: 2,000V min* Note: Modules available with either T=0 / 2-wire modes or 2-wire mode onlyThis is a summary document. The complete document is available on the Atmel website at .AT88SC0808CA [Summary DATASHEET]Atmel-5204IS-CryptoMem-AT88SC0808CA-Datasheet-Summary_0720152Table 1. Pin AssignmentsPin Configuration123487658-lead SOIC, PDIPNC NCNC GNDV CCNC SCL SDA8-lead TSSOPNCV CC 81NC C N 72NCK L C 63GND 54SDA 12348765SDA GND CLK V CC8-lead Ultra Thin Mini-MAP (MLP 2x3)Bottom ViewNCNC NC NC TWI Smart Card ModuleV C C =C1 NC =C2 SCL/CLK=C3NC=C4C5=GND C6=NC C7=S D A /IO C8=NCISO Smart Card ModuleV C C =C1 RST=C2 SCL/CLK=C3NC=C4C5=GND C6=NC C7=S D A /IO C8=NCAT88SC0808CA [Summary DATASHEET]Atmel-5204IS-CryptoMem-AT88SC0808CA-Datasheet-Summary_07201531. DescriptionThe Atmel AT88SC0808CA member of the Atmel CryptoMemory ®family is a high-performance secure memory providing 8-Kbit of user memory with advanced security and cryptographic features built in. The user memory is divided into eight128-byte zones, each of which may be individually set with different security access rights or effectively combined together to provide space for one to eight data files. The AT88SC0808CA features an enhanced command set that allows directcommunication with microcontroller hardware 2-wire interface thereby allowing for faster firmware development with reduced code space requirements.1.1 Smart Card ApplicationsThe AT88SC0808CA provides high security, low cost, and ease of implementation without the need for a microprocessor operating system. The embedded cryptographic engine provides for dynamic, symmetric-mutual authentication between the device and host, as well as performing stream encryption for all data and passwords exchanged between the device and host. Up to four unique key sets may be used for these operations. The AT88SC0808CA offers the ability to communicate with virtually any smart card reader using the asynchronous T = 0 protocol (Gemplus Patent) defined in ISO 7816-3.1.2 Embedded ApplicationsThrough dynamic, symmetric-mutual authentication, data encryption, and the use of cryptographic Message Authentication Codes (MAC), the AT88SC0808CA provides a secure place for storage of sensitive information within a system. With its tamper detection circuits, this information remains safe even under attack. A 2-wire serial interface running at speeds up to 1.0MHz provides fast and efficient communications with up to 15 individually addressable devices. The AT88SC0808CA is available in industry standard 8-lead packages with the same familiar pin configuration as Atmel AT24CXXX Serial EEPROM devices. Note:Does not apply to either the TSSOP or the Ultra Thin Mini-Map pinoutsFigure 1-1. Block DiagramV CC GNDSCL/CLK SDA/IORSTAT88SC0808CA [Summary DATASHEET]Atmel-5204IS-CryptoMem-AT88SC0808CA-Datasheet-Summary_07201542. Connection DiagramFigure 2-1. Connection Diagram3.Pin Descriptions3.1Supply Voltage (V CC )The V CC input is a 2.7V to 3.6V positive voltage supplied by the host.3.2 Clock (SCL/CLK)When using the asynchronous T = 0 protocol, the CLK (SCL) input provides the device with a carrier frequency f . The nominal length of one bit emitted on I/O is defined as an “elementary time unit” (ETU) and is equal to 372/ f .When using the synchronous protocol, data clocking is done on the positive edge of the clock when writing to the device and on the negative edge of the clock when reading from the device.3.3 Reset (RST)The AT88SC0808CA provides an ISO 7816-3 compliant asynchronous answer-to-reset (ATR) sequence. Upon activation of the reset sequence, the device outputs bytes contained in the 64-bit ATR register. An internal pull-up on the RST input pad allows the device to operate in synchronous mode without bonding RST. The AT88SC0808CA does not support an ATR sequence in the synchronous mode of operation.3.4 Serial Data (SDA/IO)The SDA/IO pin is bidirectional for serial data transfer. This pin is open-drain driven and may be wired with any number of other open-drain or open-collector devices. An external pull-up resistor should be connected between SDA/IO and V CC . The value of this resistor and the system capacitance loading the SDA/IO bus will determine the rise time of SDA/IO. This rise time will determine the maximum frequency during read operations. Low value pull-up resistors will allow higher frequency operations while drawing higher average power supply current. SDA/IO information applies to both asynchronous andsynchronous protocols.AT88SC0808CA [Summary DATASHEET]Atmel-5204IS-CryptoMem-AT88SC0808CA-Datasheet-Summary_07201554. Absolute Maximum Ratings**Notice:Stresses beyond those listed under “AbsoluteMaximum Ratings” may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other condition beyond those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods of time may affect device reliability.Table 4-1.DC CharacteristicsApplicable over recommended operating range from V CC = +2.7 to 3.6V, T AC = -40°C to +85°C (unless otherwise noted)Note:1. To prevent latch up conditions from occurring during power up of the AT88SC0808CA, V CC must be turned onbefore applying V IH . For powering down, V IH must be removed before turning V CC off.AT88SC0808CA [Summary DATASHEET]Atmel-5204IS-CryptoMem-AT88SC0808CA-Datasheet-Summary_0720156Table 4-2.AC CharacteristicsApplicable over recommended operating range from V CC = +2.7 to 3.6V, T AC = -40°C to +85°C, CL = 30pF (unless otherwise noted)5.Device Operations for Synchronous Protocols5.1Clock and Data TransitionsThe SDA pin is normally pulled high with an external device. Data on the SDA pin may change only during SCL low time periods (see Figure 5-3 on page 8). Data changes during SCL high periods will indicate a start or stop condition as defined below.5.1.1 Start conditionA high-to-low transition of SDA with SCL high defines a start condition which must precede all commands (see Figure 5-4 on page 8).5.1.2 Stop conditionA low-to-high transition of SDA with SCL high defines a stop condition. After a read sequence, the stop condition will place the EEPROM in a standby power mode (see Figure 5-4 on page 8).5.1.3 AcknowledgeAll addresses and data words are serially transmitted to and from the EEPROM in 8-bit words. The EEPROM sends a zero to acknowledge that it has received each word. This happens during the ninth clock cycle (see Figure 5-5 on page 8).AT88SC0808CA [Summary DATASHEET]Atmel-5204IS-CryptoMem-AT88SC0808CA-Datasheet-Summary_07201575.2 Memory ResetAfter an interruption in communication due protocol errors, power loss or any reason, perform "Acknowledge Polling" to properly recover from the condition. Acknowledge polling consists of sending a start condition followed by a valid CryptoMemory command byte and determining if the device responded with an acknowledge. Figure 5-1. Bus Time for 2-wire Serial CommunicationsSCL: Serial Clock, SDA: Serial Data I/OFigure 5-2. Write Cycle TimingSCL: Serial Clock, SDA: Serial Data I/ONote:The write cycle time t WR is the time from a valid stop condition of a write sequence to the end of the internal clear/write cycleSCLSDA INSDA OUTAT88SC0808CA [Summary DATASHEET]Atmel-5204IS-CryptoMem-AT88SC0808CA-Datasheet-Summary_0720158Figure 5-3. Data ValidityFigure 5-4. START and STOP DefinitionsFigure 5-5. Output AcknowledgeST ARTACKNOWLEDGESCLDAT A INDAT A OUT189AT88SC0808CA [Summary DATASHEET]Atmel-5204IS-CryptoMem-AT88SC0808CA-Datasheet-Summary_07201596.Device Architecture6.1User ZonesThe EEPROM user memory is divided into eight zones of 1-Kbit each. Multiple zones allow for storage of different types of data or files in different zones. Access to user zones is permitted only after meeting proper security requirements. These security requirements are user definable in the configuration memory during device personalization. If the same security requirements are selected for multiple zones, then these zones may effectively be accessed as one larger zone. Figure 6-1. User Zones7. Control LogicAccess to the user zones occur only through the control logic built into the device. This logic is configurable through access registers, key registers and keys programmed into the configuration memory during device personalization. Also implemented in the control logic is a cryptographic engine for performing the various higher-level security functions of the device.AT88SC0808CA [Summary DATASHEET]Atmel-5204IS-CryptoMem-AT88SC0808CA-Datasheet-Summary_072015108. Configuration MemoryThe configuration memory consists of 2048 bits of EEPROM memory used for storage of passwords, keys, codes, and also used for definition of security access rights for the user zones. Access rights to the configuration memory are defined in the control logic and are not alterable by the user after completion of personalization. Figure 8-1. Configuration Memory9. Security FusesThere are three fuses on the device that must be blown during the device personalization process. Each fuse locks certain portions of the configuration zone as OTP (One-Time Programmable) memory. Fuses are designed for the modulemanufacturer, card manufacturer and card issuer and should be blown in sequence, although all programming of the device and blowing of the fuses may be performed at one final step.10. Communication Security ModesCommunications between the device and host operate in three basic modes. Standard mode is the default mode for thedevice after power-up. Authentication mode is activated by a successful authentication sequence. Encryption mode isactivated by a successful encryption activation following a successful authentication.Table 10-1. Communication Security Modes(1)Note: 1. Configuration data include viewable areas of the configuration zone except the passwords:•MDC: Modification Detection Code•MAC: Message Authentication Code11. Security Options11.1 Anti-TearingIn the event of a power loss during a write cycle, the integrity of the device’s stored data is recoverable. This function isoptional: the host may choose to activate the anti-tearing function, depending on application requirements. When anti-tearing is active, write commands take longer to execute, since more write cycles are required to complete them, and data is limited toa maximum of eight bytes for each write request.Data is written first into a buffer zone in EEPROM instead of the intended destination address, but with the same accessconditions. The data is then written in the required location. If this second write cycle is interrupted due to a power loss, the device will automatically recover the data from the system buffer zone at the next power-up. Non-volatile buffering of the data is done automatically by the device.During power-up in applications using anti-tearing, the host is required to perform ACK polling in the event that the deviceneeds to carry out the data recovery process.11.2 Write LockIf a user zone is configured in the write lock mode, the lowest address byte of an 8-byte page constitutes a write access byte for the bytes of that page.Example: The write lock byte at $080 controls the bytes from $081 to $087Figure 11-1. Write Lock ExampleThe write lock byte itself may be locked by writing its least significant (rightmost) bit to “0”. Moreover, when write lock mode is activated, the write lock byte can only be programmed – that is, bits written to “0” cannot return to “1”.In the write lock configuration, write operations are limited to writing only one byte at a time. Attempts to write more than one byte will result in writing of just the first byte into the device.11.3 Password VerificationPasswords may be used to protect read and/or write access of any user zone. When a valid password is presented, it ismemorized and active until power is turned off, unless a new password is presented or RST becomes active. There are eight password sets that may be used to protect any user zone. Only one password is active at a time. Presenting the correct write password also grants read access privileges.11.4 Authentication ProtocolThe access to a user zone may be protected by an authentication protocol. Any one of four keys may be selected to use with a user zone.Authentication success is memorized and active as long as the chip is powered, unless a new authentication is initialized or RST becomes active. If the new authentication request is not validated, the card loses its previous authentication which must be presented again to gain access. Only the latest request is memorized. Figure 11-2. Password and Authentication OperationsNote:Authentication and password verification may be attempted at any time and in any order. Exceedingcorresponding authentication or password attempts trial limit renders subsequent authentication or password verification attempts futile.READ ACCESSWRITE ACCESS11.5 Cryptographic Message Authentication CodesAT88SC0808CA implements a data validity check function in the standard, authentication or encryption modes of operation.In the standard mode, data validity check is done through a Modification Detection Code (MDC), in which the host may read an MDC from the device in order to verify that the data sent was received correctly.In authentication and encryption modes, the data validity check becomes more powerful since it provides a bidirectional data integrity check and data origin authentication capability in the form of a Message Authentication Codes (MAC). Only thehost/device that carried out a valid authentication is capable of computing a valid MAC. While operating in the authentication or encryption modes, the use of MAC is required. For an ingoing command, if the device calculates a MAC different from the MAC transmitted by the host, not only is the command abandoned but the security privilege is revoked. A new authentication and/or encryption activation will be required to reactivate the MAC.11.6 EncryptionThe data exchanged between the device and the host during read, write and verify password commands may be encrypted to ensure data confidentiality.The issuer may choose to require encryption for a user zone by settings made in the configuration memory. Any one of four keys may be selected for use with a user zone. In this case, activation of the encryption mode is required in order to read/write data in the zone and only encrypted data will be transmitted. Even if not required, the host may still elect to activate encryption provided the proper keys are known.11.7 Supervisor ModeEnabling this feature allows the holder of one specific password to gain full access to all eight password sets, including the ability to change passwords.11.8 Modify ForbiddenNo write access is allowed in a user zone protected with this feature at any time. The user zone must be written during device personalization prior to blowing the security fuses.11.9 Program OnlyFor a user zones protected by this feature, data can only be programmed (bits change from a “1” to a “0”), but not erased (bi ts change from a “0” to a “1”).12. Protocol SelectionThe AT88SC0808CA supports two different communication protocols.∙ Smartcard Applications:Smartcard applications use ISO 7816-B protocol in asynchronous T = 0 mode for compatibility and interoperability with industry standard smartcard readers.∙ Embedded Applications:A 2-wire serial interface provides fast and efficient connectivity with other logic devices or microcontrollers.The power-up sequence determines establishes the communication protocol for use within that power cycle. Protocol selection is allowed only during power-up.12.1 Synchronous 2-wire Serial InterfaceThe synchronous mode is the default mode after power up. This is due to the presence of an internal pull-up on RST. For embedded applications using CryptoMemory in standard plastic packages, this is the only available communication protocol.∙ Power-up V CC , RST goes high also∙ After stable V CC , SCL(CLK) and SDA(I/O) may be driven∙ Once synchronous mode has been selected, it is not possible to switch to asynchronous mode without first poweringoff the deviceFigure 12-1. Synchronous 2-wire ProtocolNote: Five clock pulses must be sent before the first command is issued.V cc I/O-SDARST CLK-SCL1234512.2 Asynchronous T = 0 ProtocolThis power-up sequence complies to ISO 7816-3 for a cold reset in smart card applications.∙ V CC goes high; RST, I/O (SDA) and CLK (SCL) are low ∙ Set I/O (SDA) in receive mode ∙ Provide a clock signal to CLK (SCL) ∙RST goes high after 400 clock cyclesThe device will respond with a 64-bit ATR code, including historical bytes to indicate the memory density within the CryptoMemory family.Once asynchronous mode has been selected, it is not possible to switch to synchronous mode without first powering off the device.Figure 12-2. Asynchronous T = 0 Protocol (Gemplus Patent)13. Initial Device ProgrammingEnabling the security features of CryptoMemory requires prior personalization. Personalization entails setting up of desired access rights by zones, passwords and key values, programming these values into the configuration memory with verification using simple write and read commands, and then blowing fuses to lock this information in place.Gaining access to the configuration memory requires successful presentation of a secure (or transport) code. The initial signature of the secure (transport) code for the AT88SC0808CA device is $22 E8 3F. This is the same as the Write 7 password. The user may elect to change the signature of the secure code anytime after successful presentation.After writing and verifying data in the configuration memory, the security fuses must be blown to lock this information in the device. For additional information on personalizing CryptoMemory, please see the application notes ProgrammingCryptoMemory for Embedded Applications and Initializing CryptoMemory for Smart Card Applications from the product page at /products/securemem .V cc I/O-SDARSTCLK-SCL14. Ordering InformationNote: 1. Formal drawings may be obtained from an Atmel sales office.2. Both the J and P module packages are used for either ISO (T=0 / 2-wire mode) or TWI (2-wire mode only).15. Package InformationOrdering Code: MJ or MJTG Ordering Code: MP or MPTGModule Size: M2Dimension*: 12.6 x 11.4 [mm] Glob Top: Round - ∅8.5 [mm] Thickness: 0.58 [mm]Pitch: 14.25mm Module Size: M2Dimension*: 12.6 x 11.4 [mm]Glob Top: Square - 8.8 x 8.8 [mm] Thickness: 0.58 [mm]Pitch: 14.25mmNote: *The module dimensions listed refer to the dimensions of the exposed metal contact area. The actual dimensions of the module after excise or punching from the carrier tape are generally 0.4mm greater in both directions(i.e., a punched M2 module will yield 13.0 x 11.8mm).15.1 Atmel AT88SC0808CA Package Marking Information15.2 Ordering Code: SH8S1 – 8-lead JEDEC SOIC15.3 Ordering Code: PU8P3 – 8-lead PDIPAT88SC0808CA [Summary DATASHEET]Atmel-5204IS-CryptoMem-AT88SC0808CA-Datasheet-Summary_0720152115.4Ordering Code: TH 8X – 8-lead TSSOPAT88SC0808CA [Summary DATASHEET]Atmel-5204IS-CryptoMem-AT88SC0808CA-Datasheet-Summary_0720152215.5Ordering Code: Y6H-T8MA2 – 8-lead Ultra Thin Mini-MapAT88SC0808CA [Summary DATASHEET]Atmel-5204IS-CryptoMem-AT88SC0808CA-Datasheet-Summary_0720152316. Revision History。

