MAX6664AEE中文资料

________________________________________________________________Maxim Integrated Products 1General DescriptionThe MAX202E–MAX213E, MAX232E/MAX241E line drivers/receivers are designed for RS-232 and V.28communications in harsh environments. Each transmitter output and receiver input is protected against ±15kV electrostatic discharge (ESD) shocks, without latchup.The various combinations of features are outlined in the Selector Guide.The drivers and receivers for all ten devices meet all EIA/TIA-232E and CCITT V.28specifications at data rates up to 120kbps, when loaded in accordance with the EIA/TIA-232E specification.The MAX211E/MAX213E/MAX241E are available in 28-pin SO packages, as well as a 28-pin SSOP that uses 60% less board space. The MAX202E/MAX232E come in 16-pin TSSOP, narrow SO, wide SO, and DIP packages. The MAX203E comes in a 20-pin DIP/SO package, and needs no external charge-pump capacitors. The MAX205E comes in a 24-pin wide DIP package, and also eliminates external charge-pump capacitors. The MAX206E/MAX207E/MAX208E come in 24-pin SO, SSOP, and narrow DIP packages. The MAX232E/MAX241E operate with four 1µF capacitors,while the MAX202E/MAX206E/MAX207E/MAX208E/MAX211E/MAX213E operate with four 0.1µF capacitors,further reducing cost and board space.________________________ApplicationsNotebook, Subnotebook, and Palmtop Computers Battery-Powered Equipment Hand-Held EquipmentNext-Generation Device Featureso For Low-Voltage ApplicationsMAX3222E/MAX3232E/MAX3237E/MAX3241E/MAX3246E: ±15kV ESD-Protected Down to10nA, +3.0V to +5.5V, Up to 1Mbps, True RS-232Transceivers (MAX3246E Available in a UCSP™Package)o For Low-Power ApplicationsMAX3221/MAX3223/MAX3243: 1µA SupplyCurrent, True +3V to +5.5V RS-232 Transceivers with Auto-Shutdown™o For Space-Constrained ApplicationsMAX3233E/MAX3235E: ±15kV ESD-Protected,1µA, 250kbps, +3.0V/+5.5V, Dual RS-232Transceivers with Internal Capacitorso For Low-Voltage or Data Cable ApplicationsMAX3380E/MAX3381E: +2.35V to +5.5V, 1µA,2Tx/2Rx RS-232 Transceivers with ±15kV ESD-Protected I/O and Logic PinsMAX202E–MAX213E, MAX232E/MAX241E±15kV ESD-Protected, +5V RS-232 TransceiversSelector Guide19-0175; Rev 6; 3/05Pin Configurations and Typical Operating Circuits appear at end of data sheet.YesPARTNO. OF RS-232DRIVERSNO. OF RS-232RECEIVERSRECEIVERS ACTIVE IN SHUTDOWNNO. OF EXTERNAL CAPACITORS(µF)LOW-POWER SHUTDOWNTTL TRI-STATE MAX202E 220 4 (0.1)No No MAX203E 220None No No MAX205E 550None Yes Yes MAX206E 430 4 (0.1)Yes Yes MAX207E 530 4 (0.1)No No MAX208E 440 4 (0.1)No No MAX211E 450 4 (0.1)Yes Yes MAX213E 452 4 (0.1)Yes Yes MAX232E 220 4 (1)No No MAX241E454 (1)YesFor pricing, delivery, and ordering information,please contact Maxim/Dallas Direct!at 1-888-629-4642, or visit Maxim’s website at .AutoShutdown and UCSP are trademarks of Maxim Integrated Products, Inc.Ordering InformationOrdering Information continued at end of data sheet.2_______________________________________________________________________________________M A X 202E –M A X 213E , M A X 232E /M A X 241EABSOLUTE MAXIMUM RATINGSV CC ..........................................................................-0.3V to +6V V+................................................................(V CC - 0.3V) to +14V V-............................................................................-14V to +0.3V Input VoltagesT_IN............................................................-0.3V to (V+ + 0.3V)R_IN...................................................................................±30V Output VoltagesT_OUT.................................................(V- - 0.3V) to (V+ + 0.3V)R_OUT......................................................