全系列三极管应用参数和代换大全名称封装极性功能耐压电流功率频率配对管D633 28 NPN 音频功放开关100V 7A 40W 达林顿9013 21 NPN 低频放大50V 0.5A 0.625W 9012 9014 21 NPN 低噪放大50V 0.1A 0.4W 150HMZ 9015 9015 21 PNP 低噪放大50V 0.1A 0.4W 150MHZ 9014 9018 21 NPN 高频放大30V 0.05A 0.4W 1000MHZ8050 21 NPN 高频放大40V 1.5A 1W 100MHZ 8550 8550 21 PNP 高频放大40V 1.5A 1W 100MHZ 8050 2N2222 21 NPN 通用60V 0.8A 0.5W 25／200NS2N2369 4A NPN 开关40V 0.5A 0.3W 800MHZ2N2907 4A NPN 通用60V 0.6A 0.4W 26／70N S2N3055 12 NPN 功率放大100V 15A 115W MJ29 552N3440 6 NPN 视放开关450V 1A 1W 15MHZ 2N66 092N3773 12 NPN 音频功放开关160V 16A 50W2N3904 21E NPN 通用60V 0.2A2N2906 21C PNP 通用40V 0.2A2N2222A 21铁NPN 高频放大75V 0.6A 0.625W 300MHZ 2N6718 21铁NPN 音频功放开关100V 2A 2W2N5401 21 PNP 视频放大160V 0.6A 0.625W 100MHZ 2N55 512N5551 21 NPN 视频放大160V 0.6A 0.625W 100MHZ 2N54 012N5685 12 NPN 音频功放开关60V 50A 300W2N6277 12 NPN 功放开关180V 50A 250W9012 21 PNP 低频放大50V 0.5A 0.625W 9013 2N6678 12 NPN 音频功放开关650V 15A 175W 15MHZ9012 贴片PNP 低频放大50V 0.5A 0.625W 9013 3DA87A 6 NPN 视频放大100V 0.1A 1W3DG6B 6 NPN 通用20V 0.02A 0.1W 150MHZ3DG6C 6 NPN 通用25V 0.02A 0.1W 250MHZ3DG6D 6 NPN 通用30V 0.02A 0.1W 150MHZMPSA42 21E NPN 电话视频放大300V 0.5A 0.625W MPSA 92MPSA92 21E PNP 电话视频放大300V 0.5A 0.625W MPSA 42MPS2222A 21 NPN 高频放大75V 0.6A 0.625W 300MHZ9013 贴片NPN 低频放大50V 0.5A 0.625W 9012 3DK2B 7 NPN 开关30V 0.03A 0.2W3DD15D 12 NPN 电源开关300V 5A 50W3DD102C 12 NPN 电源开关300V 5A 50W3522V 5V稳压管A634 28E PNP 音频功放开关40V 2A 10WA708 6 PNP 音频开关80V 0.7A 0.8WA715C 29 PNP 音频功放开关35V 2.5A 10W 160MHZA733 21 PNP 通用50V 0.1A 180MHZA741 4 PNP 开关20V 0.1A 70／120NS A781 39B PNP 开关20V 0.2A 80／160NS A928 ECB PNP 通用20V 1A 0.25WA933 21 PNP 通用50V 0.1A 140MHZA940 28 PNP 音频功放开关150V 1.5A 25W 4MHZ C207 3A966 21 PNP 音频激励输出30V 1.5A 0.9W 100MHZ C223 6A950 21 PNP 通用30V 0.8A 0.6WA968 28 PNP 音频功放开关160V 1.5A 25W 100MHZ C223 8A1009 BCE PNP 功放开关350V 2A 15WA1220P 29 PNP 音频功放开关120V 1.5A 20W 150MHZA1013 21 PNP 视频放大160V 1A 0.9W C238 3A1015 21 PNP 通用60V 0.1A 0.4W 8MHZ C181 52N6050 12 PNP 音频功放开关60V 12A 150W2N6051 12 PNP 音频功放开关80V 12A 150WA1175 PNP 通用60V 0.10A 0.25W 180MHZ A1213 贴片PNP 超高频50V 0.15A 80MHZA719 ECB PNP 通用30V 0.50A 0.625W 200MHZ B12 G－PNP 音频30V 0.05A 0.05WB1114 ECB PNP 通用贴片20V 2A 180MHZ B205 锗管PNP 音频功放开关80V 20A 80WB1215 BCE PNP 功放开关贴片120V 3A 20W 130MHZ C294 6 NPN 栾生对管25V 0.05A 200MHZ C1044 6 NPN 视放45V 0.3A 2.2GHZ C1216 6 NPN 高速开关40V 0.2A T，20ｎS C1344 ECB NPN 通用低噪30V 0.10 230MHZ C1733 6 NPN 栾生对管30V 0.05A 2GHZC1317 21ECB NPN 通用30V 0.5A 0.625W 200MHZ C546 21ECB NPN 高放30V 0.03A 0.15W 600MHZ C680 11 NPN 音频功放开关200V 2A 30W 20MHZC665 12 NPN 音频功放开关125V 5A 50W 15MHZC4581 BCE NPN 电源开关600V 10A 65W 20MHZ C4584 BCE NPN 电源开关1200V 6A 65W 20MHZC4897 BCE NPN 行管1500V 20A 150WC4928 BCE NPN 行管1500V 15A 150W C5411 BCE NPN 彩显行管17”1500V 14A 60W HQ1F3P 贴片NPN 功放开关20V 2A 2WTIP132 28 NPN 音频功放开关100V 8A 70W TIP1 37A1020 21 PNP 音频开关50V 2A 0.9W A1123 21 PNP 低噪放大150V 0.05A 0.75W A1162 21D PNP 通用贴片50V 0.15A 0.15WA1216 BCE PNP 功放开关180V 17A 200W 20MHZ C292 2A1265 BCE PNP 功放开关140V 10A 100W 30MHZ C318 2A1295 BCE PNP 功放开关230V 17A 200W 30MHZ C326 4A1301 BCE PNP 功放开关160V 12A 120W 30MHZ C328 0C3280 BCE NPN 功放开关160V 12A 120W 30MHZ A130 1A1302 BCE PNP 功放开关200V 15A 120W 30MHZ C328 1C3281 BCE NPN 功放开关200V 15A 120W 30MHZ A130 2A1358 BCE PNP 120V 1A 10W 120MHZ A1444 BCE PNP 高速电源开关100V 15A 30W 80MHZA1494 BCE PNP 功放开关200V 17A 200W 20MHZ C385 8A1516 BCE PNP 功放开关180V 12A 130W 25MHZ A1668 BCE PNP 电源开关200V 2A 25W 20MHZ A1785 BCE PNP 驱动120V 1A 1W 140MHZA1941 BCE PNP 音频功放形状140V 10A 100W C519 8C5198 BCE NPN 音频功放形状140V 10A 100W A194 1A1943 BCE PNP 功放开关230V 15AA 150W C520 0C5200 BCE NPN 功放开关230V 15A 150W A194 3A1988 BCE PNP 功放开关B449 锗管12 PNP 功放开关50V 3.5A 22.5WB647 21 PNP 通用120V 1A 0.9W 140MHZ D667 D667 21 NPN 通用120V 1A 0.9W 140MHZ B649 B1375 BCE PNP 音频功放60V 3A 2W 9MHZD40C BCE NPN 0.5A 40W 75MH对讲机用40VB688 BCE PNP 音频功放开关120V 8A 80W D718 B734 39B PNP 通用60V 1A 1W D774 B649 29 PNP 视放180V 1.5A 20W D669 D669 29 NPN 视频放大180V 1.5A 20W 140MHZ B649 B669 28 PNP 达林顿功放70V 4A 40WB675 28 PNP 达林顿功放60V 7A 40WB673 28 PNP 达林顿功放100V 7A 40WB631K 29 PNP 音频功放开关120V 1A 8W 130MHZ D600 KD600K 29 NPN 音频功放开关120V 1A 8W 130MHZ B631 KC3783 BCE NPN 高压高速开关900V 5A 100WB1400 28B PNP 达林顿功放120V 6A 25W D159 0B744 29 PNP 音频功放开关70V 3A 10WB1020 28 PNP 功放开关100V 7A 40WB1240 39B PNP 功放开关40V 2A 1W 100MHZB1185 28B PNP 功放开关60V 3A 25W 70MHZ D176 2B1079 30 PNP 达林顿功放100V 20A 100W D155 9B772 29 PNP 音频功放开关40V 3A 10W D882 B774 21 PNP 通用30V 0.1A 0.25WB817 30 PNP 音频功放形状160V 12A 100W D104 7B834 28 PNP 功放开关60V 3A 30W B1316 54B PNP 达林顿功放100V 2A 10WB1317 BCE PNP 音频功放180V 15A 150W D197 5B1494 BCE PNP 达林顿功放120V 20A 120W D225 6B1429 BCE PNP 功放开关180V 15A 150WC380 21 NPN 高频放大35V 0.03A 250MHZ C458 21 NPN 通用30V 0.1A 230MHZ C536 21 NPN 通用40V 0.1A 180MHZ2N6609 12 PNP 音频功放开关160V 15A 150W ＞2MHZ 2N37 73C3795 BCE NPN 高压高速开关900V 5A 40WC2458 21ECB NPN 通用低噪50V 0.15A 0.2WC3030 BCE NPN 开关管900V 7A 80W. 达林顿C3807 BCE NPN 低噪放大30V 2A 1.2W 260MHZC3858 BCE NPN 功放开关200V 17A 200W 20MHZ A149 4D985 29 NPN 达林顿功放150V ±1.5A10WC2036 29 NPN 高放低噪80V 1A 1－4WC2068 28E NPN 视频放大300V 0.05A 1.5W 80MHZC2073 28 NPN 功率放大150V 1.5A 25W 4MHZ A940 C3039 28 NPN 电源开关500V 7A 50WC3058 12 NPN 开关管600V 30A 200WC3148 28 NPN 电源开关900V 3A 40WC3150 28 NPN 电源开关900V 3A 50WC3153 30 NPN 电源开关900V 6A 100WC3182 30 NPN 功放开关140V 10A 100W A126 5C3198 21 NPN 高频放大60V 0.15A 0.4W 130MHZ3DK4B 7 NPN 开关40V 0.8A 0.8W3DK7C 7 NPN 开关25V 0.05A 0.3W3D15D 12 NPN 电源开关300V 5A 50WC2078 28 NPN 音频功放开关80V 3A 10W 150MHZC2120 21 NPN 通用30V 0.8A 0.6WC2228 21 NPN 视频放大160V 0.05A 0.75WC2230 21 NPN 视频放大200V 0.1A 0.8WC2233 28 NPN 音频功放开关200V 4A 40WC2236 21 NPN 通用30V 1.5A 0.9W A966 C1733 小铁NPN 孪生对管30V 2GHZ C1317 21EBC NPN 通用30V 0.5A 0.625W 200MHZC2238 28 NPN 音频功放开关160V 1.5A 25W 100MHZ A968 C752 21 NPN 通用30V 0.1A 300MHZC815 21 NPN 通用60V 0.2A 0.25WC828 21 NPN 通用45V 0.05A 0.25WC900 21 NPN 低噪放大30V 0.03A 100MHZC945 21 NPN 通用50V 0.1A 0.5W 250MHZC1008 21 NPN 通用80V 0.7A 0.8W 50MHZC1162 21 NPN 音频功放35V 1.5A 10WC1213 39B NPN 监视器专用30V 0.5A 0.4WC1222 21 NPN 低噪放大60V 0.1A 100MHZC1494 40A NPN 发射36V 6A PQ=40W 175MHZC1507 28 NPN 视放300V 0.2A 15WC1674 21 NPN HF/ZF 30V 0.02A 600MHZC1815 21 NPN 通用60V 0.15A 0.4W 8MHZ A101 5C1855 21F NPN HF/ZF 20V 0.02A 550MHZ C1875 12 NPN 彩行1500V 3.5A 50WC1906 21 NPN 高频放大30V 0.05A 1000MHZ C1942 12 NPN 彩行1500V 3A 50WC1959 21 NPN 通用30V 0.4A 0.5W 300MHZ C1970 28 NPN 手机发射40V 0.6A PQ=1.3W 175MHZC1971 28A NPN 手机发射35V 2A PQ-7.0W 175MHZ C1972 28A NPN 手机发射35V 3.5A PQ=15W 175MHZ C2320 21 NPN 通用50V 0.2A 0.3W 200MHZ C2012 21 NPN 高放30V 0.03A 200MHZ C2027 12 NPN 行管1500V 5A 50WD814 BCE NPN 低噪放大贴片150V 0.05A 150MHZ C5142 BCE NPN 彩行1500V 20A 200WD998 BCE NPN 音频功放开关120V 10A 80W <1/3US D2253 BCE NPN 彩显行管1700V 6A 50WD110 12 NPN 音频功放开关130V 10A 100W 1MHZC2335 28 NPN 视频功放500V 7A 40WC2373 28 NPN 功放200V 7.5A 40WC2383 21 NPN 视频开关160V 1A 0.9W A101 3C3300 30 NPN 音频功放开关100V 15A 100WC3310 28C NPN 电源开关500V 5A 40WC3320 28C NPN 电源开头500V 15A 80WC3355 21F NPN 高频放大20V 0.1A 6500MHZ C3358 40B NPN 高频放大20V 0.1A 7000MHZ C3457 BCE NPN 电源开关1100V 3A 50WC3460 BCE NPN 电源开关1100V 6A 100WC3466 BCE NPN 电源开关1200V 8A 120WC3505 28B NPN 电源开关900V 6A 80WC3527 BCE NPN 电源开关500V 15A 100WC3528 BCE NPN 电源开关500V 20A 150WC3866 BCE NPN 高压高速开关900V 3A 40WC2443 大铁NPN 功放开关600V 50A 400WC2481 29 NPN 音频功放开关150V 1.5A 20WC2482 21 NPN 视频放大300V 0.1A 0.9WC2500 21 NPN 通用30V 2A 0.9W 150MHZ C2594 29 NPN 音频功放开关40V 5A 10WC2611 29 NPN 视频放大300V 0.1A 1.25WC2625 30 NPN 音频功放开关450V 10A 80WC2682 29 NPN NF/Vid 180V 0.1A 8WC2688 29 NPN 视放管300V 0.2A 10W 80MHZC2690 29 NPN 音频功放开关120V 1.2A 20W 150MHZ A122 0PC2751 BCE NPN 电源开关500V 15A 120WC2837 30 NPN 音频功放开关150V 10A 100WC3873 BCE NPN 高压高速开关500V 12A 75W 30MHZ C3886 BCE NPN 开关行管1400V 8A 50W 8MHZ C3893 28B NPN 行管1400V 8A 50W 8MHZ C3907 28B NPN 功放开关180V 12A 130W 30MHZ C3595 29 NPN 射频30V 0.5A 1.2WC4059 BCE NPN 高速开关600V 15V 130W 0.5/2.2US C4106 BCE NPN 电源开关500V 7A 50W 20MHZ?C4111 BCE NPN 开关行管1500V 10A 150WC3679 BCE NPN 电源开关900V 5A 100W 6MHZC2898 28 NPN 音频功放开关500V 8A 50WC2922 43 NPN 音频功放开关180V 17A 200W 50MHZ A121 6C3026 12 NPN 开关管1700V 5A 50W D986 29 NPN 达林顿功放150-80V ±1.5A10W C3262 BCE NPN 功放800V 10A 100WC3264 BCE NPN ＰＡ功放开关230V 17A 200WB=170 A129 5C3280 30 NPN 音频功放开关160V 12A 120WB=100C3281 30 NPN 音频功放开关200V 15A 150W 30MHZC3680 BCE NPN 电源开关900V 7A 120W 6MHZC3688 BCE NPN 彩行1500V 10A 150WC3720 12 NPN 彩行1200V 10A 200WC3953 29 NPN 视放120V 0.2A 1.3W 400MHZC3987 28 NPN 达林顿50V 3A 20WC3995 BCE NPN 行管1500V 12A 180WD1025 28 NPN 达林顿功放200V 8A 50WC3997 BCE NPN 行管1500V 15A 250WC3998 BCE NPN 行管1500V 25A 250WC4024 BCE NPN 功放开关100V 10A 35W 24MHZC4038 BCE NPN 门电路50V 0.1A 0.3W 180MHZD1037 BCE NPN 音频功放开关150V 30A 180WD1047 30 NPN 音频功放开关160V 12A 100W B817 C4119 BCE NPN 微波炉开关1500V 15A 250WC4231 50C NPN 音频功放800V 2A 30WC4237 BCE NPN 高压高速开关1000V 8A 120W 30MHZC4242 BCE NPN 高压高速开关450V 7A 40WC4297 BCE NPN 电源开关500V 12A 75W 10MHZC4429 BCE NPN 电源开关1100V 8A 60WC4517 BCE NPN 音频功放550V 3A 30W 6MHZC4532 BCE NPN 大屏行管1700V 10A 200WC4582 BCE NPN 电源开关600V 15A 75W 20MHZON4673 BCE NPNON4873 BCE NPNC5244 BCE NPN 彩行1700V 15A 200WC5249 BCE NPN 功放开关600V 3A 35W 6MHZC5250 BCE NPN 开关1000V 7A 100WC5251 BCE NPN 彩行1500V 12A 50WD1071 28 NPN 达林顿功放300V 6A 40WC4706 BCE NPN 电源开关900V 14A 130W 6MHZC4382 BCE NPN 功放开关200V 2A 25W 20MHZ A166 8C4742 46 NPN 彩行1500V 6A 50WC4745 46 NPN 彩行1500V 6A 50WC4747 46 NPN 彩行1500V 10A 50WC4769 BCE NPN 微机行管1500V 7A 60WC4913 BCE NPN 大屏视放管2000V 0.02A 35WC4924 BCE NPN 音频功放800V 10A 70WC4927 BCE NPN 行管1500V 8A 50WC4927 BCE NPN SONY29行管1500V 8A 50WC4941 BCE NPN 行管1500V 6A 65W 500/380NS C4953 BCE NPN 功放开关500V 2A 25W t=300nSC5020 BCE NPN 彩行1000V 7A 100WC5068 BCE NPN 彩行1500V 10A 50WC5086 BCE NPN 彩行1500V 10A 50WC5088 BCE NPN 彩行1500V 10A 50WC5129 BCE NPN 彩显行管1500V 8A 50WD1163A 28 NPN 行偏转用350V 7A 40W 60MHZD1175 12 NPN 行偏转用1500V 5A 100WC5132 BCE NPN 彩行1500V 16A 50WC5144 BCE NPN 大屏彩行1700V 20A 200WC5148 BCE NPN 大屏彩行1500V 8A 50WC5149 BCE NPN 高速高频行管1500V 8A 50WC5198 BCE NPN 功放开关140V 10A 100WC5200 BCE NPN 功放开关230V 15A 150W A194 3D1273 28 NPN 音频功放80V 3A 40W 50MHZC5207 BCE NPN 彩行1500V 10A 50WC5243 BCE NPN 彩行1700V 15A 200WC5252 BCE NPN 彩行1500V 15A 100WC5294 BCE NPN 彩行1500V 20A ｔ＝200MS C5296 BCE NPN 开关管带阻1500V 8A 80WC5297 BCE NPN 开关管1500V 16A 60WC5331 BCE NPN 大屏彩显行管1500V 15A 180WD325 BCE NPN 功放开关50V 3A 25WD385 11 NPN 达林顿功放100V 7A 30WD400 21 NPN 通用25V 1A 0.75WD1302 21 NPN 音频25V 0.5A 0.5W 200MHZD1397 BCE NPN 开关1500V 3.5A 50W 3MHZD1398 BCE NPN 开关1500V 5A 50W 3MHZD1403 BCE NPN 彩行1500V 6A 120WD401 28 NPN 音频功放开关200V 2A 20WD415 29 NPN 音频功放开关120V 0.8A 5WD438 21 NPN 通用500V 1A 0.75W 100MHZD560 BCE NPN 达林顿功放150V 5A 30WD637 39E NPN 通用60V 0.1A 150MHZD667 21 NPN 视频放大120V 1A 0.9W 140MHZ B647 D1403 BCE NPN 彩行1500V 6A 120WD1415 BCE NPN 功放电源开关100V 7A 40W 达林顿D718 30 NPN 音频功放开关120V 8A 80W B668 D774 39B NPN 通用100V 1A 1W B734 D789 21 NPN 音频输出100V 1A 0.90D820 12 NPN 彩行1500V 5A 50WD870 12 NPN 彩行1500V 5A 50WD880 28 NPN 音频功放开关60V 3A 10WD882 29 NPN 音频功放开关40V 3A 30W B772 D884 28 NPN 音频功放开关330V 7A 40WD898 12 NPN 彩行1500V 3A 50WD951 12 NPN 彩行1500V 3A 65WD965 21 NPN 音频40V 5A 0.75WD966 21 NPN 音频40V 5A 1WD633拆28 NPN 音频功放开关100V 7A 40W达林顿D1431 28B NPN 彩行1500V 5A 80WD1433 28B NPN 彩行1500V 7A 80WD1980 61B NPN 达林顿100V 2A 10WD1981 EBC NPN 达林顿100V 2A 1WD1993 45B NPN 音频低噪55V 0.1A 0.4WD1416 BCE NPN 功放电源开关80V 7A 40W 达林顿D1427 BCE NPN 彩行1500V 5A 80W 带阻尼BU2525AF 30 NPN 开关功放1500V 12A 150W 350NSD1428 28B NPN 彩行1500V 6A 80W 带阻尼BU2525AX 30 NPN 开关功放1500V 12A 150W 350NSD1439 BCE NPN 彩行1500V 3A 80WD1541 28B NPN 彩行1500V 3A 80WD1545 28B NPN 彩行1500V 5A 50WD1547 BCE NPN 彩行1500V 7A 80WBU2527AF 30 NPN 开关功放1500V 15A 150WD1554 BCE NPN 彩行1500V 3.5A 80WD1555 BCE NPN 彩行1500V 5A 80WD1556 BCE NPN 彩行1500V 6A 80WD1559 BCE NPN 达林顿功放100V 20A 100W B107 9D1590 28 NPN 达林顿功放150V 8A 25WD1623 28B NPN 彩行1500V 4A 70WD1640 29 NPN 达林顿功放120V 2A 1.2WD1651 SP NPN 彩行1500V 5A 60W 3MHZ D1710 BCE NPN 彩行1500V 5A 50WD1718 28C NPN 音频功放180V 15A 150W 20MHZD1762 BCE NPN 音频功放开关60V 3A 25W 90MHZ B118 5D1843 BCE NPN 低噪放大50V 1A 1WD1849 50A NPN 彩行1500V 7A 120WD1850 50A NPN 彩行1500V 7A 120WD1859 50A NPN 音频80V 0.7A 1W 120MHZ D1863 50A NPN 音频120V 1A 1W 100MHZ D1724 29 NPN 开关120V 3A 180MHZ D1877 30 NPN 彩行1500V 4A 50W 带阻尼D1879 30 NPN 彩行1500V 6A 60W 带阻尼D1887 20 NPN 彩行1500V 10 70WD1930 21 NPN 达林顿100V 2A 1.2W 达林顿D1975 53A NPN 音频功放180V 15A 150W B131 7BU2532AW 30 NPN 开关功放1500V 15A 150W D1978 21 NPN 达林顿120V 1.5A 0.9W D1994A EBC NPN 音频驱动60V 1A 1WBD237 29 NPN 音频功放100V 2A 25W BD23 8BD238 29 PNP 音频功放100V 2A 25W BD23 7BU2520AF 30 NPN 开关功放1500V 10A 150W 1/500NS BU2520DF 30 NPN 开关功放1500V 10A 150W 1/500NS BU2520DX 30 NPN 开关功放1500V 10A 50W 600NS BUH515 BCE NPN 行管1500V 10A 80WBUH515D BCE NPN 行管1500V 10A 80WBUS13A 12 NPN 开关功放1000V 15A 175WD1997 45B NPN 激励管40V 3A 1.5W 100MHZ D2008 EBC NPN 音频功放80V 1A 1.2WD2012 BCE NPN 音频功放60V 3A 2W 3MHZD2136 EBC NPN 功放80V 1A 1.2WD2155 53A NPN 音频功放180V 15A 150WD2256 46 NPN 达林顿功放120V 25A 125W B149 4D2334 28B NPN 彩行1500V 5A 80WD2335 BCE NPN 彩行1500V 7A 100W 带阻尼D2349 BCE NPN 大屏彩显行管1500V ±10A50WD1959 BCE NPN 彩行1400V 10A 50WD2374 BCE NPN 功放开关60V 3A 25W 30MHZ D2375 BCE NPN 高放大倍数80V 3A 25W 50MHZ D2388 EBC NPN 达林顿90V 3A 1.2WD2445 BCE NPN 彩行1500V 12.5A 120WD2498 BCE NPN 彩行1500V 6A 50WD2588 BCE NPN 点火器用DK55 BCE NPN 开关400V 4A 60W BC307 21a PNP 通用50V 0.2A 0.3WBC327 CBE PNP 低噪音频50V 0.8A 0.625W BC33 7BC337 21a NPN 音频激励低噪50V 0.8A 0.625W BC32 7BC338 21a NPN 通用激励50V 0.8A 0.6WBC546 21a NPN 通用80V 0.2A 0.5WBC547 CBE NPN 通用50V 0.2A 0.5W 300MHZ BD135 29 NPN 音频功放45V 1.5A 12.5WBD136 29 PNP 音频功放45V 1.5A 12.5W BD13 7BD137 29 NPN 音频功放60V 1.5A 12.5W BD13 6BD138 29 PNP 音频功放60V 1.5A 12.5W BD13 9BD139 29 PNP 音频功放80V 1.5A 12.5W BD13 8BUS14A 12 NPN 开关功放1000V 30A 250W BUT11A 28 NPN 开关功放1000V 5A 100WBD243 28 NPN 音频功放45V 6A 65W BD24 4BD244 28 PNP 音频功放45V 6A 65W BD24 3BD681 29 NPN 达林顿功放100V 4A 40W BD68 2BD682 29 PNP 达林顿功放100V 4A 40W BD68 1BF458 29 NPN 视放250V 0.1A 10WBU208A 12 NPN 彩行1500V 5A 12.5WBU208D 12 NPN 彩行1500V 5A 12.5WBU323 28 NPN 达林顿功放450V 10A 125WBU406 28 NPN 行管400V 7A 60WBU508A 28 NPN 行管1500V 7.5A 75WBU508A 28 NPN 行管1500V 7.5A 75WBU508D 28 NPN 行管1500V 7.5A 75WBU806 28 NPN 功放400V 8A 60WBU932R 12 NPN 功放500V 15A 150WBUT12A 28 NPN 开关功放450V 10A 125WBU941 12 NPN 功放开关500V 15A 175W 达林顿BU1508DX 28 NPN 开关功放1500V 8A 35WBU2506DX 30 NPN 开关功放1500V 7A 50W 600NS BU2508AF 30 NPN 开关功放1500V 8A 125W 600NS BU2508AX 30 NPN 开关功放1500V 8A 125W 600NSBU2508DF 30 NPN 开关功放1500V 8A 125W 600NS BU2508DX 30 NPN 开关功放1500V 8A 50W 600NS BUV26 28 NPN 音频功放开关90V 14A 65W 250NS BU2522AF 30 NPN 开关功放1500V 11A 150W 350NSMJ15024 12 NPN 音频功放开关 400V 16A 250W 4MHZ MJ15 025MJ15025 12 PNP 音频功放开关400V 16A 250W 4MHZ MJ15 024MJE271 29 PNP 达林顿100V 2A 15W 6MHZ BUV28A 28 NPN 音频功放开关225V 10A 65W 250NS BUV48A 30 NPN 音频功放开关450V 15A 150WBUW13A 30 NPN 功放开关1000V 15A 150WBUX48 12 NPN 功放开关850V 15A 125WBUX84 30 NPN 功放开关800V 2A 40WBUX98A 12 NPN 功放开关400V 30A 210W 5MHZ DK55 28 NPN 功放开关400V 4A 65WDTA114 PNP 10K－10K 160V 0.6A 0.625WDTC143 NPN 录像机用 4.7kHPA100 BCE NPN 大屏彩显行管1500V 10A 150WHPA150 BCE NPN 大屏彩显行管1500V 15A 150WHSE830 BCE PNP 音频功放80V 115W 1MHZ HSE8 00HSE838 BCE NPN 音频功放80V 115W 1MHZ HSE8 30MN650 BCE NPN 行管1500V 6A 80WMJ802 12 NPN 音频功放开关90V 30A 200W MJ45 02MJ2955 12 PNP 音频功放开关60V 15A 115W MJ30 55MJ3055 12 NPN 音频功放开关60V 15A 115W MJ29 55MJ4502 12 PNP 音频功放开关90V 30A 200W MJ80 2MJ10012 12 NPN 达林顿400V 10A 175W MJ10015 12 NPN 电源开关400V 50A 200W MJ10016 12 NPN 电源开关500V 50A 200W MJ10025 12 电源开关850V 20A 250WMJ11032 12 NPN 电源开关120V 50A 300W MJ11 033MJ11033 12 PNP 电源开关120V 50A 300W MJ11 032MJ13333 12 NPN 电源开关400V 20A 175W MJ11015 12 PNP 铁达林顿500V 10AMJ14003 12 PNP 铁MJE340 29 NPN 视放300V 0.5A 20W MJE3 50MJE350 29 PNP 视放300V 0.5A 20W MJE3 40MJE2955T BCE PNP 音频功放开关60V 10A 75W 2MHZ MJE3 055TMJE3055T BCE NPN 音频功放开关70V 10A 75W 2MHZ MJE2 955TMJE5822 BCE PNP 音频功放开关500V 8A 80W MJE9730 BCE NPNMJE13003 29 NPN 功放开关400V 1.5A 14W MJE13005 28 NPN 功放开关400V 4A 60W MJE13007 28 NPN 功放开关1500V 2.5A 60W KSE800 28 NPN 达林顿140V 4A 20WTIP31C BCE NPN 功放开关100V 3A 40W 3MHZ TIP3 2TIP32C BCE PNP 功放开关100V 3A 40W 3MHZ TIP3 1TIP35C 30 NPN 音频功放开关100V 25A 125W 3MHZ TIP3 6TIP36C 30 PNP 音频功放开关100V 25A 125W 3MHZ TIP3 5TIP41C 30 NPN 音频功放开关100V 6A 65W 3MHZ TIP4 2TIP42C 30 PNP 音频功放开关100V 6A 65W 3MHZ TIP4 1TIP102 28 NPN 音频功放开关100V 8A 2WTIP105 28 PNP 音频功放开关60V 15A 80W 达林顿TIP122 28 NPN 音频功放开关100V 5A 65W TIP1 27TIP127 28 PNP 音频功放开关100V 5A 65W TIP1 22TIP137 28 PNP 音频功放开关100V 8A 70W TIP1 32TIP142 30 NPN 音频功放开关100V 10A 125W TIP1 47TIP142大30 NPN 音频功放开关100V 10A 125W TIP1 47TIP147 30 PNP 音频功放开关100V 10A 125W TIP1 42TIP147大30 PNP 音频功放开关100V 10A 125W TIP1 42TIP152 BCE 电梯用达林顿400V 3A 65W TL431 21 电压基准源BT33 电压结晶体管UGN3144 SGO 霍尔开关60MIAL1 电磁／微波炉1000V 60A 300WT30G40 BCE NPN 大功率开关管400V 30A 300W5609 21 NPN 音频低频放大50V 0.8A 0.625W 5610 5610 21 PNP 音频低频放大50V 0.8A 0.625W 5610 9626 21 NPN 通用。

1Features•Single-chip All-in-one Design, Only Requires External DAC–MIDI Control Processor, Serial and Parallel Interface –Synthesis, General MIDI Wavetable Implementation –Compatible Effects: Reverb + Chorus –Spatial Effect–4-band Stereo Equalizer•State-of-the-art Synthesis for Best Quality/Price Products –38-voice Polyphony + Effects–On-chip CleanWave ™ Wavetable Data, Firmware, RAM Delay Lines •Synthesizer Chipset: ATSAM2193/ATSAM2193-G + DAC •Hardware Programmable DAC Mode –I2S: 16 to 20 bits –Japanese: 16 bits •Typical Applications–Battery-operated Musical Keyboards –Portable Phones –Karaokes•TQFP44 (10 mm x 10 mm) Package for ATSAM2193TFBGA44 (7 mm x 7 mm) Package for ATSAM2193-G–Both Options Provide Small Footprint, Low Pin Count •Low-power–95 mW Typical Operating, <5 µA Power-down–2.5V and 3.3V Power Supply or Single 2.5V Supply –Built-in Power SwitchDescriptionThe A TSAM2193 provides a single-chip, low-cost MIDI sound system. Equipped with a serial and a parallel MIDI input, it provides state-of-the-art sound synthesis using a full GM sound set together with a range of compatible effects. Its low power consump-tion makes it ideal for all battery-powered applications such as portable Karaoke or any other device using MIDI synthesis.The A TSAM2193-G has the same functionality as the A TSAM2193 but is presented in a TFBGA44 package.Figure 1. Typical Hardware ConfigurationMIDI IN MPU-401(Parallel MIDI)ATSAM2193orATSAM2193-GStereo DACAudio OutSound Synthesis ATSAM2193 ATSAM2193-G Low-power Single-chip Synthesizer with EffectsRev. 2695A–DRMSD–06/032ATSAM2193/ATSAM2193-G2695A–DRMSD–06/03Pin Description44-lead TQFP PackageTable 1. Pin by Function - 44-lead TQFP PackagePin NamePin NumberTypeFunctionPower Supply Group GND 9, 11, 20, 22, 30, 34, 38, 42PWR Digital ground - all pins should be connected to a ground plane.VC310, 29PWR I/O power supply, 2.25V to 3.6V . All pins should be connected to a nominal 3.3V power. VC21, 12, 32, 41, 44PWRCore power supply, 2.25V to 2.75V . All pins should be connected to nominal 2.5V . If the built-in power switch is used for minimum power-down consumption, then all these pins should be connected to the output of the power switch PWROUT (pin 36).PWRIN 35PWRPower switch input, 2.25V to 2.95V . Even if the power switch feature is not used, this pin must be connected to nominal 2.5V .Serial MIDI, Parallel MIDI (MPU-401)MIDI IN17INSerial TTL MIDI IN. Connected to the built-in synthesizer at power-up or after MPU reset. Connected to the D0 - D7 bus (read mode) when MPU switched to UART mode. This pin should be tied HIGH if not used.D0 - D76, 8, 14, 16, 18, 21, 24, 26I/O 8-bit bi-directional bus, under control of CS, RD, WR. These pins should be left unconnected if not used.A02INThis pin has built-in pull-down. Should be left unconnected if not used. Select:0 = data registers (read/write)1 = status register (read), control register (write)CS 4IN Chip select, active low. This pin has a built-in pull-down. It should be left unconnected if not used.RD31INRead, active low. When CS and RD are low, data (A0 = 0) or status (A0 = 1) is read on D0-D7. Read data is acknowledged on the rising edge of RD. This pin has a built-in pull-down. It should be left unconnected if not used.WR 33INWrite, active low. When CS and WR are low, data (A0 = 0) or control (A0 = 1) is written from the D0 -D7 bus to the A TSAM2193 on the rising edge of WR. This pin has a built-in pull-up. It should be left unconnected if not used.IRQ 28OUTA rising edge indicates that a MIDI byte is available for read on D0 - D7. Acknowledged by reading the byte.Digital Audio Group CLBD 3OUT Digital audio bit clock. WSBD 23OUT Digital audio left/right select.DABD 27OUT Digital audio stereo output.DACSEL15INDAC type:0 = I2S 16 to 20 bits 1 = Japanese 16 bitsMiscellaneous Group X1, X239, 40-9.6 MHz crystal connection. An external 9.6 MHz clock can also be used on X1 (2.5V PP max through 47 pF capacitor). X2 cannot be used to drive external circuits, use CKOUT instead.3ATSAM2193/ATSAM2193-G2695A–DRMSD–06/03CKOUT 7OUT Buffered X2 output, can be used to drive external DAC master clock (256 * Fs)LFT 43-PLL external RC network.RESET 5IN Reset input, active low. This is a Schmitt trigger input, allowing direct connection to an RC network.PWROUT 36PWR Power switch output. Use this pin to supply 2.5V nominal core voltage by connecting it to all V C2 pins.PDWN37INPower down, active low. When power down is active, all outputs are set to logic level 0. The PLL and crystal oscillator are stopped. If the power switch feature is used, then 2.5V supply is removed from the core. T o exit from power down, PDWN must be set to V C2, then RESET applied. When unused this pin must be connected to V C2.TEST0 - TEST113, 25IN Test pins, should be grounded.RUN19OUTWhen high, indicates synthesizer is up and running.Table 1. Pin by Function - 44-lead TQFP Package (Continued)Pin Name Pin Number Type FunctionTable 2. Pinout by Pin Number - 44-lead TQFP PackagePin Number Signal Name Pin Number Signal Name Pin Number Signal Name Pin Number Signal Name 1VC212VC223WSBD 34GND 2A013TEST024D635PWRIN 3CLBD 14D225TEST136PWROUT 4CS 15DACSEL 26D737PDWN 5RESET 16D327DABD 38GND 6D017MIDI IN.28IRQ 39X17CKOUT 18D429VC340X28D119RUN 30GND 41VC29GND 20GND 31RD 42GND 10VC321D532VC243LFT 11GND22GND33WR44VC24ATSAM2193/ATSAM2193-G2695A–DRMSD–06/0344-ball TFBGA PackageTable 3. Pin by Function - 44-ball TFBGA PackagePin NamePin NumberTypeFunctionPower Supply Group GNDA4, B4, C3, C5, E3, E5, G2, G6PWRDigital ground - all pins should be connected to a ground plane.VC3A7, D1PWR I/O power supply, 2.25V to 3.6V . All pins should be connected to a nominal 3.3V power. VC2D6, F2, F4, F7, G5PWRCore power supply, 2.25V to 2.75V . All pins should be connected to nominal 2.5V . If the built-in power switch is used for minimum power-down consumption, then all these pins should be connected to the output of the power switch PWROUT (pin 36).PWRIN F1PWRPower switch input, 2.25V to 2.95V . Even if the power switch feature is not used, this pin must be connected to nominal 2.5V .Serial MIDI, Parallel MIDI (MPU-401)MIDI INB5INSerial TTL MIDI IN. Connected to the built-in synthesizer at power-up or after MPU reset. Connected to the D0 - D7 bus (read mode) when MPU switched to UART mode. This pin should be tied HIGH if not used.D0 - D7D7, C7, B6, A5, B3, A2, B1, C1I/O8-bit bi-directional bus, under control of CS, RD, WR. These pins should be left unconnected if not used.A0F5INThis pin has built-in pull-down. Should be left unconnected if not used. Select:0 = data registers (read/write)1 = status register (read), control register (write)CS E6IN Chip select, active low. This pin has a built-in pull-down. It should be left unconnected if not used.RDE2INRead, active low. When CS and RD are low, data (A0 = 0) or status (A0 = 1) is read on D0-D7. Read data is acknowledged on the rising edge of RD. This pin has a built-in pull-down. It should be left unconnected if not used.WR G1INWrite, active low. When CS and WR are low, data (A0 = 0) or control (A0 = 1) is written from the D0 -D7 bus to the A TSAM2193 on the rising edge of WR. This pin has a built-in pull-up. It should be left unconnected if not used.IRQ D2OUTA rising edge indicates that a MIDI byte is available for read on D0 - D7. Acknowledged by reading the byte.Digital Audio Group CLBD F6OUT Digital audio bit clock. WSBD A1OUT Digital audio left/right select.DABD C2OUT Digital audio stereo output.DACSELA6INDAC type:0 = I2S 16 to 20 bits 1 = Japanese 16 bitsMiscellaneous Group X1, X2G3, G4-9.6 MHz crystal connection. An external 9.6 MHz clock can also be used on X1 (2.5V PP max through 47 pF capacitor). X2 cannot be used to drive external circuits, use CKOUT instead.5ATSAM2193/ATSAM2193-G2695A–DRMSD–06/03Figure 2. Pinout by Pin Coordinate - 44-ball TFBGA (Top View)CKOUT C6OUT Buffered X2 output, can be used to drive external DAC master clock (256 * Fs)LFT G7-PLL external RC network.RESET E7IN Reset input, active low. This is a Schmitt trigger input, allowing direct connection to an RC network.PWROUT E1PWR Power switch output. Use this pin to supply 2.5V nominal core voltage by connecting it to all V C2 pins.PDWNF3INPower down, active low. When power down is active, all outputs are set to logic level 0. The PLL and crystal oscillator are stopped. If the power switch feature is used, then 2.5V supply is removed from the core. T o exit from power down, PDWN must be set to V C2, then RESET applied. When unused this pin must be connected to V C2.TEST0 - TEST1B7, B2IN Test pins, should be grounded.RUNA3OUTWhen high, indicates synthesizer is up and running.Table 3. Pin by Function - 44-ball TFBGA Package (Continued)Pin Name Pin Number Type FunctionWSBD D5RUN GND D3DACSEL VC3D6TEST1D4GND MIDI IN D2TEST0D7DABD GND GND CKOUT D1VC3IRQ VC2D0PWROUT GND GND RESETPWRIN VC2VC2A0CLBD VC2WRGNDX1X2VC2GNDLFTRD CS PDWN6ATSAM2193/ATSAM2193-G2695A–DRMSD–06/03Absolute Maximum RatingsRecommended Operating ConditionsNote:1.When using 3.3V VCC supply in a 5V environment, care must be taken that pin voltage does not exceed VC3+0.3V . Pin X1is powered by VC2, therefore voltage on this pin should not exceed VC2+0.3V . VC3 should not be lower than VC2.DC CharacteristicsTable 4. Absolute Maximum RatingsAmbient Temperature (Power applied)........... -40°C to +85°C *NOTICE:Stresses beyond those listed under “Abso-lute Maximum Ratings” may cause perma-nent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating con-ditions for extended periods may affect device reliability.Storage Temperature.....................................-65°C to +150°C Voltage on Input Pins.................................-0.5V to V C3 + 0.3V (except X1 and PDWN)Voltage on X1 and PDWN Pins..................-0.5V to V C2 + 0.3V V C2 Supply Voltage (core).....................................-0.5V to +3V V C3 Supply Voltage (I/O)....................................-0.3V to +4.5V Maximum IOL per I/O pin.................................................4 mATable 5. Recommended Operating ConditionsSymbol Parameter Min Typ Max Unit V C2Supply voltage 2.25 2.5 2.75V V C3(1)Supply voltage2.53.33.6V t A Operating ambient temperature70°CTable 6. DC Characteristics (t A = 25°C, V C2 = 2.5V ± 10%, V C3 = 3.3V ± 10%)Symbol ParameterMin Typ Max Unit V IL Low-level input voltage (Except X1, PDWN)-0.3- 1.0V V IH High-level input voltage (Except X1, PDWN) 2.3-V C3+0.3V V IL Low-level input voltage for X1, PDWN -0.3-0.3V V IH High-level input voltage for X1, PDWN 2-V C2+0.3V V OL Low-level output voltage I OL = -2mA --0.4V V OHHigh-level output voltage I OH = 2mA2.9--V Power consumption (crystal frequency =9.6 MHz)-95mW Power down supply current (using power switch)15µA7ATSAM2193/ATSAM2193-G2695A–DRMSD–06/03Parallel MPU-401 Interface TimingsFigure 3. MPU Interface Read CycleFigure 4. MPU Interface Write CycleTable 7. MPU Interface Timing ParametersSymbol ParameterMin Typ Max Unit t AVCS Address valid to chip select low 0--ns t CSLRDL Chip select low to RD low 5--ns t RDHCSH RD high to CS high 5--ns t PRD RD pulse width 50--ns t RDLDV Data out valid from RD--20ns t DRH Data out hold from RD 5-10ns t CSLRWRL Chip select low to WR low 5--ns t WRHCSH WR high to CS high 5--ns t PWR WR pulse width 50--ns t DWS Write data setup time 10--ns t DWH Write data hold time 0--ns t WRCYCWrite cycle3--µsA0D0 - D7t AVCSt CSLRDLt PRD t RDHCSHt RDLDVt DRHCSRDIRQA0D0 - D7t AVCSt CSLWRLt PWR t WRHCSHt DWSt DWHCSWRt WRCYC8ATSAM2193/ATSAM2193-G2695A–DRMSD–06/03Digital Audio TimingsFigure 5. Digital AudioFigure 6. Digital Audio Frame FormatNotes: 1.Selection between I2S and Japanese format is via pin DACSEL.Table 8. Digital Audio Timing ParametersSymbol ParameterMin TypMaxUnit t CW CLBD rising to WSBD change 200ns t SOD DABD valid prior/after CLBD rising 200ns t CLBDCLBD cycle time416.67nst CWWSBDt CWt CLBDt SODt SODCLBDDABDWSBD (I2S)DABDWSBD (Japanese)CLBDMSBLSB 16 bits LSB 18 bits LSB 20 bitsMSB9ATSAM2193/ATSAM2193-G2695A–DRMSD–06/03Reset and Power-downDuring power-up, the RESET input should be held low until the crystal oscillator and PLL are stabilized. This takes about 20 ms. A typical RC/diode power-up network can be used.After RESET, the ATSAM2193 or ATSAM2193-G enters an initialization routine. It takes around 50 ms before a MIDI IN or MPU message can be processed.If PDWN is asserted low, then the crystal oscillator and PLL are stopped. The chip enters a deep power-down sleep mode. To exit power down, PDWN must be asserted high, then RESET applied.Power-down mode is managed by an internal power switch. The equivalent schematic and standard connection is shown in Figure 7.All the VC2 pins must be connected to PWROUT.Figure 7. SchematicNote:High level for PDWN is VC2 = 2.5V ±10%.Figure 8. PDWN Connection ExampleVC2 Source fromPower SupplyA TSAM2193A TSAM2193-GVC2VC2VC2VC2VC2VC2PDWN = L: Power-down Mode (Internal Power Switch Open)PDWN = H: Operating Mode (Internal Power Switch Closed)P W R O U TP W R I NP D W NATSAM2193ATSAM2193-GVC2HOSTPDWN Control(High level = 3.3V)VC33.3V10 kOhmPDWNVC33.3VPWRIN 2.5VPWROUT10ATSAM2193/ATSAM2193-G2695A–DRMSD–06/03Recommended Board LayoutLike all HCMOS high integration ICs, the following simple rules of board layout are man-datory for reliable operation: •GND, VC3, VC2 Distribution and DecouplingsAll GND, VC3, VC2 pins should be connected. A GND plane is strongly recommended below the ATSAM2193 and ATSAM2193-G. The board GND + VC2 distribution should be in grid form.Recommended VC2 decoupling is 0.1 µF at each corner of the IC with an additional 10µF between pins 42 and 44 for the ATSAM2193 and between pins G6 and F7 for the ATSAM2193-G. VC3 requires a single 0.1 uF decoupling.•Crystal, LFTThe paths between the crystal, the crystal compensation capacitors, the LFT filter R-C-R and the device should be short and shielded. The ground return from the compensa-tion capacitors and LFT filter should be the GND plane from the device.•Analog SectionA specific AGND ground plane should be provided, which is connected to the GND ground by a single trace. No digital signals should cross the AGND plane.Refer to the Codec vendor recommended layout for correct implementation of the ana-log section.11ATSAM2193/ATSAM2193-G2695A–DRMSD–06/03Recommended CrystalCompensation and LFT FilterFigure 9. ATSAM2193Figure 10. ATSAM2193-G394340X1X2LFTX1R1470 OhmC21 nFC310 nFGNDC422 pFC122 pFGNDGND 9.6 MHz A TSAM2193G3G7G4X1X2LFTX1R1470 OhmC21 nFC310 nFGNDC122 pFC422 pFGND GND 9.6 MHz ATSAM2193-G12ATSAM2193/ATSAM2193-G2695A–DRMSD–06/03Mechanical Dimensions44-lead TQFP PackageFigure 11.Thin Plastic 44-lead Quad Flat Pack (TQFP44)Table 9. 44-lead TQFP Package Dimensions (in mm)ParameterMinNomMax A 1.60A10.050.15A2 1.351.40 1.45D 12.00D110.00E 12.00E110.00L 0.450.600.75P 0.80B0.30.370.4513ATSAM2193/ATSAM2193-G2695A–DRMSD–06/0344-ball TFBGA PackageFigure 12. 44-ball TFBGA PackageFigure 13. Package MarkingNote:A1 Ball in lower left-hand corner.0.530.350.800.26F RANCESAM2193-G YYWW 57541A XXXXXXXXXPrinted on recycled paper.Disclaimer: Atmel Corporation makes no warranty for the use of its products, other than those expressly contained in the Company’s standard warranty which is detailed in Atmel’s Terms and Conditions located on the Company’s web site. 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Atmel’s products are not authorized for use as critical components in life support devices or systems.Atmel CorporationAtmel Operations2325 Orchard Parkway San Jose, CA 95131Tel: 1(408) 441-0311Fax: 1(408) 487-2600Regional HeadquartersEuropeAtmel SarlRoute des Arsenaux 41Case Postale 80CH-1705 Fribourg SwitzerlandTel: (41) 26-426-5555Fax: (41) 26-426-5500AsiaRoom 1219Chinachem Golden Plaza 77 Mody Road Tsimshatsui East Kowloon Hong KongTel: (852) 2721-9778Fax: (852) 2722-1369Japan9F, Tonetsu Shinkawa Bldg.1-24-8 ShinkawaChuo-ku, Tokyo 104-0033JapanTel: (81) 3-3523-3551Fax: (81) 3-3523-7581Memory2325 Orchard Parkway San Jose, CA 95131Tel: 1(408) 441-0311Fax: 1(408) 436-4314Microcontrollers2325 Orchard Parkway San Jose, CA 95131Tel: 1(408) 441-0311Fax: 1(408) 436-4314La Chantrerie BP 7060244306 Nantes Cedex 3, France Tel: (33) 2-40-18-18-18Fax: (33) 2-40-18-19-60ASIC/ASSP/Smart CardsZone Industrielle13106 Rousset Cedex, France Tel: (33) 4-42-53-60-00Fax: (33) 4-42-53-60-011150 East Cheyenne Mtn. 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产品特性•高性能、低功耗的 8位AVR®微处理器•高级RISC结构–120条指令 – 大多数指令执行时间为单个时钟周期–32 个8位通用工作寄存器–全静态工作–工作于20 MHz时性能高达20 MIPS•非易失性程序和数据存储器–1K字节的系统内可编程Flash擦写寿命: 10,000次–64字节的系统内可编程EEPROM擦写寿命: 100,000次–64字节的片内SRAM–可以对锁定位进行编程以及实现EEPROM数据的加密•外设特点–一个具有独立预分频器的8位定时器/计数器及两条PWM通道–含有片内参考电压的4路10位ADC控制器–具有独立片内振荡器的可编程看门狗定时器–片内模拟比较器•特殊的处理器特点–片内调试系统–通过SPI端口在系统内可编程–片内/片外中断源–低功耗空闲模式、噪声抑制模式、省电模式–增强型上电复位–可编程的掉电检测–片内标定振荡器•I/O和封装–8引脚PDIP/SOIC: 6可编程 I/O线•工作电压:–ATtiny13V：1.8 - 5.5V–ATtiny13：2.7 - 5.5V•速度等级–ATtiny13V: 0 - 4 MHz @ 1.8 - 5.5V, 0 - 10 MHz @ 2.7 - 5.5V–ATtiny13: 0 - 10 MHz @ 2.7 - 5.5V, 0 - 20 MHz @ 4.5 - 5.5V•工业级温度范围•低功耗–正常模式:1 MHz, 1.8V: 240µA–掉电模式:< 0.1µA at 1.8V引脚配置Figure 1. ATtiny13芯片引脚2ATtiny132535D–AVR–04/04综述ATtiny13是基于增强的AVR RISC 结构的低功耗8位CMOS 微控制器。