-0.3V to (V CC + 0.3V)Short-Circuit Duration, T_OUT....................................Continuous Continuous Power Dissipation (T A = +70°C)16-Pin Plastic DIP (derate 10.53mW/°C above +70°C)....842mW 16-Pin Narrow SO (derate 8.70mW/°C above +70°C).....696mW 16-Pin Wide SO (derate 9.52mW/°C above +70°C)......762mW 16-Pin TSSOP (derate 9.4mW/°C above +70°C)...........755mW20-Pin Plastic DIP (derate 11.11mW/°C above +70°C)...889mW 20-Pin SO (derate 10.00mW/°C above +70°C).............800mW 24-Pin Narrow Plastic DIP(derate 13.33mW/°C above +70°C) ...............................1.07W 24-Pin Wide Plastic DIP(derate 14.29mW/°C above +70°C)................................1.14W 24-Pin SO (derate 11.76mW/°C above +70°C).............941mW 24-Pin SSOP (derate 8.00mW/°C above +70°C)..........640mW 28-Pin SO (derate 12.50mW/°C above +70°C)....................1W 28-Pin SSOP (derate 9.52mW/°C above +70°C)..........762mW Operating Temperature RangesMAX2_ _EC_ _.....................................................0°C to +70°C MAX2_ _EE_ _...................................................-40°C to +85°C Storage Temperature Range.............................-65°C to +165°C Lead Temperature (soldering, 10s).................................+300°CELECTRICAL CHARACTERISTICS(V CC = +5V ±10% for MAX202E/206E/208E/211E/213E/232E/241E; V CC = +5V ±5% for MAX203E/205E/207E; C1–C4 = 0.1µF for MAX202E/206E/207E/208E/211E/213E; C1–C4 = 1µF for MAX232E/241E; T A = T MIN to T MAX ; unless otherwise noted. Typical values are at T A = +25°C.)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.ELECTRICAL CHARACTERISTICS (continued)MAX202E–MAX213E, MAX232E/MAX241E (V CC= +5V ±10% for MAX202E/206E/208E/211E/213E/232E/241E; V CC= +5V ±5% for MAX203E/205E/207E; C1–C4 = 0.1µF forMAX202E/206E/207E/208E/211E/213E; C1–C4 = 1µF for MAX232E/241E; T A= T MIN to T MAX; unless otherwise noted. Typical valuesare at T A= +25°C.)Note 1:MAX211EE_ _ tested with V CC= +5V ±5%._______________________________________________________________________________________34______________________________________________________________________________________M A X 202E –M A X 213E , M A X 232E /M A X 241E__________________________________________Typical Operating Characteristics(Typical Operating Circuits, V CC = +5V, T A = +25°C, unless otherwise noted.)5.00MAX211E/MAX213ETRANSMITTER OUTPUT VOLTAGEvs. LOAD CAPACITANCELOAD CAPACITANCE (pF)V O H , -V O L (V )5.56.06.57.07.58.0100020003000400050000MAX211E/MAX213E/MAX241E TRANSMITTER SLEW RATE vs. LOAD CAPACITANCELOAD CAPACITANCE (pF)S L E W R A T E ( V /µs )5101520253010002000300040005000_______________________________________________________________________________________5MAX202E–MAX213E, MAX232E/MAX241E____________________________Typical Operating Characteristics (continued)(Typical Operating Circuits, V CC = +5V, T A = +25°C, unless otherwise noted.)2MAX202E/MAX203E/MAX232E TRANSMITTER SLEW RATE vs. LOAD CAPACITANCELOAD CAPACITANCE (pF)S L E W R A T E ( V /µs )468101214100020003000400050005.07.5-7.53000MAX205E–MAX208ETRANSMITTER OUTPUT VOLTAGEvs. LOAD CAPACITANCE-5.02.5LOAD CAPACITANCE (pF)O U T P U T V O L T A G E (V )10002000400050000-2.54550203000MAX205E–MAX208E SUPPLY CURRENT vs. LOAD CAPACITANCE2540LOAD CAPACITANCE (pF)S U P P L Y C U R R E N T (m A )100020004000500035302.55.0-10.0180MAX205E –MAX208EOUTPUT VOLTAGE vs. DATA RATE-7.50DATA RATE (kbps)O U T P U T V O L T A G E (V )601202401503090210-2.5-5.010.07.56_______________________________________________________________________________________M A X 202E –M A X 213E , M A X 232E /M A X 241EMAX203EMAX205E_____________________________________________________________Pin DescriptionsMAX202E/MAX232E_______________________________________________________________________________________7MAX202E–MAX213E, MAX232E/MAX241EMAX208E________________________________________________Pin Descriptions (continued)MAX206EMAX207E8_______________________________________________________________________________________M A X 202E –M A X 213E , M A X 232E /M A X 241EMAX211E/MAX213E/MAX241E)(MAX205E/MAX206E/MAX211E/MAX213E/MAX241E)________________________________________________Pin Descriptions (continued)MAX211E/MAX213E/MAX241EFigure 3. Transition Slew-Rate Circuit_______________Detailed Description The MAX202E–MAX213E, MAX232E/MAX241E consist of three sections: charge-pump voltage converters, drivers (transmitters), and receivers. These E versions provide extra protection against ESD. They survive ±15kV discharges to the RS-232 inputs and outputs, tested using the Human Body Model. When tested according to IEC1000-4-2, they survive ±8kV contact-discharges and ±15kV air-gap discharges. The rugged E versions are intended for use in harsh environments or applications where the RS-232 connection is frequently changed (such as notebook computers). The standard (non-“E”) MAX202, MAX203, MAX205–MAX208, MAX211, MAX213, MAX232, and MAX241 are recommended for applications where cost is critical.