由于其先进的指令集以及单时钟周期指令执行时间，ATtiny13的数据吞吐率高达1MIPS /MHz ，从而可以缓减系统在功耗和处理速度之间的矛盾。

HSC277Silicon Epitaxial Planar Diode for UHF/VHF tuner Band SwitchADE-208-413 (Z)Rev. 0Dec. 1995 Features• Low forward resistance. (r f = 0.7max)• U l tra small F l at P a ckage (UFP) is suitable for surface mount design.Ordering InformationType No.Cathode Mark Package CodeHSC277Laser UFPOutlineAbsolute Maximum Ratings (Ta = 25°C)Item Symbol Value Unit35VReverse voltage VRJunction temperature Tj125°CPower dissipation Pd150mWOperation temperature Topr–20 to +60°CStorage temperature Tstg–45 to +125°CHSC2772Electrical Characteristics (Ta = 25°C)ItemSymbol Min Typ Max Unit Test Condition Reverse voltage V R 35——V I R = 10µA Reverse current I R ——50µA V R = 25V Forward voltage V F —— 1.0V I F = 10mA Capacitance C —— 1.2pF V R = 6V, f = 1MHz Forward resistancer f——0.7ΩI F = 2mA, f = 100MHzFig.1 Forward current Vs. Forward voltageHSC277Fig.2 Reverse current Vs. Reverse voltageFig.3 Capacitance Vs. Reverse voltage3HSC277Fig.4 Forward resistance Vs. Forward current 4HSC277 Package Dimensions5Cautions1.Hitachi neither warrants nor grants licenses of any rights of Hitachi’s or any third party’s patent,copyright, trademark, or other intellectual property rights for information contained in this document.Hitachi bears no responsibility for problems that may arise with third party’s rights, includingintellectual property rights, in connection with use of the information contained in this document.2.Products and product specifications may be subject to change without notice. Confirm that you have received the latest product standards or specifications before final design, purchase or use.3.Hitachi makes every attempt to ensure that its products are of high quality and reliability. However,contact Hitachi’s sales office before using the product in an application that demands especially high quality and reliability or where its failure or malfunction may directly threaten human life or cause risk of bodily injury, such as aerospace, aeronautics, nuclear power, combustion control, transportation,traffic, safety equipment or medical equipment for life support.4.Design your application so that the product is used within the ranges guaranteed by Hitachi particularly for maximum rating, operating supply voltage range, heat radiation characteristics, installationconditions and other characteristics. Hitachi bears no responsibility for failure or damage when used beyond the guaranteed ranges. Even within the guaranteed ranges, consider normally foreseeable failure rates or failure modes in semiconductor devices and employ systemic measures such as fail-safes, so that the equipment incorporating Hitachi product does not cause bodily injury, fire or other consequential damage due to operation of the Hitachi product.5.This product is not designed to be radiation resistant.6.No one is permitted to reproduce or duplicate, in any form, the whole or part of this document without written approval from Hitachi.7.Contact Hitachi’s sales office for any questions regarding this document or Hitachi semiconductor products.Hitachi, Ltd.Semiconductor & Integrated Circuits.Nippon Bldg., 2-6-2, Ohte-machi, Chiyoda-ku, Tokyo 100-0004, Japan Tel: Tokyo (03) 3270-2111 Fax: (03) 3270-5109Copyright ' Hitachi, Ltd., 1999. All rights reserved. Printed in Japan.Hitachi Asia Pte. Ltd.16 Collyer Quay #20-00Hitachi TowerSingapore 049318Tel: 535-2100Fax: 535-1533URLNorthAmerica : http:/Europe : /hel/ecg Asia (Singapore): .sg/grp3/sicd/index.htm Asia (Taiwan): /E/Product/SICD_Frame.htm Asia (HongKong): /eng/bo/grp3/index.htm Japan : http://www.hitachi.co.jp/Sicd/indx.htmHitachi Asia Ltd.Taipei Branch Office3F, Hung Kuo Building. No.167, Tun-Hwa North Road, Taipei (105)Tel: <886> (2) 2718-3666Fax: <886> (2) 2718-8180Hitachi Asia (Hong Kong) Ltd.Group III (Electronic Components)7/F., North Tower, World Finance Centre,Harbour City, Canton Road, Tsim Sha Tsui,Kowloon, Hong Kong Tel: <852> (2) 735 9218Fax: <852> (2) 730 0281 Telex: 40815 HITEC HXHitachi Europe Ltd.Electronic Components Group.Whitebrook ParkLower Cookham Road MaidenheadBerkshire SL6 8YA, United Kingdom Tel: <44> (1628) 585000Fax: <44> (1628) 778322Hitachi Europe GmbHElectronic components Group Dornacher Stra§e 3D-85622 Feldkirchen, Munich GermanyTel: <49> (89) 9 9180-0Fax: <49> (89) 9 29 30 00Hitachi Semiconductor (America) Inc.179 East Tasman Drive,San Jose,CA 95134 Tel: <1> (408) 433-1990Fax: <1>(408) 433-0223For further information write to:。

电路笔记CN-0359Circuits from the Lab® reference designs are engineered and tested for quick and easy system integration to help solve today’s analog, mixed-signal, and RF design challenges. For more information and/or support, visit /CN0359.连接/参考器件AD825310 MHz、20 V/μs、G = 1、10、100、1000、i CMOS可编程增益仪表放大器ADuCM360集成双通道Σ-Δ型ADC和ARM Cortex-M3的低功耗精密模拟微控制器ADA4627-1 30 V、高速、低噪声、低偏置电流JFET运算放大器AD8542CMOS轨到轨通用放大器ADA4000-1 低成本、精密JFET输入运算放大器ADP2300 1.2 A、20 V、700 kHz/1.4 MHz异步降压型稳压器ADA4638-1 30 V、零漂移、轨到轨输出精密放大器ADP1613 650 kHz/1.3 MHz升压PWM DC-DC开关转换器ADA4528-2 精密、超低噪声、RRIO、双通道、零漂移运算放大器ADG1211低电容、低电荷注入、±15 V/+12 V iCMOS四通道单刀单掷开关ADA4077-2 4 MHz、7 nV/√Hz、低失调和漂移、高精度放大器ADG1419 2.1 Ω导通电阻、±15 V/+12 V/±5 V、iCMOS单刀双掷开关AD8592 CMOS、单电源、轨到轨输入/输出运算放大器，具有关断功能ADM3483 3.3 V限摆率、半双工、RS-485/RS-422收发器全自动高性能电导率测量系统Rev. 0Circuits from the Lab® reference designs from Analog Devices have been designed and built by AnalogDevices engineers. Standard engineering practices have been employed in the design andconstruction of each circuit, and their function and performance have been tested and veri ed in a labenvironment at room temperature. However, you are solely responsible for testing the circuit and determining its suitability and applicability for your use and application. Accordingly, in no event shall Analog Devices be liable for direct, indirect, special, incidental, consequential or punitive damages due to any cause whatsoever connected to the use of any Circuits from the Lab circuits. (Continued on last page)One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A. Tel: 781.329.4700 Fax: 781.461.3113 ©2015 Analog Devices, Inc. All rights reserved.评估和设计支持电路评估板CN-0359电路评估板(EVAL-CN0359-EB1Z)设计和集成文件原理图、源代码、布局文件、物料清单电路功能与优势图1中的电路是一个完全独立自足、微处理器控制的高精度电导率测量系统，适用于测量液体的离子含量、水质分析、工业质量控制以及化学分析。

Thermopile with integrated signal processing circuitFEATURES· Smart thermopile sensor with integrated signal processing.· Can be adapted to your specific meas-urement task.· Integrated, calibrated ambient tempera-ture sensor.· Output signal ambient temperature com-pensated.· Fast reaction time.· Different optics and IR filters available. · Digital serial interface for calibration and adjustment purposes.· Analog frontend/backend, digital signal processing.· E2PROM for configuration and data stor-age.· Configurable comparator with high/low signal for remote temperature threshold control.· TO 39 6 pin housing. APPLICATIONS· Miniature remote non contact temperature measurement (pyrometer).· Temperature dependent switch for alarm or thermostatic applications· Residential, commercial, automotive, and in-dustrial climate control.· Household appliances featuring a remote tem-perature control like microwave oven, toaster, hair dryer.· Temperature control in laser printers and copi-ers.· Automotive climate control.FUNCTIONAL DIAGRAMDESCRIPTIONThe PerkinElmer A2TPMI is a versatile infrared thermopile sensor with an integrated configurable ASIC for signal processing and ambient temperature compensation. This integrated infrared module senses the thermal radiation emitted by objects and converts this to a analog voltage.The A2TPMI can be delivered fully factory calibrated and adapted to the customer specification, as well as customer programmable via the serial interface. In the pre-calibrated version, only three pins are necessary for operation: object output voltage, 5V supply voltage, and ground.As described in this specification, the temperature accuracy of the fully adjustable integrated circuit out-performs that of the previous PerkinElmer thermopile modules with discrete components on pcb, be-cause the A2TPMI features an offset correction of the amplifier and a factory calibrated ambient tem-perature sensor. This makes the A2TPMI a versatile, compact and high precision device.Due to the internal digital signal processing and 8 bit resolution of the internal control registers the A2TPMI has improved accuracy for adjustment and improved performance. E2PROM technology allows unlimited changing of the configuration.For amplification of the highly sensitive thermopile signal in the micro- to millivolt range, a high resolu-tion programmable low noise chopper amplifier is provided. An adjustable high precision ambient tem-perature sensor followed by a signal processor, offers an accurate compensation signal with polynomial characteristics that perfectly matches to that of the thermopiles output. Adding of these signals results in an ambient independent object temperature signal over a large temperature range, which still can be adapted / scaled to customer needs due to flexible offset and postgain adjustment facilities of the de-vice.The two configurable comparators of the A2TPMI, that can alternatively be used, enhance the function-ality. This allows to employ the A2TPMI as an temperature dependent switch for alarm purposes. Threshold temperatures and the hysteresis is free programmable for both comparators.Due to integration of sensor and electronic in a compact TO 39 housing, the A2TPMI is robust and insensitive to environmental influences like pcb contamination (leakage currents), humidity and electro-magnetic interference.TPMI Ordering InformationPart code:sn TPMI n3c xxx Gxx Oxx nnn Pnx MxGxx xxxx Series (sn)A2analog ASIC - version 1TPMI- TO 39 housing- 5 isolated pins, 1 ground pin to housing- internal ASIC for signal conditioningSensor chip and cap (n3c)chip:n = 30.7 x 0.7 mm2 absorber (standard)digit "3":temperature reference included (standard for TPMI)cap:c = 4standard cap, window diameter 2.5 mm2, fov = 60°/ lens cap of various lengthsc = 6high cap, additional internal optics, e.g. internal reflector (IR)c = 7square hole 3.5 x 3.5 mm2, low cap, large fov = 100°Sensor optics (xxx)blank standard filter with 5.5 µm cut-on wavelengthL-x.y silicon lens with x.y mm focal lengthIRA internal reflector (mirror)A internal apertureInfrared filter on sensor (Gxx)blank standard filter with 5.5 µm cut-on wavelengthG9pyrometry filter, 8..14 µm bandpassGxx PerkinElmer specified broadband or (narrow) bandpass filterOutput configuration (Oxx)Pin V TobjA ambient temperature compensated output voltage representing object temperatureB not compensated output voltageC comparator 1 enabledPin V TambA output voltage representing ambient (sensor) temperatureV V ref = 1.225 VC comparator 2 enabledTemperature sensing range (n)nnn-20 ... nnn°C (remark: for object T range < 100°C the min. T-range may be >20°C)Option: Printed circuit board (pcb)P1standard pcb 17 x 33 mm2P3mini pcb 17 x 20 mm2L1 or L2electrical low pass filter on pcb (L1 = 1st order with RC; L2 = 2nd order with OpAmp)Option: External optics and filterML / MR / MF mirror left / right / front lookingG standard filter glued to mirrorG12G12 (uncoated silicon) filter glued to mirrorOption: Connectorblank noneWTB wire to boardI / JxT I = customer specific connector / J = standard JST connector, x = no of pins, top entryI / JxS I = customer specific connector / J = standard JST connector, x = no of pins, side entryI / JxxC with counterpartExamples:· A2TPMI 334-L5.5 OAA 100 and A2TPMI 334-L5.5 OAA 300are standard configurations of the PerkinElmer TPS 334 sensor with integrated A2TPMI ASIC and lens optics with 7° field of view adapted to an object temperature range –20…+100°C and -20…300°C, respectively.· A2TPMI 334 OAA 140 P1L1 MLG12 J4Tfeatures the PerkinElmer TPS 334 sensor with integrated A2TPMI ASIC on a standard pcb (P1). An RC circuit serves as a low pass filter to block the chopper frequency. The optics is the standard left looking mirror with attached protection filter. A 4 pin JST connector with top entry is used. The object temperature range is set to –20…100°C. Typical module for microwave oven application.)· A2TPMI 334 OAA 60features the PerkinElmer TPS 334 sensor with integrated A2TPMI ASIC. No additional optics – the sensor looks with full field of view into the surrounding. The temperature range is –10…60°C. (This is a typical module for air conditioner application.)· A2TPMI 334 L5.5 OAA 250 P3L2 J6Sfeatures the PerkinElmer TPS 334-L5.5 sensor with integrated A2TPMI ASIC and build-in 5.5 mmlens on a miniature pcb. It has an additional 2ndorder low pass filter with operation amplifier to block the chopper frequency. The connector is a 6 pin side entry connector and the temperature range is –20…250°C. This is a high performance module for industrial applications. The 6 pin con-nector gives access to the serial interface of the module.· For data visualization and for configuration changes a versatile application kit with PC software isavailable. Please ask for details.LabelingSensor:SSSS Last four digits of the device part numberXYY X = Last digit of the calendar year, YY = Week of the calendar year HHH Serial number of the production lot AA Calibration encodingExample:PCB Version:Sensors assembled on a PCB are labeled with a sticker having a letter and a serial number printed on. The letter describes the manufacturing site as follows: H Production parts made in Germany B Production parts made in Indonesia E Engineering samplesAbsolute Maximum ratingsParameter Min MAXSupply Voltage VDD -0.3 V +6.5 VStorage Temperature Range (Note 1) -40 °C 100°C Operating Temperature Range -25°C 100°CVoltage at all inputs and outputs (Note 1) -0.3 V VDD +0.3 V Current at input pins (Note 2) +/- 5mALead temperature (Soldering, 10sec) +300°CESD Tolerance (Note 3) 2.5 kVNote 1: Extension to 120°C for limited periods of several minutes possibleNote 2: Limiting input pin current is only necessary for input voltages that exceed absolute maximum input voltage ratingsNote 3: Human body model, 1.5k W in series with 100pF. All pins rated per method 3015.7 of MIL-STD-883.Static-sensitive device. Unused devices must be stored in conductive material. Protect devices from static discharge and static fields. Stresses above those listed under “Absolute maximum ratings” may cause permanent damage to the device. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.Precautions should be taken to avoid reverse polarity of power supply. Reversed polarity of power supply results in a destroyed unit.Do not expose the sensors to aggressive detergents such as freon, trichlorethylen, etc. Optical windows (e.g. filter, lens) may be cleaned with alcohol and cotton swab.Electrical CharacteristicsUnless otherwise indicated, all limits specified for T A = 25°C, V DD = +5 VSymbol Parameter Min Typ Max Unit ConditionsPower SupplyV DD Supply Voltage 4.5 5 5.5 VI DD Supply Current 1.5 2 mA R L > 1M WOutputs V Tobj / V TambESDV O Output Voltage Swing 0.25 V DD –0.25VV I out: -100m A … +100m AR O Output Resistance 100 WR L Resistive Output Load 50 k WC L Capacitive Output Load 100 500 pF6 mA SourcingI SC Output short circuit current13 mA Sinking Serial Interface SDAT, SCLKV iL Low level input voltage 0.3 V DD VV iH High level input voltage 0.7V DD VI iL Low level input current -600 -200 m AI iH High level input current 1 m AElectrical Characteristics (continued)Symbol Parameter Min Typ Max Unit Conditions V oL Low level output voltage 0.5 V Output current £ 2mAV oH High level output voltage V DD-0.6VV output current ³ -2mAReference VoltageV Ref Reference voltage 1.223 1.225 1.227 V R L > 1M W, T A = 25°CTC VRef Temperature coefficient of refer-ence voltage±30 ±100 ppm K-1AC CharacteristicsUnless otherwise indicated, all limits specified for T A = 25°C, V DD = +5VSymbol Parameter Min Typ Max Unit Conditions In N V1 Input referred voltage noise 120 nV/ÖHz rms valuet Strt Response Time after Power On 1 st lat Latency time for V Tobj75 mst resp Response Time 90 150 msThermopile CharacteristicsSymbol Parameter Min Typ Max Unit Conditions3-type chip (TPS 33x)S Sensitive (absorber) area 0.7x0.7 mm2N Noise voltage 38 nV/ÖHzt Time constant 25 msV Tobj / V Tamb CharacteristicsThe V Tobj and the V Tamb characteristics of thermopile sensors depends not only on object and ambient temperature but on several other factors like object size to spot size relation, ambient temperature com-pensation behaviour or optical filter characteristics. Therefore it is not possible to specify a general V Tobj and V Tamb characteristic. Those characteristics will be specified application specific in a separate cus-tomer specification.Optical CharacteristicsThe A2TPMI is available with different standard optical cap assemblies with and without an infrared lens or mirror.The optics defines the view angle or field of view (FOV) of the sensor.The FOV is defined as the incidence angle difference, where the sensor shows 50% relative output signal ac-cording to the setup shown.Figure 1: FOV definitionSymbol ParameterMinTypMaxUnit ConditionsStandard Cap Type (C4)FOV Field of view 60 70 ° 50% rel. output signal OAOptical axis 0 ± 10 °High cap type with internal reflector (C6 IRA)FOV Field of view 15 20 ° 50% rel. output signal OAOptical axis±2°Low cap type (C7)100 105 ° 50% rel. output signal FOV Field of view 125 135 ° 10% rel. output signal OAOptical axis±10°Mirror Module (ML / MR / MF)Field of view712°50% rel. output signalLens Cap Type (L5.5)FOV Field of view 7 12 ° 50% rel. output signal OA Optical axis0 ± 3.5 ° D:SDistance to spot size ratio8:1Optical Characteristics (continued)Symbol Parameter Min Typ Max Unit ConditionsLens Cap Type (L10.6)FOV Field of view 5 8 ° 50% rel. output signal OA Optical axis 0 ±2 °D:S Distance to spot size ratio 11:1Filter CharacteristicsParameter Min Typ Max Unit Conditions Standard FilterAverage Transmission 70 % Wavelength range from 7.5 µm to 13.5 µmAverage Transmission 0.5 % Wavelength range from visual to 5 µmCut On 5.2 5.5 5.8 µm At 25°C G9 FilterAverage Transmission 70 % Wavelength range from 9 µm to 13 µmAverage Transmission 1 % Wavelength range from visual to bandpassCut On 7.8 8 8.2 µm At 25°C Uncoated Silicon Lens (G12)Average Transmission 52 % Wavelength range from 5.5 µm to 13.5 µmPerkinElmer offers a wide range of Infrared Filters available in many different filter characteristics. Please contact PerkinElmer if you have special requirements or need further information.General DescriptionTHERMOPILE SENSORThe signal voltage, generated by the infrared radiation-sensitive thermopile sensor, is preamplified by a programmable choppered amplifier with 8 bit resolution.Due to the principle of thermopile temperature measurements, the thermopile voltage can be positive or negative depending if the object temperature is higher or lower than the ambient temperature of the A2TPMI. In order to allow signal processing of negative voltages with a single supply system, all internal signals are related to an internal voltage reference (Vref) of nominal 1.225 V, which serves as a virtual analog ground.For offset voltage trimming of the thermopile amplification path, the preamplifier is followed by a programmable trimming stage generating an offset voltage with a resolution of 8 bit.The thermopile voltage shows a non-linear output characteristic versus the object temperature. AMBIENT TEMPERATURE SENSORThe temperature of the A2TPMI, respectively the thermopile sensor, is detected by an integrated tem-perature sensor. This signal will be amplified and signal processed in order to match the reverse char-acteristics of the amplified thermopile curve, to realize an optimum of ambient temperature compensa-tion after adding the two signals. The characteristics of the temperature sensor signal is adjustable. This adjustment is part of the ASIC production process and will be provided by PerkinElmer. Thus the characteristics of the A2TPMI ambient temperature signal V Tamb is always provided fully calibrated. AMBIENT TEMPERATURE COMPENSATIONThe thermopile sensor converts the temperature radiation of an object surface to an electrical signal by means of thermocouples (Seebeck effect). The sensor output voltage is caused by the temperature difference between radiation heated (hot) junctions and cold junctions with a good thermal contact to the housing.In order to deliver an output signal which is only dependent on the object temperature, any change of housing (ambient) temperature has to lead to an appropriate output signal correction.For temperature compensation, the amplified thermopile- and temperature reference signals (V Tamb int) are added in an adding amplifier stage. The amplification is adjustable in a wide range according to application / customer requirements.The ambient temperature compensated and amplified signal is supplied to the output V Tobj. The tem-perature reference signal or alternatively the bandgap reference voltage is available on a second output pin V Tamb. Both outputs are short circuit stable .CONTROL UNIT / SERIAL INTERFACEThe operation characteristics of the A2TPMI have to be configured with a set of internal random access registers. All parameters / configurations are permanently stored in E2PROM in parallel, Configuration is usually done during factory calibration and does not need any user input.The control unit offers via serial interface access to all the registers, i.e. the internal parameters of the A2TPMI. The serial interface is a two wire bi-directional synchronous (SDAT, SCLK) type. A2TPMI sen-sors are in general factory calibrated and therefore there is no need to use the serial interface for stan-dard applications.The SDAT- / SCLK pins are internally pulled up to VDD and can be left unconnected. If the SDAT / SCLK pins will be connected in the application, ensure signal conformity to the serial interface specifica-tion. Subsequent undefined signals applied to these pins, may change the configuration and lead to malfunctioning of the sensor.For detailed information about the serial interface refer to application note: A2TPMI Serial Interface de-scription, or contact PerkinElmer application support.OUTPUT CONFIGURATIONThe A2TPMI offers various output configurations, which can be configured via the serial communication interface by means of integrated analog switches. For each output it can be individually selected whether the output operates in ‘Analog mode’ or in ‘Comparator mode’.In ‘Analog mode’ the output signal represents the measured IR radiation, respectively the temperature as an analog DC voltage.In ‘Comparator mode’ the measured IR radiation, respectively the temperature is compared to a pro-grammed threshold. For slowly changing signals an additional hysteresis can be configured. If the measured signal is above the threshold, +5VDC (logical high) is applied to the output. If the measured signal is below the threshold, 0VDC (logical low)is applied to the output.For detailed information about the output configuration refer to application note: A2TPMI Serial Interface description, or contact PerkinElmer application support.Application InformationAMBIENT TEMPERATURE COMPENSATIONBecause of many physical effects, that influence the non-contact temperature measurement based on infrared radiation, it is difficult to meet the best initial adjustment for a specific application. Therefore some deviations might be found at first measuring. For all applications the optimized solution can be prepared and fixed based on the measurement in the application environment. PerkinElmer is pleased in providing you assistance to find the conditions, which deliver the highest accuracy in your application.The temperature compensation is only working well within a certain ambient temperature range, limited by different device parameters of the thermopile sensor and the temperature reference sensor. The following diagram shows a typical characteristics and is only an example for better understanding of the principle compensation curve. The curve shows the deviation for a correct working of a compensated module.Temperature Deviation of VTobj vs. Ambient Temperature-0,50,511,522,53-2020406080100Ambient Temperature [°C]T y p i c a l T e m p e r a t u r e D e v i a t i o n [K ]The compensation of the module sample in the diagram is adjusted to the best fitting at 20°C to 80°C ambient temperature, but the curve can be shifted in the whole ambient temperature range through the change of A2TPMI parameters.MEASUREMENT TOLERANCEThe temperature error of the A2TPMI depends on several factors like the emissivity, object temperature, object size to spot size relation, temperature gradients over the sensor housing in the environment, device tolerances and the optimal adjustment of the ambient temperature compensation.The accuracy as specified under V Tamb and V Tobj characteristics is based on theoretical calculation as well as on statistical evaluation results. The PerkinElmer quality system ensures that all A2TPMIs are calibrated and tested under a certain test conditions in order to guarantee these specifications.However, due to the nature of infrared remote temperature measurements there might occur limits ex-ceeding or deviations in specific application environments. In this case please contact the PerkinElmer application support to help you solving the problem.OUTPUT SIGNALThe A2TPMI amplifiers are realized in chopper amplifier technology. Due to the nature of this technol-ogy the output signals V Tobj and V Tamb incorporate an AC signal of approximately 10 mV peak to peak in the range of 250 kHz. This AC voltage can be suppressed either by an electrical low pass filter or via an additional software filtering.In applications with low resistive load ( > 1Mohm) a simple RC low pass filter as follows can be used to smooth the signal:In applications with high resistive load (50kOhm … 1MOhm) filtering can be achieved with the following circuit. A rail to rail OPAmp like the LMV358 should be used so that the full sensing range will be avail-able on the output of the filter circuit.PRINTED CIRCUIT BOARD (PCB) VERSIONTwo different sizes of standard PCB versions are available. P1 version is a 17 x 34 mm 2PCB whichallows assembly of additional external mirror optics (M options). P3 version is 17 x 20 mm 2PCB suit-able for applications with restricted space. P3 version is not available with mirror (M option).Each PCB version is available either as plain version (sensor directly wired to connector), or with 1storder (RC-circuit, L1 option) or 2ndorder (active OpAmp circuit, L2 option) low pass filter, in order to provide attenuation of the AC portion on the output signal as described in chapter Output Signal.A2TPMIV Tobjor VTamb 500 Ohms A2TPMIV Tobj or V TambC V Tobj or V Tamb filteredThe PCB versions are available with following connector assemblies:Manufacturer: Model No. Connection typeHeader Connector4 pin top entry JST: B 4B-PH-K-S 4 pin side entry JST: S 4B-PH-K-SHousing: PHR 4 Contact:SPH-004T-P0.5S6 pin top entry JST: B 6B-PH-K-S 6 pin side entry JST: S 6B-PH-K-SHousing: PHR 6 Contact:SPH-004T-P0.5S Contact Material: Phosphor bronze ; tin-plated,Applicable wire: 0.032 to 0.08mm2Insulation O.D.: 0.5 to 0.9 mmNote: Engineering samples will be delivered only with a 6 pin header and counterpart connector with 350 mm cable.OUTPUT LOADCapacitive loads which are applied directly to the outputs reduce the loop stability margin. Values of 100 pF can be accommodated. Resistive load for the outputs should be held as small as possible (i.e. a large load resistance, R load > 50 k W has to be used) in order to avoid an impact on the temperature sig-nal due to self heating of the module.RESPONSE TIMEThe response time to an object temperature jump depends on the time constant t of the thermopile and the signal processing time of the A2TPMI. The processing of the thermopile signal has a latency time (t lat) of max. 75ms caused by the time required for AD-conversion, DA conversion and signal process-ing. The following diagram explains the connection of these eventsFigure 2:response time definitionThe A2TPMI has a sampling rate of 30 samples / second which results in a resolution of approx. 30ms for dynamic signals at V Tobj.T obj 2T obj 1V Tobj 1V Tobj 2LATCHUP AVOIDANCEJunction isolated CMOS circuits inherently include a parasitic 4 layer (PNPN) structure which has char-acteristics similar to a thyristor (SCR). Under certain circumstances this junction may be triggered into a low impedance state, resulting in excessive supply current, which can thermally destroy the circuit.To avoid this condition, no voltage greater than 0.3 V beyond the supply rails should be applied to any pin. In general the ATPMI supplies must be established either at the same time or before any signals are applied to the inputs. If this is not possible the drive circuits must limit the input current flow to maximum 5mA to avoid latchup. In general the device has to be operated with a 100 nF capacitor in parallel to the power supply.SOLDERINGThe TPMI is a lead-free component and fully complies with the ROHS regulations, especially with exist-ing roadmaps of lead-free soldering. The terminations of the TPMI sensor consist of nickel plated Kovar and gold finish. Hand soldering is recommended.Packaging InformationPackaging Information (continued)Connection Information元器件交易网Datasheet A2TPMI ÔLiability PolicyThe contents of this document are subject to change without notice. Customers are advised to consultwith PerkinElmer Optoelectronics sales representatives before ordering.Customers considering the use of PerkinElmer Optoelectronics thermopile devices in special applica-tions where failure or abnormal operation may directly affect human lives or cause physical injury orproperty damage, or where extremely high levels of reliability are demanded, are requested to consultwith PerkinElmer Optoelectronics sales representatives before such use. The company will not be re-sponsible for damage arising from such use without prior approval.As any semiconductor device, thermopile sensors or modules have inherently a certain rate of failure. Itis therefore necessary to protect against injury, damage or loss from such failures by incorporating safetydesign measures into the equipment.PerkinElmer Optoelectronics GmbH & Co. KGPO Box 300765020 Wiesbaden · GermanyTel.: +49 (0)611 492 430Fax: +49 (0)611 492 177A2TPMI Datasheet Rev4 Page 21 of 21 Rev. Oct 2003。