+5V to ±10V Dual Charge-PumpVoltage Converter The +5V to ±10V conversion is performed by dual charge-pump voltage converters (Figure 4). The first charge-pump converter uses capacitor C1 to double the +5V into +10V, storing the +10V on the output filter capacitor, C3. The second uses C2 to invert the +10V into -10V, storing the -10V on the V- output filter capacitor, C4.In shutdown mode, V+ is internally connected to V CC by a 1kΩpull-down resistor, and V- is internally connected to ground by a 1kΩpull up resistor.RS-232 Drivers With V CC= 5V, the typical driver output voltage swing is ±8V when loaded with a nominal 5kΩRS-232 receiver. The output swing is guaranteed to meet EIA/TIA-232E and V.28 specifications that call for ±5V minimum output levels under worst-case conditions. These include a 3kΩload, minimum V CC, and maximum operating temperature. The open-circuit output voltage swings from (V+ - 0.6V) to V-.Input thresholds are CMOS/TTL compatible. The unused drivers’ inputs on the MAX205E–MAX208E, MAX211E, MAX213E, and MAX241E can be left unconnected because 400kΩpull up resistors to V CC are included on-chip. Since all drivers invert, the pull up resistors force the unused drivers’ outputs low. The MAX202E, MAX203E, and MAX232E do not have pull up resistors on the transmitter inputs._______________________________________________________________________________________9MAX202E–MAX213E, MAX232E/MAX241E10______________________________________________________________________________________M A X 202E –M A X 213E , M A X 232E /M A X 241E±15kV ESD-Protected, +5V RS-232 Transceivers When in low-power shutdown mode, the MAX205E/MAX206E/MAX211E/MAX213E/MAX241E driver outputs are turned off and draw only leakage currents—even if they are back-driven with voltages between 0V and 12V. Below -0.5V in shutdown, the transmitter output is diode-clamped to ground with a 1k Ωseries impedance.RS-232 ReceiversThe receivers convert the RS-232 signals to CMOS-logic output levels. The guaranteed 0.8V and 2.4V receiver input thresholds are significantly tighter than the ±3V thresholds required by the EIA/TIA-232E specification.This allows the receiver inputs to respond to TTL/CMOS-logic levels, as well as RS-232 levels.The guaranteed 0.8V input low threshold ensures that receivers shorted to ground have a logic 1 output. The 5k Ωinput resistance to ground ensures that a receiver with its input left open will also have a logic 1 output. Receiver inputs have approximately 0.5V hysteresis.This provides clean output transitions, even with slow rise/fall-time signals with moderate amounts of noise and ringing.In shutdown, the MAX213E’s R4 and R5 receivers have no hysteresis.Shutdown and Enable Control (MAX205E/MAX206E/MAX211E/MAX213E/MAX241E)In shutdown mode, the charge pumps are turned off,V+ is pulled down to V CC , V- is pulled to ground, and the transmitter outputs are disabled. This reduces supply current typically to 1µA (15µA for the MAX213E).The time required to exit shutdown is under 1ms, as shown in Figure 5.ReceiversAll MAX213E receivers, except R4 and R5, are put into a high-impedance state in shutdown mode (see Tables 1a and 1b). The MAX213E’s R4 and R5 receivers still function in shutdown mode. These two awake-in-shutdown receivers can monitor external activity while maintaining minimal power consumption.The enable control is used to put the receiver outputs into a high-impedance state, to allow wire-OR connection of two EIA/TIA-232E ports (or ports of different types) at the UART. It has no effect on the RS-232 drivers or the charge pumps.N ote: The enabl e control pin is active l ow for the MAX211E/MAX241E (EN ), but is active high for the MAX213E (EN). The shutdown control pin is active high for the MAX205E/MAX206E/MAX211E/MAX241E (SHDN), but is active low for the MAX213E (SHDN ).Figure 4. Charge-Pump DiagramMAX202E–MAX213E, MAX232E/MAX241EV+V-200µs/div3V 0V 10V 5V 0V -5V -10VSHDNMAX211EFigure 5. MAX211E V+ and V- when Exiting Shutdown (0.1µF capacitors)X = Don't care.*Active = active with reduced performanceSHDN E N OPERATION STATUS Tx Rx 00Normal Operation All Active All Active 01Normal Operation All Active All High-Z 1XShutdownAll High-ZAll High-ZTable 1a. MAX205E/MAX206E/MAX211E/MAX241E Control Pin ConfigurationsTable 1b. MAX213E Control Pin ConfigurationsThe MAX213E’s receiver propagation delay is typically 0.5µs in normal operation. In shutdown mode,propagation delay increases to 4µs for both rising and falling transitions. The MAX213E’s receiver inputs have approximately 0.5V hysteresis, except in shutdown,when receivers R4 and R5 have no hysteresis.When entering shutdown with receivers active, R4 and R5 are not valid until 80µs after SHDN is driven low.When coming out of shutdown, all receiver outputs are invalid until the charge pumps reach nominal voltage levels (less than 2ms when using 0.1µF capacitors).±15kV ESD ProtectionAs with all Maxim devices, ESD-protection structures are incorporated on all pins to protect against electrostatic discharges encountered during handling and assembly. The driver outputs and receiver inputs have extra protection against static electricity. Maxim’s engineers developed state-of-the-art structures to protect these pins against ESD of ±15kV without damage. The ESD structures withstand high ESD in all states: normal operation, shutdown, and powered down. After an ESD event, Maxim’s E versions keep working without latchup, whereas competing RS-232products can latch and must be powered down to remove latchup.ESD protection can be tested in various ways; the transmitter outputs and receiver inputs of this product family are characterized for protection to the following limits:1)±15kV using the Human Body Model2)±8kV using the contact-discharge method specifiedin IEC1000-4-23)±15kV using IEC1000-4-2’s air-gap method.ESD Test ConditionsESD performance depends on a variety of conditions.Contact Maxim for a reliability report that documents test set-up, test methodology, and test results.Human Body ModelFigure 6a shows the Human Body Model, and Figure 6b shows the current waveform it generates when discharged into a low impedance. This model consists of a 100pF capacitor charged to the ESD voltage of interest, which is then discharged into the test device through a 1.5k Ωresistor.S H D N ENOPERATION STATUS Tx 1–400Shutdown All High-Z 01Shutdown All High-Z 10Normal Operation 11Normal OperationAll ActiveAll Active Active1–34, 5High-Z ActiveHigh-Z High-Z High-Z Active*High-Z RxM A X 202E –M A X 213E , M A X 232E /M A X 241EIEC1000-4-2The IEC1000-4-2 standard covers ESD testing and performance of finished equipment; it does not specifically refer to integrated circuits. The MAX202E/MAX203E–MAX213E, MAX232E/MAX241E help you design equipment that meets level 4 (the highest level) of IEC1000-4-2, without the need for additional ESD-protection components.The major difference between tests done using the Human Body Model and IEC1000-4-2 is higher peak current in IEC1000-4-2, because series resistance is lower in the IEC1000-4-2 model. Hence, the ESD withstand voltage measured to IEC1000-4-2 is generally lower than that measured using the Human Body Model. Figure 7b shows the current waveform for the 8kV IEC1000-4-2 level-four ESD contact-discharge test.The air-gap test involves approaching the device with a charged probe. The contact-discharge method connects the probe to the device before the probe is energized.Machine ModelThe Machine Model for ESD tests all pins using a 200pF storage capacitor and zero discharge resistance. Its objective is