Features•AVR ® - High Performance and Low Power RISC Architecture •118 Powerful Instructions - Most Single Clock Cycle Execution •2K bytes of In-System Reprogrammable Flash –SPI Serial Interface for Program Downloading –Endurance: 1,000 Write/Erase Cycles •128 bytes EEPROM–Endurance: 100,000 Write/Erase Cycles •128 bytes Internal RAM•32 x 8 General Purpose Working Registers •15 Programmable I/O Lines •V CC : 2.7 - 6.0V•Fully Static Operation –0 - 10 MHz, 4.0 - 6.0V –0 - 4 MHz, 2.7 - 6.0V•Up to 10 MIPS Throughput at 10 MHz•One 8-Bit Timer/Counter with Separate Prescaler •One 16-Bit Timer/Counter with Separate Prescaler and Compare and Capture Modes •Full Duplex UART•Selectable 8, 9 or 10 bit PWM•External and Internal Interrupt Sources•Programmable Watchdog Timer with On-Chip Oscillator •On-Chip Analog Comparator•Low Power Idle and Power Down Modes •Programming Lock for Software Security •20-Pin DeviceDescriptionThe AT90S2313 is a low-power CMOS 8-bit microcontroller based on the AVR enhanced RISC architecture. By executing powerful instructions in a single clock cycle, the AT90S2313 achieves throughputs approaching 1 MIPS per MHz allowing the system designer to optimize power consumption versus processing speed.The AVR core combines a rich instruction set with 32 general purpose working regis-ters. All the 32 registers are directly connected to the Arithmetic Logic Unit (ALU),allowing two independent registers to be accessed in one single instruction executed in one clock cycle. The resulting architecture is more code efficient while achieving throughputs up to ten times faster than conventional CISC microcontrollers.(continued)Pin Configuration8-BitMicrocontroller with 2K bytesBlock DiagramFigure 1. The A T90S2313 Block DiagramThe AT90S2313 provides the following features: 2K bytes of In-System Programmable Flash, 128 bytes EEPROM, 128 bytes SRAM, 15 general purpose I/O lines, 32 general purpose working registers, flexible timer/counters with compare modes, internal and external interrupts, a pro-grammable serial UART, programmable Watchdog Timer with internal oscillator, an SPI serial port for Flash Memory downloading and two software selectable power saving modes. The Idle Mode stops the CPU while allowing the SRAM, timer/counters, SPI port and interrupt system to continue functioning. The power down mode saves the reg-ister contents but freezes the oscillator, disabling all other chip functions until the next interrupt or hardware reset. The device is manufactured using Atmel’s high density non-volatile memory technology. The on-chip In-System Programmable Flash allows the program memory to be reprogrammed in-system through an SPI serial interface or by a conventional nonvolatile memory programmer. By combining an enhanced RISC 8-bit CPU with In-System Programmable Flash on a monolithic chip, the Atmel AT90S2313 is a powerful microcontroller that provides a highly flexible and cost effective solution to many embed-ded control applications.The AT90S2313 AVR is supported with a full suite of pro-gram and system development tools including: C compil-ers, macro assemblers, program debugger/simulators, in-circuit emulators, and evaluation kits.AT90S2313Pin DescriptionsVCCSupply voltage pin.GNDGround pin.Port B (PB7..PB0)Port B is an 8-bit bi-directional I/O port. Port pins can pro-vide internal pull-up resistors (selected for each bit). PB0 and PB1 also serve as the positive input (AIN0) and the negative input (AIN1), respectively, of the on-chip analog comparator. The Port B output buffers can sink 20mA and can drive LED displays directly. When pins PB0 to PB7 are used as inputs and are externally pulled low, they will source current if the internal pull-up resistors are activated. Port B also serves the functions of various special features of the AT90S2313 as listed on page38.Port D (PD6..PD0)Port D has seven bi-directional I/O pins with internal pull-up resistors, PD6..PD0. The Port D output buffers can sink 20 mA. As inputs, Port D pins that are externally pulled low will source current if the pull-up resistors are activated.Port D also serves the functions of various special features of the AT90S2313 as listed on page43.Reset input. A low on this pin for two machine cycles while the oscillator is running resets the device.XTAL1Input to the inverting oscillator amplifier and input to the internal clock operating circuit.XTAL2Output from the inverting oscillator amplifierCrystal OscillatorXTAL1 and XTAL2 are input and output, respectively, of an inverting amplifier which can be configured for use as an on-chip oscillator, as shown in Figure 2. Either a quartz crystal or a ceramic resonator may be used. To drive the device from an external clock source, XTAL2 should be left unconnected while XTAL1 is driven as shown in Figure 3.Figure 2. Oscillator ConnectionsFigure 3.External Clock Drive Configuration元器件交易网AT90S2313 Architectural OverviewThe fast-access register file concept contains 32 x 8-bit general purpose working registers with a single clock cycle access time. This means that during one single clock cycle, one ALU (Arithmetic Logic Unit) operation is executed. Two operands are output from the register file, the operation is executed, and the result is stored back in the register file -in one clock cycle.Six of the 32 registers can be used as three 16-bits indirect address register pointers for Data Space addressing -enabling efficient address calculations. One of the three address pointers is also used as the address pointer for the constant table look up function. These added function reg-isters are the 16-bits X-register, Y-register and Z-register. The ALU supports arithmetic and logic functions between registers or between a constant and a register. Single reg-ister operations are also executed in the ALU. Figure 4 shows the AT90S2313 AVR Enhanced RISC microcontrol-ler architecture.In addition to the register operation, the conventional mem-ory addressing modes can be used on the register file as well. This is enabled by the fact that the register file is assigned the 32 lowermost Data Space addresses ($00 -$1F), allowing them to be accessed as though they were ordinary memory locations.The I/O memory space contains 64 addresses for CPU peripheral functions as Control Registers, Timer/Counters, A/D-converters, and other I/O functions. The I/O memory can be accessed directly, or as the Data Space locations following those of the register file, $20 - $5F.The AVR has Harvard architecture - with separate memo-ries and buses for program and data. The program memory is accessed with a two stage pipeline. While one instruction is being executed, the next instruction is pre-fetched from the program memory. This concept enables instructions to be executed in every clock cycle. The program memory is In-system Programmable Flash memory.With the relative jump and call instructions, the whole 1K address space is directly accessed. Most AVR instructions have a single 16-bit word format. Every program memory address contains a 16- or 32-bit instruction.During interrupts and subroutine calls, the return address program counter (PC) is stored on the stack. The stack is effectively allocated in the general data SRAM, and conse-quently the stack size is only limited by the total SRAM size and the usage of the SRAM. All user programs must initial-ize the SP in the reset routine (before subroutines or inter-rupts are executed). The 8-bit stack pointer SP is read/write accessible in the I/O space.The 128 bytes data SRAM + register file and I/O registers can be easily accessed through the five different address-ing modes supported in the AVR architecture.The memory spaces in the AVR architecture are all linear and regular memory maps.元器件交易网AT90S2313Figure 4. The AT90S2313 AVR Enhanced RISC ArchitectureFigure 5.Memory Maps元器件交易网元器件交易网Address Name Bit 7Bit 6Bit 5Bit 4Bit 3Bit 2Bit 1Bit 0Page$3F ($5F) SREG I T H S V N Z C17 $3E ($5E) Reserved$3D ($5D) SPL SP7SP6SP5SP4SP3SP2SP1SP018 $3C ($5C) Reserved$3B ($5B) GIMSK INT1INT0------23 $3A ($5A) GIFR INTF1INTF023 $39 ($59) TIMSK TOIE1OCIE1A--TICIE1-TOIE0-23 $38 ($58) TIFR TOV1OCF1A--ICF1-TOV0-24 $37 ($57) Reserved$36 ($56) Reserved$35 ($55) MCUCR--SE SM ISC11ISC10ISC01ISC0025 $34 ($54) Reserved$33 ($53) TCCR0-----CS02CS01CS0028 $32 ($52) TCNT0 Timer/Counter0 (8 Bit)29 $31 ($51) Reserved$30 ($50) Reserved$2F ($4F) TCCR1A COM1A1COM1A0----PWM11PWM1030 $2E ($4E) TCCR1B ICNC1ICES1.-CTC1CS12CS11CS1031 $2D ($4D) TCNT1H Timer/Counter1 - Counter Register High Byte32 $2C ($4C) TCNT1L Timer/Counter1 - Counter Register Low Byte32 $2B ($4B) OCR1AH Timer/Counter1 - Compare Register High Byte32 $2A ($4A) OCR1AL Timer/Counter1 - Compare Register Low Byte32 $29 ($49) Reserved$28 ($48) Reserved$27 ($47) Reserved$26 ($46) Reserved$25 ($45) ICR1H Timer/Counter1 - Input Capture Register High Byte33 $24 ($44) ICR1L Timer/Counter1 - Input Capture Register Low Byte33 $23 ($43) Reserved$22 ($42) Reserved$21 ($41) WDTCR---WDTOE WDE WDP2WDP1WDP035 $20 ($40) Reserved$1F ($3F) Reserved$1E ($3E) EEAR- EEPROM Address Register36 $1D ($3D) EEDR EEPROM Data register37 $1C ($3C) EECR-----EEMWE EEWE EERE37 $1B ($3B) Reserved$1A ($3A) Reserved$19 ($39) Reserved$18 ($38) PORTB PORTB7PORTB6PORTB5PORTB4PORTB3PORTB2PORTB1PORTB046 $17 ($37) DDRB DDB7DDB6DDB5DDB4DDB3DDB2DDB1DDB046 $16 ($36) PINB PINB7PINB6PINB5PINB4PINB3PINB2PINB1PINB046 $15 ($35) Reserved$14 ($34) Reserved$13 ($33) Reserved$12 ($32) PORTD-PORTD6PORTD5PORTD4PORTD3PORTD2PORTD1PORTD051 $11 ($31) DDRD-DDD6DDD5DDD4DDD3DDD2DDD1DDD051 $10 ($30) PIND-PIND6PIND5PIND4PIND3PIND2PIND1PIND051 $0F ($2F) Reserved$0E ($2E) Reserved$0D ($2D) Reserved$0C ($2C) UDR UART I/O Data Register40 $0B ($2B) USR RXC TXC UDRE FE OR---40 $0A ($2A) UCR RXCIE TXCIE UDRIE RXEN TXEN CHR9RXB8TXB841 $09 ($29) UBRR UART Baud Rate Register43 $08 ($28) ACSR ACD-ACO ACI ACIE ACIC ACIS1ACIS044…Reserved$00 ($20) Reserved元器件交易网AT90S2313 AT90S2313 Instruction Set SummaryMnemonics Operands Description Operation Flags#Clocks ARITHMETIC AND LOGIC INSTRUCTIONSADD Rd, Rr Add two Registers Rd ← Rd + Rr Z,C,N,V,H1 ADC Rd, Rr Add with Carry two Registers Rd ← Rd + Rr + C Z,C,N,V,H1 ADIW Rdl,K Add Immediate to Word Rdh:Rdl ← Rdh:Rdl + K Z,C,N,V,S2 SUB Rd, Rr Subtract two Registers Rd ← Rd − Rr Z,C,N,V,H1 SUBI Rd, K Subtract Constant from Register Rd ← Rd − K Z,C,N,V,H1 SBIW Rdl,K Subtract Immediate from Word Rdh:Rdl ← Rdh:Rdl − K Z,C,N,V,S2 SBC Rd, Rr Subtract with Carry two Registers Rd ← Rd − Rr − C Z,C,N,V,H1 SBCI Rd, K Subtract with Carry Constant from Reg.Rd ← Rd − K − C Z,C,N,V,H1 AND Rd, Rr Logical AND Registers Rd ← Rd • Rr Z,N,V1 ANDI Rd, K Logical AND Register and Constant Rd ← Rd • K Z,N,V1 OR Rd, Rr Logical OR Registers Rd ← Rd v Rr Z,N,V1 ORI Rd, K Logical OR Register and Constant Rd ← Rd v K Z,N,V1 EOR Rd, Rr Exclusive OR Registers Rd ← Rd ⊕ Rr Z,N,V1 COM Rd One’s Complement Rd ← $FF − Rd Z,C,N,V1 NEG Rd Two’s Complement Rd ← $00 − Rd Z,C,N,V,H1 SBR Rd,K Set Bit(s) in Register Rd ← Rd v K Z,N,V1 CBR Rd,K Clear Bit(s) in Register Rd ← Rd • ($FF − K)Z,N,V1 INC Rd Increment Rd ← Rd + 1Z,N,V1 DEC Rd Decrement Rd ← Rd − 1 Z,N,V1 TST Rd Test for Zero or Minus Rd ← Rd • Rd Z,N,V1 CLR Rd Clear Register Rd ← Rd ⊕ Rd Z,N,V1 SER Rd Set Register Rd ← $FF None1 BRANCH INSTRUCTIONSRJMP k Relative Jump PC ← PC + k + 1 None2 IJMP Indirect Jump to (Z)PC ← Z None2 RCALL k Relative Subroutine Call PC ← PC + k + 1None3 ICALL Indirect Call to (Z)PC ← Z None3 RET Subroutine Return PC ← STACK None4 RETI Interrupt Return PC ← STACK I4 CPSE Rd,Rr Compare, Skip if Equal if (Rd = Rr) PC ← PC + 2 or 3None 1 / 2 CP Rd,Rr Compare Rd − Rr Z, N,V,C,H1 CPC Rd,Rr Compare with Carry Rd − Rr − C Z, N,V,C,H1 CPI Rd,K Compare Register with Immediate Rd − K Z, N,V,C,H1 SBRC Rr, b Skip if Bit in Register Cleared if (Rr(b)=0) PC ← PC + 2 or 3 None 1 / 2 SBRS Rr, b Skip if Bit in Register is Set if (Rr(b)=1) PC ← PC + 2 or 3None 1 / 2 SBIC P, b Skip if Bit in I/O Register Cleared if (P(b)=0) PC ← PC + 2 or 3 None 1 / 2 SBIS P, b Skip if Bit in I/O Register is Set if (R(b)=1) PC ← PC + 2 or 3None 1 / 2 BRBS s, k Branch if Status Flag Set if (SREG(s) = 1) then PC←PC + k + 1None 1 / 2 BRBC s, k Branch if Status Flag Cleared if (SREG(s) = 0) then PC←PC + k + 1None 1 / 2 BREQ k Branch if Equal if (Z = 1) then PC ← PC + k + 1None 1 / 2 BRNE k Branch if Not Equal if (Z = 0) then PC ← PC + k + 1None 1 / 2 BRCS k Branch if Carry Set if (C = 1) then PC ← PC + k + 1None 1 / 2 BRCC k Branch if Carry Cleared if (C = 0) then PC ← PC + k + 1None 1 / 2 BRSH k Branch if Same or Higher if (C = 0) then PC ← PC + k + 1None 1 / 2 BRLO k Branch if Lower if (C = 1) then PC ← PC + k + 1None 1 / 2 BRMI k Branch if Minus if (N = 1) then PC ← PC + k + 1None 1 / 2 BRPL k Branch if Plus if (N = 0) then PC ← PC + k + 1None 1 / 2 BRGE k Branch if Greater or Equal, Signed if (N ⊕ V= 0) then PC ← PC + k + 1None 1 / 2 BRLT k Branch if Less Than Zero, Signed if (N ⊕ V= 1) then PC ← PC + k + 1None 1 / 2 BRHS k Branch if Half Carry Flag Set if (H = 1) then PC ← PC + k + 1None 1 / 2 BRHC k Branch if Half Carry Flag Cleared if (H = 0) then PC ← PC + k + 1None 1 / 2 BRTS k Branch if T Flag Set if (T = 1) then PC ← PC + k + 1None 1 / 2 BRTC k Branch if T Flag Cleared if (T = 0) then PC ← PC + k + 1None 1 / 2 BRVS k Branch if Overflow Flag is Set if (V = 1) then PC ← PC + k + 1None 1 / 2 BRVC k Branch if Overflow Flag is Cleared if (V = 0) then PC ← PC + k + 1None 1 / 2 BRIE k Branch if Interrupt Enabled if (I = 1) then PC ← PC + k + 1None 1 / 2 BRID k Branch if Interrupt Disabled if (I = 0) then PC ← PC + k + 1None 1 / 2元器件交易网Mnemonics Operands Description Operation Flags#Clocks DATA TRANSFER INSTRUCTIONSMOV Rd, Rr Move Between Registers Rd ← Rr None1 LDI Rd, K Load Immediate Rd ←K None1 LD Rd, X Load Indirect Rd ← (X)None2 LD Rd, X+Load Indirect and Post-Inc.Rd ← (X), X ← X + 1None2 LD Rd, - X Load Indirect and Pre-Dec.X ← X − 1, Rd ← (X)None2 LD Rd, Y Load Indirect Rd ← (Y)None2 LD Rd, Y+Load Indirect and Post-Inc.Rd ← (Y), Y ← Y + 1None2 LD Rd, - Y Load Indirect and Pre-Dec.Y ← Y − 1, Rd ← (Y)None2 LDD Rd,Y+q Load Indirect with Displacement Rd ← (Y + q)None2 LD Rd, Z Load Indirect Rd ← (Z)None2 LD Rd, Z+Load Indirect and Post-Inc.Rd ← (Z), Z ← Z+1None2 LD Rd, -Z Load Indirect and Pre-Dec.Z ← Z - 1, Rd ← (Z)None2 LDD Rd, Z+q Load Indirect with Displacement Rd ← (Z + q)None2 LDS Rd, k Load Direct from SRAM Rd ← (k)None2 ST X, Rr Store Indirect(X) ← Rr None2 ST X+, Rr Store Indirect and Post-Inc.(X) ← Rr, X ← X + 1None2 ST- X, Rr Store Indirect and Pre-Dec.X ← X - 1, (X) ← Rr None2 ST Y, Rr Store Indirect(Y) ← Rr None2 ST Y+, Rr Store Indirect and Post-Inc.(Y) ← Rr, Y ← Y + 1None2 ST- Y, Rr Store Indirect and Pre-Dec.Y ← Y - 1, (Y) ← Rr None2 STD Y+q,Rr Store Indirect with Displacement(Y + q) ← Rr None2 ST Z, Rr Store Indirect(Z) ← Rr None2 ST Z+, Rr Store Indirect and Post-Inc.(Z) ← Rr, Z ← Z + 1None2 ST-Z, Rr Store Indirect and Pre-Dec.Z ← Z - 1, (Z) ← Rr None2 STD Z+q,Rr Store Indirect with Displacement(Z + q) ← Rr None2 STS k, Rr Store Direct to SRAM(k) ← Rr None2 LPM Load Program Memory R0 ← (Z)None3 IN Rd, P In Port Rd ←P None1 OUT P, Rr Out Port P ← Rr None1 PUSH Rr Push Register on Stack STACK ← Rr None2 POP Rd Pop Register from Stack Rd ← STACK None2 BIT AND BIT-TEST INSTRUCTIONSSBI P,b Set Bit in I/O Register I/O(P,b) ←1None2 CBI P,b Clear Bit in I/O Register I/O(P,b) ←0None2 LSL Rd Logical Shift Left Rd(n+1) ← Rd(n), Rd(0) ← 0Z,C,N,V1 LSR Rd Logical Shift Right Rd(n) ← Rd(n+1), Rd(7) ← 0Z,C,N,V1 ROL Rd Rotate Left Through Carry Rd(0)←C,Rd(n+1)← Rd(n),C←Rd(7)Z,C,N,V1 ROR Rd Rotate Right Through Carry Rd(7)←C,Rd(n)← Rd(n+1),C←Rd(0)Z,C,N,V1 ASR Rd Arithmetic Shift Right Rd(n) ← Rd(n+1), n=0..6Z,C,N,V1 SWAP Rd Swap Nibbles Rd(3..0)←Rd(7..4),Rd(7..4)←Rd(3..0)None1 BSET s Flag Set SREG(s) ← 1SREG(s)1 BCLR s Flag Clear SREG(s) ← 0 SREG(s)1 BST Rr, b Bit Store from Register to T T ← Rr(b)T1 BLD Rd, b Bit load from T to Register Rd(b) ←T None1 SEC Set Carry C ←1C1 CLC Clear Carry C ← 0 C1 SEN Set Negative Flag N ←1N1 CLN Clear Negative Flag N ← 0 N1 SEZ Set Zero Flag Z ←1Z1 CLZ Clear Zero Flag Z ← 0 Z1 SEI Global Interrupt Enable I ←1I1 CLI Global Interrupt Disable I ← 0 I1 SES Set Signed Test Flag S ←1S1 CLS Clear Signed Test Flag S ← 0 S1 SEV Set Twos Complement Overflow V ←1V1 CLV Clear Twos Complement Overflow V ← 0 V1 SET Set T in SREG T ←1T1 CLT Clear T in SREG T ← 0 T1 SEH Set Half Carry Flag in SREG H ←1H1 CLH Clear Half Carry Flag in SREG H ← 0 H1 NOP No Operation None1 SLEEP Sleep(see specific descr. for Sleep function)None3 WDR Watchdog Reset(see specific descr. for WDR/timer)None1。

现货库存、技术资料、百科信息、热点资讯，精彩尽在鼎好!General DescriptionThe MAX3370/MAX3371 logic level translators are ideal for applications interfacing low-voltage devices to other logic levels. Externally applied voltages set the logic levels of the MAX3370/MAX3371. The devices accept V CC from +2.5V to +5.5V and V L from +1.6V to +5.5V,allowing data transfer between low-voltage ASICs and higher voltage devices. The MAX3371 features a shut-down mode that reduces supply current to <1µA and puts the I/O pins in a high-impedance state.The MAX3370/MAX3371 are bidirectional level shifters,allowing data transfer from the V CC side to the V L side and from the V L side to the V CC side. Both devices operate at speeds up to 2Mbps with an active driver and up to 500kbps with an open-drain driver.The MAX3370/MAX3371 are available in space-saving 5-pin and 6-pin SC70 packages, respectively.________________________ApplicationsCell Phone Cradles Cell Phone Hands-Free Kits Portable POS SystemsPortable Communication Devices Smart Card ReadersSPI™, MICROWIRE™, and I 2C™ Level Translation Low-Voltage ASIC Level Translation RS-232-Compatible TranslationFeatureso Allow Bidirectional Level Translationo Miniature SC70 Packages o Operational Down to 1.6V o Low Quiescent Current (<100µA)o Ultra-Low (<1µA) Shutdown Supply Current (MAX3371)o Three-State Outputs in Shutdown (MAX3371)o 2Mbps (10pF Load) Push-Pull Driving o 1Mbps (50pF Load) Push-Pull Driving o 500kbps (30pF Load) Open-Drain DrivingMAX3370/MAX3371†1µA, 2Mbps, Low-Voltage LevelTranslators in SC70________________________________________________________________Maxim Integrated Products 1Pin ConfigurationsTypical Operating Circuit19-1847; Rev 1; 2/01Ordering InformationI 2C is a trademark of Philips Corp.SPI is a trademark of Motorola, Inc.MICROWIRE is a trademark of National Semiconductor Corp.For price, delivery, and to place orders,please contact Maxim Distribution at 1-888-629-4642,or visit Maxim’s website at .†MAX3370/MAX3371 covered by U.S. Patent number 5,894,240.M A X 3370/M A X 33711µA, 2Mbps, Low-Voltage Level Translators in SC70ABSOLUTE MAXIMUM RATINGSELECTRICAL CHARACTERISTICS(V CC = +2.5V to +5.5V, V L = +1.6V to +5.5V (Note 1), GND = 0; I/O V , I/O V unconnected; T A = -40°C to +85°C, unless otherwise Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.V CC to GND..............................................................-0.3V to +7V SHDN to GND...............................................-0.3V to (V L + 0.3V)I/O V L to GND................................................-0.3V to (V L + 0.3V)V L , I/O V CC to GND...................................-0.3V to (V CC + 0.3V)Short-Circuit Duration: I/O V L , I/O V CC to GND..........ContinuousContinuous Power Dissipation (T A = +70°C)5/6-Pin SC70 (derate 3.1mW/°C above +70°C) ...........245mW Operating Temperature Range ...........................-40°C to +85°C Storage Temperature Range.............................-65°C to +150°C Lead Temperature (soldering, 10s).................................+300°CMAX3370/MAX33711µA, 2Mbps, Low-Voltage LevelTranslators in SC70_______________________________________________________________________________________3ELECTRICAL CHARACTERISTICS (continued)(V CC = +2.5V to +5.5V, V L = +1.6V to +5.5V (Note 1), GND = 0; I/O V L , I/O V CC unconnected; T A = -40°C to +85°C, unless otherwiseM A X 3370/M A X 33711µA, 2Mbps, Low-Voltage Level Translators in SC704_______________________________________________________________________________________Note 2:All units are 100% production tested at T A = +25°C. Limits over the operating temperature range are guaranteed by designand not production tested.Note 3:Tested only at worst case: V CC = +2.5V, V L = +1.6V.Note 4:10% to 90%.Note 5:Guaranteed by correlation to C LOAD = 50pF.ELECTRICAL CHARACTERISTICS (continued)(V CC = +2.5V to +5.5V, V L = +1.6V to +5.5V (Note 1), GND = 0; I/O V L , I/O V CC unconnected; T A = -40°C to +85°C, unless otherwise noted. Typical values are at T A = +25°C.) (Note 2)MAX3370/MAX33711µA, 2Mbps, Low-Voltage LevelTranslators in SC70_______________________________________________________________________________________5Figure 1a. Rail-to-Rail Driving I/O V L Figure 1b. Rail-to-Rail Driving I/O V CCFigure 1c. Open-Drain Driving I/O V L Figure 1d. Open-Drain Driving I/O V CCM A X 3370/M A X 33711µA, 2Mbps, Low-Voltage Level Translators in SC706_______________________________________________________________________________________Typical Operating Characteristics(Driving I/O V L rail-to-rail, R L = 1M Ω,T A = +25°C, unless otherwise noted.)I V L (µA )868890929496981001022.53.53.04.0 4.55.05.5V L SUPPLY CURRENT vs. POWER-SUPPLY VOLTAGEV CC (V)2001004003005006002.53.54.03.04.55.05.5V CC (V)I V C C (µA )V CC SUPPLY CURRENT vs. POWER-SUPPLY VOLTAGE8992919093949596979899-4010-15356085TEMPERATURE (°C)I V L (µA )V L SUPPLY CURRENT vs. TEMPERATURE100200150300250400350450-4010-15356085TEMPERATURE (°C)I V C C (µA )V CC SUPPLY CURRENT vs. TEMPERATURE80908510095110105115C LOAD (pF)I V L (µA )50100150200V L SUPPLY CURRENT vs. LOAD CAPACITANCE80280180480380680580780C LOAD (pF)I V C C (µA )50100150200V CC SUPPLY CURRENT vs. LOAD CAPACITANCEMAX3370/MAX33711µA, 2Mbps, Low-Voltage LevelTranslators in SC70_______________________________________________________________________________________701510520253035404550050100150200C LOAD (pF)P R O P A G A T I O N D E L A Y (n s )PROPAGATION DELAYvs. LOAD CAPACITANCE (DRIVING I/O V L )1052015302535050100150200C LOAD (pF)P R O P A G A T I O N D E L A Y (n s )PROPAGATION DELAYvs. LOAD CAPACITANCE (DRIVING I/O V CC)I/O V CC1V/div0I/O V L100ns/divRAIL-TO-RAIL DRIVING (RATE = 2Mbps, C LOAD = 10pF,V CC = 3.3V, V L = 1.8V)M A X 3370-09I/O V CC1V/div0I/O V L200ns/divRAIL-TO-RAIL DRIVING (RATE = 1Mbps, C LOAD = 50pF,V CC= 3.3V, V L = 1.8V)M A X 3370-10I/O V CC1V/div0I/O V L400ns/divOPEN-DRAIN DRIVING(RATE = 500kbps, C LOAD = 30pF,V CC = 3.3V, V L = 1.8V)MA X 3370-11I/O V CC2V/div0I/O V L400ns/divOPEN-DRAIN DRIVING(RATE = 500kbps, C LOAD = 30pF,V CC = 5V, V L = 2.5V)M A X 3370-122V/divI/O V CC100ns/divMAX3371EXITING SHUTDOWNM A X 3370-13I/O V LV SHDN0Typical Operating Characteristics (continued)(Driving I/O V L rail-to-rail, R L = 1M Ω, T A = +25°C, unless otherwise noted.)M A X 3370/M A X 33711µA, 2Mbps, Low-Voltage Level Translators in SC708_______________________________________________________________________________________Pin DescriptionDetailed DescriptionThe MAX3370/MAX3371 provide the necessary level translation to allow data transfer in a multivoltage sys-tem. These devices transmit data between an I/O pin referenced to V CC and an I/O pin referenced to V L . The V CC supply voltage range is from +2.5V to +5.5V, and the V L supply voltage range is between +1.6V and +5.5V. The MAX3371 features a shutdown mode in which I/O V CC and I/O V L are placed in a high-imped-ance state and supply current drops to 1µA.The MAX3370/MAX3371 are bidirectional level shifters allowing data transfer from the V CC side to the V L side,and from the V L side to the V CC side. Both devices operate at speeds up to 2Mbps with an active driver and up to 500kbps with an open-drain driver.Level TranslationThe MAX3370/MAX3371 provide bidirectional level translation between I/O pins referred to V CC and V L .I/O V CC and I/O V L are internally pulled up to their respective power-supply rails through 10k Ωresistors.V CC must be between +2.5V and +5.5V, and V L must be between +1.6V and +5.5V. For proper operation, V L can not exceed V CC .The MAX3370/MAX3371 can operate at data rates up to 2Mbps when driven by an active (push-pull) driver with a 10pF load, 1Mbps when driven by an active dri-ver with a 50pF load, or 500kbps when driven by an open-drain driver with a 30pF load. The internal pullups allow these devices to be driven by open-drain drivers.MAX3371 Shutdown ModeThe MAX3371 enters a low-power shutdown mode when SHDN is driven low. Connect SHDN to V L or drive high for normal operation. Activating shutdown mode disconnects the internal 10k Ωpullup resistors on I/OV CC and I/O V L . As a result, the supply current decreases to <1µA, and the I/O lines are high imped-ance. The high impedance I/O lines in shutdown allow use in a multidrop network. When in shutdown, I/O V L can be driven to V L and I/O V CC can be driven to V CC .Speed-UpThe speed-up circuit is a one-shot generator that helps the rise time of the output waveform in the low-to-high transition. When triggered, switches S 1and S 2turn on for 320ns to pull up I/O V L and I/O V CC . This greatly reduces the rise time and propagation delay for the low-to-high transition as well as improves the duty cycle (closer to 50% for an ideal square-wave input).See the scope plots in the Typical Operating Characteristics for the speed-up circuitry in operation.MAX3370/MAX33711µA, 2Mbps, Low-Voltage LevelTranslators in SC70_______________________________________________________________________________________9Applications InformationPower-Supply DecouplingTo reduce ripple and the chance of transmitting incor-rect data, decouple V CC and V L to ground with a 0.1µF capacitor as close to the device as possible.I 2C Level TranslationThe MAX3370/MAX3371 are ideal for level translation between a low-voltage ASIC and an I 2C device. The devices ’ bidirectional natures allow their use in the data line of I 2C communications. A typical application is interfacing a low-voltage microprocessor to a 3V or 5V D/A converter, such as the MAX517.The I/O lines on the MAX3370/MAX3371 are bidirec-tional, can be level-shifted up to +5.5V, and contain internal 10k Ωpullup resistors to allow open-drain dri-ving (see the Typical Operating Circuit ).Push-Pull vs. Open-Drain DrivingThe MAX3370/MAX3371 I/O pins can be driven by a push-pull or open-drain device. When using a push-pull driver, the MAX3370/MAX3371 operate up to 2Mbps with a 10pF load or 1Mbps with a 50pF load. The inter-nal pullup resistors on the I/O pins allow use with open-drain devices. The MAX3370/MAX3371 operate up to 500kbps with a 30pF load when driven by an open-drain device.Data rates higher than those listed in the Electrical Characteristics table can be achieved. The maximum data rate is limited to 3Mbps by the speed-up circuitry.Unidirectional vs. Bidirectional Level Translator The MAX3370/MAX3371 may also be used to translate unidirectional signals without signal inversion. The devices provide the smallest solution (SC70 package)for unidirectional level translation without inversion.Chip InformationTRANSISTOR COUNT: 75PROCESS: BiCMOSM A X 3370/M A X 33711µA, 2Mbps, Low-Voltage Level Translators in SC70Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.10____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600©2001 Maxim Integrated ProductsPrinted USAis a registered trademark of Maxim Integrated Products.Package InformationS C 70, 5L .E PS。

BC337A — NPN Medium Power TransistorSeptember 2007BC337ANPN Medium Power Transistor•This device is designed for general purpose amplifier application at collector currents to 800mA.•Sourced from process 38.Absolute Maximum Ratings T C =25°C unless otherwise noted* These ratings are limiting values above which the serviceability of any semiconductor device may be impaired.NOTES :1) These ratings are based on a maximum junction temperature of 150 degrees C.2) These are steady state limits. The factory should be consulted on applications involving pulsed or low duty cycle operations.Thermal Characteristics T a =25°C unless otherwise noted*Device mounted on FR-4 PCB 1.6” X 1.6” X 0.06”.Electrical Characteristics T C =25°C unless otherwise notedNotes:1.These ratings are limiting values above which the serviceability of any semiconductor device may be impaired.2.These are steady state limits. The factory should be consulted on applications involving pulsed or low duty cycle operations.3.These ratings are based on a maximum junction temperature of 150degrees C.SymbolParameter ValueUnitsV CEO Collector-Emitter Voltage 60V V CES Collector-Emitter Voltage 60V V EBO Emitter-Base Voltage 5V I C Collector Current (DC)800mA T J , T STGOperating and Storage Junction Temperature Range-55 ~ 150°CSymbolParameter Max.UnitsP D Total Device Dissipation Derate above 25°C6255.0mW mW/°C R θJC Thermal Resistance, Junction to Case 83.3°C/W R θJAThermal Resistance, Junction to Ambient200°C/WSymbolParameterTest ConditionMin.Typ.Max.UnitsBV CEO Collector-Emitter Breakdown Voltage I C = 10mA 60V BV CES Collector-Emitter Cutoff Voltage I C = 100μA 60V BV EBO Emitter-Base Breakdown Voltage I E = 100μA 5VI EBO Emitter Cut-off Current V EB = 5V10μA I CBO Collector Cut-off Current V CB = 20V, T = 25 °C T = 150 °C 0.15μAh FE DC Current GainV CE = 1V, I C = 100mA V CE = 1V, I C = 500mA 10040400V CE (sat)Collector-Emitter Saturation Voltage I C = 500 mA, I B = 50 mA 0.7V V BE (on)Base-Emitter On VoltageV CE = 5V, I C = 2mA1.2V1. Collector2. Base3. EmitterTO-921BC337A NPN Medium Power TransistorBC337ATRADEMARKSThe following are registered and unregistered trademarks and service marks Fairchild Semiconductor owns or is authorized to use andis not intended to be an exhaustive list of all such trademarks.DISCLAIMERFAIRCHILD SEMICONDUCTOR RESERVES THE RIGHT TO MAKE CHANGES WITHOUT FURTHER NOTICE TO ANY PRODUCTS HEREIN TO IMPROVE RELIABILITY, FUNCTION, OR DESIGN. FAIRCHILD DOES NOT ASSUME ANY LIABILITY ARISING OUT OF THE APPLICATION OR USE OF ANY PRODUCT OR CIRCUIT DESCRIBED HEREIN; NEITHER DOES IT CONVEY ANY LICENSE UNDER ITS PATENT RIGHTS, NOR THE RIGHTS OF OTHERS. THESE SPECIFICATIONS DO NOT EXPAND THE TERMS OF FAIRCHILD’S WORLDWIDE TERMS AND CONDITIONS, SPECIFICALLY THE WARRANTY THEREIN, WHICH COVERS THESE PRODUCTS.LIFE SUPPORT POLICYFAIRCHILD’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF FAIRCHILD SEMICONDUCTOR CORPORATION.As used herein:1. Life support devices or systems are devices or systemswhich, (a) are intended for surgical implant into the body, or (b) support or sustain life, and (c) whose failure to perform when properly used in accordance with instructions for use provided in the labeling, can be reasonably expected to result in significant injury to the user.2.A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system, or to affect its safety or effectiveness.PRODUCT STATUS DEFINITIONS Definition of Terms ACEx ®Build it Now™CorePLUS™CROSSVOLT ™CTL™Current Transfer Logic™EcoSPARK ®Fairchild ®Fairchild Semiconductor ®FACT Quiet Series™FACT ®FAST ®FastvCore™FPS™FRFET ®Global Power Resource SMGreen FPS™Green FPS™ e-Series™GTO™i-Lo ™IntelliMAX™ISOPLANAR™MegaBuck™MICROCOUPLER™MicroFET™MicroPak™Motion-SPM™OPTOLOGIC ®OPTOPLANAR ®®PDP-SPM™Power220®Power247®POWEREDGE ®Power-SPM™PowerTrench ®Programmable Active Droop™QFET ®QS™QT Optoelectronics™Quiet Series™RapidConfigure™SMART START™SPM ®STEALTH™SuperFET™SuperSOT™-3SuperSOT™-6SuperSOT™-8SyncFET™The Power Franchise ®TinyBoost™TinyBuck™TinyLogic ®TINYOPTO™TinyPower™TinyPWM™TinyWire™µSerDes™UHC ®UniFET™VCX™Datasheet Identification Product Status DefinitionAdvance InformationFormative or In DesignThis datasheet contains the design specifications for product development. Specifications may change in any manner without notice.Preliminary First ProductionThis datasheet contains preliminary data; supplementary data will be pub-lished at a later date. Fairchild Semiconductor reserves the right to make changes at any time without notice to improve design.No Identification Needed Full ProductionThis datasheet contains final specifications. Fairchild Semiconductor reserves the right to make changes at any time without notice to improve design. Obsolete Not In ProductionThis datasheet contains specifications on a product that has been discontin-ued by Fairchild semiconductor. The datasheet is printed for reference infor-mation only.Rev. I30。

A7302C<Preliminary> 315M/433MHz ASK/FSK Transmitter Document TitleA7302C Data Sheet, 315MHz / 433MHz ASK Transmitter with 1~10Kbps data rate 315MHz / 433MHz FSK Transmitter with 1~20Kbps data rateRevision HistoryRev. No.HistoryIssue DateRemark0.1Initial issueCompared to A7302A No CKO functionSeperated VDD_A and VDD_DASK data rate 1K ~ 10Kbps FSK data rate 1K ~ 20KbpsOct, 2009Important Notice:AMICCOM reserves the right to make changes to its products or to discontinue any integrated circuit product or service withoutnotice. AMICCOM integrated circuit products are not designed, intended, authorized, or warranted to be suitable for use in life-support applications, devices or systems or other critical applications. Use of AMICCOM products in such applications isunderstood to be fully at the risk of the customer.<Preliminary>315M/433MHz ASK/FSK TransmitterTable of Content1. General Description (3)2. Typical Applications (3)3. Features (3)4. Block Diagram (4)5. Absolute Maximum Ratings (4)6. Pin Configuration (5)7. Pin Description (5)8. Specification (6)9. Circuit Description (7)9.1 Functional Block (7)9.2 HW Control Mode (7)9.3 SPI Control Mode (9)9.3.1 SPI timing (9)9.3.2 Register 0 (Address: 00 ) (11)9.3.3 Register 1 (Address: 10) (12)9.4 Start-up Sequence (13)9.5 TX Data Shaping (16)9.6 TX Spurious Emission (17)10. Application Circuit (20)11. Abbreviations (21)12. Ordering Information (21)13. Package Information (22)14. Top Marking Information (23)15. Reflow Profile (24)16. Tape Reel Information (25)17 Product Status (27)<Preliminary>315M/433MHz ASK/FSK Transmitter 1. General DescriptionA7302C is a very easy-to-use CMOS RF transmitter for sub 1GHz license free ISM band (315/433MHz). It is a FSK/ASK single chip RF transmitter with 4-steps programmable power amplifier (max 10dBm @ 433MHz). This device integrates a fully VCO and PLL synthesizer. A7302C's carrier frequency F RF is determined by the frequency of the reference crystalF XTAL. The integer-N PLL synthesizer ensures that each RF value, ranging from 310 ~ 330 MHz and 425 ~ 445MHz withPLL steps of 847,5KHz ( RF step = 423,75KHz when Xtal = 13,56MHz. because F RF = F VCO/ 2 ), can be achieved. This is done by using a crystal as a reference frequency according to: F RF = F XTAL x N / 2R, where N is the PLL feedback divider ratio and R is crystal divider to support 13,56MHz crystal.A7302C supports FSK data rate from 1K to 20Kbps and ASK data rate from 1K to 10Kbps. In FSK modulation, this device’s Fdev (frequency deviation) is controlled by crystal detuning of series an external capacitor (typical 75pF for ±12,5KHz ). In ASK modulation, this capacitor is not necessary.For easy-to-use, A7302C has only two control registers, register 0 and 1. MCU can configure two registers via 3-wire SPI bus. In addition to SPI control mode, A7302C has a special mode called HW control mode. In HW control mode, user just needs to apply pin setting. Then, radio control is done (register 0 and register 1 are in default values). No matter HW or SPI control mode, A7302C is very easy to use by a low cost MCU or encoder. Those features are all integrated in a small DFN 10 pins package.For packet handling, there is no FIFO inside A7302C. Hence, MCU or Encoder just delivers the defined packet (preamble + sync word + payload) to TX_DATA pin for data transmitting.2. Typical Applicationsn Remote Control.■Wireless Toys.n Alarm and Security System.■RKE (Remote Keyless Entry).n Smart Energy Management■Garage Door Opener.n AMR (Auto Meter Reading)■Home Automation.3. Featuresn Operating range: VDD=2,2~3,6V. T=-40~+85℃.n Small DFN10 package.n Easy to usen HW or 3-wire SPI control mode selection.n HW control mode (no need MCU for radio control, default max TX power).n Auto calibration.n Auto start-up sequence, XtalàAuto CalibrationàPLLà TX.n TX current 14mA (FSK, 10dBm) / 8,8mA (ASK, 10dBm, 50% duty cycle).n Shut down mode current 0,1 uA.n Two stages class-C PA, 4-steps programmable TX Power : 0 / 2 / 7 / 10 dBm.n Fully integrated VCO, on chip loop filter and PLL synthesizer.n RF range from 310 ~ 330MHz and 425 ~ 445MHz with RF steps of 423,75 KHz by 13,56MHz Xtal.n Direct ASK modulation by switching PA.n Direct FSK modulation (frequency deviation) by crystal detuning via external capacitor.n Support low cost crystal (13,56MHz with ±50ppm tolerance).n Very few external components: No need external IF/SAW filters.<Preliminary>315M/433MHz ASK/FSK Transmitter 4. Block DiagramFig 4 A7302C Block Diagram5. Absolute Maximum RatingsCharacteristic With respect to Rating Unit Power supply voltage-0.3~5VInput pin voltage-0.3~5V Storage temperature range T stg-55~150°CHBM *± 2K VESD RatingMM *± 200V*Pin 6 (PA_OUT) is -2KV and -100V of HBM and MM respectively.*Stresses above those listed under “Absolute Maximum Rating” may cause permanent damage to the device. These are stress ratings only; functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.*Device is ESD sensitive. Use appropriate ESD precautions. Exceeding the absolute maximum rating may damage the device.HBM (Human Body Mode) is tested under MIL-STD-883G Method 3015.7. MM (Machine Mode) is tested under JEDEC EIA/JESD22-A115-A.*Device is Moisture Sensitivity Level III (MSL 3).<Preliminary>315M/433MHz ASK/FSK Transmitter6. Pin ConfigurationDFN 107. Pin DescriptionPin No.Pin Name DescriptionMODEHW control mode, mode selection.Connect to GND: 433MHz band, ASK mode.Connect 120K Ωto GND: 315MHz band, ASK mode.Connect 240K Ωto GND: 315MHz band, FSK mode.Connect to VDD: 433MHz band, FSK mode.1SPI_STB SPI control mode, SPI Strobe.TX_DATAHW control mode, input transmitted data only.2SPI_DATA SPI control mode, SPI data input and Transmitted data input.CE HW control mode, Chip Enable, active high3SPI_CLK SPI control mode, SPI clock input4VDD_D Digital power supply. (Need low pass RC filter on this pin .)5VDD_A Analog power supply. (Need low pass RC filter on this pin .)6PA_OUT Power Amplifier output.7GND Ground.8XICrystal oscillator port (Recommend Xtal Cload = 16pF)9FSK_SW FSK deviation setting. Capacitor value determines the Freq. deviation.10SPISControl Mode selection.Low à HW control mode (Use Pin 1 / 2 /3 to do radio control.)High à SPI control mode.<Preliminary>315M/433MHz ASK/FSK Transmitter 8. SpecificationGeneral Test Condition for A7302C: Ta = 25ºC, VDD=3.0V, Crystal=13.56MHz, with matching network, PN9 patternParameter Description Min.Typ.Max.Unit GeneralOperating temperature-4085°CASK 2.2 3.0 3.6V Supply voltageFSK 2.2 3.0 3.6VShut down mode (all circuit off)0.1uATX mode (FSK, 10dBm), TXP = 0014TX mode (ASK, 10dBm, 50 % duty cycle)8.8TX mode (FSK, 7dBm), TXP = 0111.5TX mode (FSK, 2dBm), TXP = 109Current consumptionTX mode (FSK, 0dBm), TXP = 118mA315MHz band, 423.75KHz RF step310 ~ 330MHz RF Frequency Range433MHz band, 423.75KHz RF step425 ~ 445MHz Xtal Frequency (F XTAL)Recommend Cload = 16pF.13.56MHz Xtal Series Resistance (ESR)Cload =16pF.60ohm Crystal Tolerance+/-50ppmwith Xtal compensated capacitor, Ccomp.5ms Crystal settling time(1)without Ccomp.1ms PLL settling time Xtal stable to TX ready1msASK110Kbps Data RateFSK120KbpsTX315MHz, VDD=3.0V10Max Output Power433MHz, VDD=3.0V10dBmTXP = 00 (max)10TXP = 017TXP = 102Output Power stepTXP = 110dBmASK Modulation Quality On-Off Ratio70dBOffset=100KHz-80Phase NoiseOffset=1MHz-100dBc/Hzf < 1GHz(RBW =100kHz)-36dBm47MHz< f <74MHz 87.5MHz< f <118MHz 174MHz< f <230MHz 470MHz< f <862MHz (RBW =100kHz)-54Spurious Emission(2)Above 1GHz (RBW = 1MHz)-30dBm(1) Refer to section 9.4 for details.(2) Pin 4 / 5 are critical paths of good spurious emission. Use suitable RC filters on those two pins for noiseless power supply is very important.Refer to section 9.5, 9.6 for details.<Preliminary>9.1 Functional BlockA7302C is an integer-N PLL synthesizer via feedback mechanism N-counter (Na + Nb). The VCO frequency is generated as a integer multiple of Phase Detect comparison frequency which is dividing by R-counter (16) from Xtal (13.56MHz).The phase detector tunes the VCO in the locked state at wanted frequency F VCO = F RF x 2.See figure 9.1 for details.Figure 9.1.1 VCO Topology in SPI control mode.9.2 HW Control Mode0 for HW control mode, MCU has no extra efforts to do radio control but just needs to control CE and TX_DATA pin. Table 9.2.1 and Table 9.2.2 show default setting and how to do pin settings respectively. If so, A7302C is set at max TX power. Hence, MCU just needs to deliver TX data to TX_DATA pin. For different wanted frequency allocations, refer to Table 9.2.3 for crystal selection.PA_OUT =433,92 MHzBuffer PAVCO output =867,84MHzComparison Freq 847,5KHzNa + Nb (div 1024)CP/Phase DetectLoop FilterPAVCOExample of 433,92 MHz433,92 MHz = 13,56MHz x 1024 / 2 / 16R-counter (div 16)847,5KHz<Preliminary>Figure 9.2.1 VCO in HW control mode.Pin 2 (Mode)Pin 3 (TX_DATA)Pin 4 (CE)433M ASK = 0315M ASK = 120 ohm Shut down = 0315M FSK = 240 ohm 433M FSK = VDDTransmitting dataActive = 1Table 9.2.2 Pin setting in HW control mode.310MHz ~ 330MHz425MHz ~ 445MHzSPIS F RF (MHz)Crystal (MHz)SPIS F RF 031013.45310031113.500311.06213.515600313.513.52870432.92031413.53280433.050314.513.54430433.420314.84613.54670433.496031513.558400315.152713.560PA_OUT =433,92 MHzBuffer PAVCO output =867,84MHz(div 128)PAVCO433,92 MHz = 867,84MHz / 26,78MHz<Preliminary>counter is separated into NA and NB to support wanted F RF in every 423KHz RF step with 13,56MHz Xtal. Refer to section , it is used to set TX output power, Modulation type (FSK or ASK) as well as Band Selection. Refer toPin 2 (SPI_STB)Pin 3 (SPI_DATA)Pin 4 (SPI_CLK)SPI Strobe SPI data inputSPI clockandTransmitting dataTable 9.3.1 Pin setting in SPI control mode.A7302C is very easy-to-use, only two steps to do radio control.Step 1: Set wanted RF frequency by Register 0.Step 2: Set features by Register 1.Step 3: If A7302C is set from shut down mode to active mode, please note to do step 1 and 2 again.Register 0 and 1 are both write-only. A7302C supports maximum 4Mbps SPI baud rate. To active SPI, SPI_STB pin must be set to high. To latch correct data, hold time and setup time between SPI_CLK and SPI_DATA must be satisfied. SPI_DATA is latched into the device at the rising edge of SPI_CLK. See below table for SPI timing characteristic.Fig 9.3.1.1 SPI timing chart<Preliminary>Figure 9.3.1.2 Timing chart of SPI_STB<Preliminary>315M/433MHz ASK/FSK Transmitter9.3.2 Register 0 (Address: 00 )Name Write-onlyD15D14D13D12D11D10D9D8D7D6D5D4D3D2D1D0Register 0R1R0NB7NB6NB5NB4NB3NB2NB1NB0NA3NA2NA1NA000Reset value111111← Write in direction (from D0 to D15, LSB first).D1 and D0: Address bit. Register 0 = [00], Other settings are forbidden.R[1:0]: Crystal reference frequency.R [1:0]Crystal (MHz)R counterNote00Reserved Reserved 011215PLL step = 800KHz, RF step = 400 KHz1013.5616PLL step = 847.5KHz, RF step = 423.75 KHz 111620PLL step = 800KHz, RF step = 400 KHzN= (16XNB) +NA. NB=46~144, NA=0~15NB, NA: Used to define wanted F RF of PLL (see below table).NA[3:0]: NA is 0 ~ 15.NB[7:0]: NB is 40~65.FormulaExampleNA = 0 = [0000]NB = 64 = [0100-0000]N = 16 x 64 + 0 = 1024R = 16 (F XTAL =13,56MHz)N = 16 x NB + NA F RF = F XTAL x N / 2 / RF RF = 13,56x 1024 / 2 / 16F RF = 433,92 MHz310MHz ~ 330MHz 425MHz ~ 445MHzNA NB Example NA NB Example 040060141161342362443463544564645665746784789489104910111112121313141415F RF= 13,56x(16x46+7) /2 /16 = 314,846 MHz 15F RF= 13,56x(16x64+0) /2/16 = 433,92 MHz<Preliminary>315M/433MHz ASK/FSK Transmitter 9.3.3 Register 1 (Address: 10)Name Write-onlyD15D14D13D12D11D10D9D8D7D6D5D4D3D2D1D0Register 1---- -- ------TXP1TXP0CKS ECK STBY BAND FSK_ASK CE10 Reset value0000000011010010← Write in direction (from D0 to D15, LSB first).D1 and D0: Address bit. Register 1 = [10], other settings are forbidden.TXP: TX output power control.[00]:max. [01]: high.[10]: mid.[11]: min.TXP [1:0]TX power level Band 315MHz Band 433MHz00Max.10 dBm10 dBm01High7 dBm7 dBm10Mid. 2 dBm 2 dBm11Min.0 dBm0 dBmCKS: Reserved.ECK: Reserved.STBY: Shall be set to [0].BAND: RF band selection.[0]:315 MHz band.[1]: 433 MHz band (default).FSK_ASK: FSK ASK Select.[0]:ASK (default).[1]: FSK.CE: Chip Enable[0]:Shut down mode (default).[1]:.Active mode.<Preliminary><1VCEVDDtimeVoltage90%> 1VFigure 9.4.1. An extra RC delay on CE pin for correct start up sequence.Hence, CE pin is recommended to be enabled by MCU. If so, RC delay on CE pin is not necessary, but, MCU shall let CE pin go HIGH after VDD is stable (> 90% max VDD) as shown below.CE> 1V,Xtal starts,calibration starts<Preliminary>time>100usFigure 9.4.2. CE pin is controlled by MCU for a correct start up sequence.When CE > 1V, crystal oscillator and calibration procedure are active. Figure 9.4.3 illustrates A7302C’s settling time when Ccomp is NC. If Ccomp is added, Xtal settling time becomes longer from typical 1ms to 5 ms. See Table 9.4.1 for details.OFFXtal settling (~1,0 ms)PLL settling (~1,0 ms)TX Shut down modeWithout CcompFig 9.4.3 Settling time from shut down mode to TX mode.A7302C’s crystal oscillator is Colpitts type with integrated feedback capacitors as shown in Figure 9.4.4. The input from XI pin is about 12 pF ~ 16 pF. Therefore, it is recommended to use a Xtal with 16 pF Cload because Xtal settling time is short (~1ms). If Xtal Cload is larger than 16 pF, an external Ccomp shall be added at XI pin. Then, Xtal settling time becomes longer. Another case to add Ccomp is to fine tune F RF for a proper frequency even though Xtal Cload =16 pF. Refer to Figure 9.4.5 and Table 9.4.1 for details.CE> 1V,Xtal starts,calibration starts<Preliminary>CextC XICcompFigure 9.4.4 Schematic of crystal oscillator.Settling Time (Typical)Without Ccomp 1 msXtal settlingWith Ccomp 5 msPLL settling time 1 msTable 9.4.1 Typical settling timeRecommend Quartz Crystal SpecificationCenter Frequency13,56MHzLoad Capacitance (Cload)16 pFEquivalent Series Resistance (ESR)=<60 ohmsShunt Capacitance (C0)=<5pFStability± 50 ppmTable 9.4.2 Recommend crystal specFrom Figure 9.4.4, A7302C’s frequency deviation in FSK is defined by applying external capacitors (C FSK) on FSK_SW pin. Fig. 9.4.5 is the equivalent circuit of detuning Xtal when TX_DATA=1 and TX_DATA = 0 respectively. Table 9.4.3 is a ± 12,5KHz frequency deviation which is suitable for FSK data rate from 1K to 20Kbps when<Preliminary>TX_DATA = 1TX_DATA = 0Figure 9.4.5 Equivalent circuit of crystal oscillator during FSK modulation.9.5 TX Data ShapingFor minimizing TX transient power as well as occupied bandwidth, A7302C has built-in TX data shaping circuit as illustrated in Figure 9.5.1. Therefore, user has no need to add external RC data shaping on TX_DATA pin. TX modulated spectrum in ASK and FSK are shown in Figure 9.5.2 respectively.<Preliminary>ASK FSKFigure 9.5.2 TX Spectrum (Spectrum Analyzer, RBW=VBW=100KHz, SPAN 10MHz)9.6 TX Spurious EmissionNoisy VDD is a critical issue to induce A7302C a bad TX spurious emission. Inside A7302C, analog circuitry is powered by VDD_A pin and digital circuitry is powered by VDD_D pin. Please note to add low pass RC filter in front of VDD_A and VDD_D. For PA power supply, connect to system voltage (2,2 ~ 3,6V) directly. RC filters in front of VDD_D and VDD_A are used to isolate power noise while PA is switching. Therefore, VDD RC filters lead good results of TX spurious emission as shown below. Figure 9.6.1 illustrates R and C values used in AMICCOM’s reference module. For different PCB design,R and C may be fine tuned to get optimized performance.28 pF57RVDD_DPA_OUTMatching networkANTLPFSystem voltage (ex., 3V)82 pF<Preliminary>315M/433MHz ASK/FSK TransmitterFigure 9.6.2 TX spectrum in ASK, Span 100MHz<Preliminary>315M/433MHz ASK/FSK TransmitterFigure 9.6.4 TX spectrum in FSK, Span 100MHz<Preliminary>315M/433MHz ASK/FSK Transmitter 10. Application CircuitFig 10.1 Typical Application Circuit of A7302C<Preliminary>315M/433MHz ASK/FSK Transmitter11. AbbreviationsAIF Auto IFAFC Auto Frequency CompensationAGC Automatic Gain ControlASK Amplitude Shift KeyingBER Bit Error RateBW BandwidthFdev Frequency DeviationFSK Frequency Shift KeyingIF Intermediate FrequencyISM Industrial, Scientific and MedicalLO Local OscillatorMCU Micro Controller UnitPLL Phase Lock LoopRX ReceiverRSSI Received Signal Strength IndicatorSPI Serial to Parallel InterfaceTX TransmitterVCO Voltage Controlled OscillatorXtal Crystal12. Ordering InformationPart No.Package Units Per Reel / Tube A73C02CDF/Q DFN10, Tape & Reel, Pb free3000pcsA73C02CDF DFN10, Tube, Pb free121pcsA73C02AH Die Form, Tray, Pb free250pcs<Preliminary>0.25CDD 2E 21ebC 0.10M A B LCA 3A0.10//CSeating Plane361058Dimensions in inches Dimensions in mm SymbolMin Nom Max Min Nom Max A 0.0280.0300.0320.700.750.80A 10.0000.0010.0020.000.020.05A 30.008 REF 0.203 REF b 0.0070.0100.0120.180.240.30D 0.1160.1180.120 2.95 3.00 3.05D 20.0890.0930.096 2.25 2.35 2.45<Preliminary>315M/433MHz ASK/FSK Transmitter 14. Top Marking InformationA73C02CDF¡ Part No. :A73C02CDF¡ Pin Count :10¡ Package Type :DFN¡ Dimension :3*3 mm¡ Mark Method :Laser Mark¡ Character Type :ArialA7302C <Preliminary> 315M/433MHz ASK/FSK Transmitter 15. Reflow Profile<Preliminary>315M/433MHz ASK/FSK Transmitter16. Tape Reel InformationCover / Carrier Tape Dimension11 EA IC60cm ±4cm TYPE P A0B0P0P1D0D1E F W 20 QFN 4*48 4.35 4.35 4.0 2.0 1.5 1.5 1.75 5.51224 QFN 4*48 4.4 4.4 4.0 2.0 1.5 1.5 1.75 5.51232 QFN 5*58 5.25 5.25 4.0 2.0 1.5 1.5 1.75 5.51248 QFN 7*7127.257.25 4.0 2.0 1.5 1.5 1.757.516DFN-104 3.2 3.2 4.0 2.0 1.5- 1.75 1.9820 SSOP 128.27.5 4.0 2.0 1.5 1.5 1.757.51624 SSOP 128.28.8 4.0 2.0 1.5 1.5 1.757.51628 SSOP (150mil)86104.0 2.0 1.5 1.5 1.757.516TYPE K0K1t COVER TAPE WIDTH20 QFN (4X4) 1.1-0.39.224 QFN (4X4) 1.4-0.39.232 QFN (5X5) 1.1-0.39.248 QFN (7X7) 1.1-0.313.3DFN-100.75-0.25820 SSOP 2.5-0.313.324 SSOP 2.1-0.313.328 SSOP (150mil) 2.5-0.312.5A 040mil.NO COMPONENT LEADER LENGTH500minPP 1P 0D 0FWD 1Unit : mm<Preliminary>315M/433MHz ASK/FSK TransmitterREEL DIMENSIONS UNIT IN mmTYPE GNTMDKLR20 QFN(4X4)24 QFN(4X4)32 QFN(5X5)DFN-1012.8+0.6/-0.4100 REF 18.2(MAX)1.75±0.2513.0+0.5/-0.2 2.0±0.5330＋0.00/-1.020.248 QFN(7X7)16.8+0.6/-0.4100 REF 22.2(MAX)1.75±0.2513.0+0.5/-0.2 2.0±0.5330＋0.00/-1.020.228 SSOP (150mil)20.4+0.6/-0.4100 REF 25(MAX) 1.75±0.2513.0+0.5/-0.2 2.0±0.5330＋0.00/-1.020.220 SSOP24 SSOP16.4+2.0/-0.0100 REF 22.4(MAX)1.75±0.2513.0+0.2/-0.21.9±0.4330＋0.00/-1.020.2NDT<Preliminary>315M/433MHz ASK/FSK TransmitterRF ICs AMICCOM17 Product StatusData Sheet Identification Product StatusDefinitionObjectivePlanned or Under DevelopmentThis data sheet contains the design specifications for product development. Specifications may change in any manner without notice.PreliminaryEngineering Samples and First ProductionThis data sheet contains preliminary data, and supplementary data will be published at a later date.AMICCOM reserves the right to make changes at any time without notice in order to improve design and supply the best possible product.No Identification Noted Full ProductionThis data sheet contains the final specifications.AMICCOM reserves the right to make changes at any time without notice in order to improve design and supply the best possible product.Obsolete Not In ProductionThis data sheet contains specifications on a product that has been discontinued by AMICCOM.The data sheet is printed for reference information only.Headquarter5F, No.2, Li-Hsin Rd. 6, Hsinchu Science Park ,Taiwan 30078Tel: 886-3-5785818Taipei Office。

AN5095K引脚主要功能AN5095K其引脚主要功能如下：1 R箝位滤波2 G箝位滤波3 B箝位滤波4 自动消隐色识别滤波5 消色识别输出，50/60Hz识别输出，SECAM检测输出6 色副载波恢复电路APC滤波7 4.43MHz晶振8 3.58MHz晶振9 黑电平检测10 字符消隐信号Ys输入11 字符R信号输入12 字符G信号输入13 字符B信号输入14 9V电源输入15 R信号输出16 G信号输出17 B信号输出18 行一致性检测输出19 地（RGB/DAC）20 自动对比度控制21 数据线（IIC总线）22 时钟线（IIC总线）23 5V电源输入（VIF/SIF）24 中频输入125 中频输入226 地（VIF/SIF）27 RF AGC输出28 音频输出输出29 去加重30 AFT输出31 外视频信号输入32 音频去耦33 伴音中频3输入/度控制34 伴音鉴频电路电源滤波35 伴音中频2输入36 伴音中频1输入37 中放AGC滤波38 内视频输入139 鉴频器APC滤波40 内视频输入241 视频检波输出42 PLL视频检测输出APC滤波43 同步检波19MHz振荡47 5V电源输入（VCJ）48 色度信号输入49 地（VCJ）50 行逆程脉冲输入51 行启动电源输入52 AFC2滤波53 AFC1滤波54 行振荡（32fH晶振）55 X射线保护56 行激励输出57 场箝位58 场频脉冲输出59 SECAM制接口60 -（B-Y）输出61 -（R-Y）输出62 沙堡脉冲输出63 -（B-Y）输入64 -（R-Y）输入。