to emulate the stress caused by contact that occurs with handling and assembly during manufacturing. Of course, all pins require this protection during manufacturing, not just RS-232 inputs and outputs. Therefore,after PC board assembly,theMachine Model is less relevant to I/O ports.Figure 7a. IEC1000-4-2 ESD Test ModelFigure 7b. IEC1000-4-2 ESD Generator Current WaveformFigure 6a. Human Body ESD Test ModelFigure 6b. Human Body Model Current Waveform__________Applications InformationCapacitor Selection The capacitor type used for C1–C4 is not critical for proper operation. The MAX202E, MAX206–MAX208E, MAX211E, and MAX213E require 0.1µF capacitors, and the MAX232E and MAX241E require 1µF capacitors, although in all cases capacitors up to 10µF can be used without harm. Ceramic, aluminum-electrolytic, or tantalum capacitors are suggested for the 1µF capacitors, and ceramic dielectrics are suggested for the 0.1µF capacitors. When using the minimum recommended capacitor values, make sure the capacitance value does not degrade excessively as the operating temperature varies. If in doubt, use capacitors with a larger (e.g., 2x) nominal value. The capacitors’ effective series resistance (ESR), which usually rises at low temperatures, influences the amount of ripple on V+ and V-.Use larger capacitors (up to 10µF) to reduce the output impedance at V+ and V-. This can be useful when “stealing” power from V+ or from V-. The MAX203E and MAX205E have internal charge-pump capacitors. Bypass V CC to ground with at least 0.1µF. In applications sensitive to power-supply noise generated by the charge pumps, decouple V CC to ground with a capacitor the same size as (or larger than) the charge-pump capacitors (C1–C4).V+ and V- as Power Supplies A small amount of power can be drawn from V+ and V-, although this will reduce both driver output swing and noise margins. Increasing the value of the charge-pump capacitors (up to 10µF) helps maintain performance when power is drawn from V+ or V-.Driving Multiple Receivers Each transmitter is designed to drive a single receiver. Transmitters can be paralleled to drive multiple receivers.Driver Outputs when Exiting Shutdown The driver outputs display no ringing or undesirable transients as they come out of shutdown.High Data Rates These transceivers maintain the RS-232 ±5.0V minimum driver output voltages at data rates of over 120kbps. For data rates above 120kbps, refer to the Transmitter Output Voltage vs. Load Capacitance graphs in the Typical Operating Characteristics. Communication at these high rates is easier if the capacitive loads on the transmitters are small; i.e., short cables are best.Table 2. Summary of EIA/TIA-232E, V.28 SpecificationsMAX202E–MAX213E, MAX232E/MAX241EM A X 202E –M A X 213E , M A X 232E /M A X 241E____________Pin Configurations and Typical Operating Circuits (continued)Table 3. DB9 Cable ConnectionsCommonly Used for EIA/TIAE-232E and V.24 Asynchronous Interfaces____________Pin Configurations and Typical Operating Circuits (continued)MAX202E–MAX213E, MAX232E/MAX241EM A X 202E –M A X 213E , M A X 232E /M A X 241E____________Pin Configurations and Typical Operating Circuits (continued)MAX202E–MAX213E, MAX232E/MAX241E____________Pin Configurations and Typical Operating Circuits (continued)M A X 202E –M A X 213E , M A X 232E /M A X 241E____________Pin Configurations and Typical Operating Circuits (continued)MAX202E–MAX213E, MAX232E/MAX241E____________Pin Configurations and Typical Operating Circuits (continued)M A X 202E –M A X 213E , M A X 232E /M A X 241E____________Pin Configurations and Typical Operating Circuits (continued)______________________________________________________________________________________21MAX202E–MAX213E, MAX232E/MAX241E Ordering Information (continued)*Dice are specified at T A= +25°C.M A X 202E –M A X 213E , M A X 232E /M A X 241E22________________________________________________________________________________________________________________________________________________Chip Topographies___________________Chip InformationC1-V+C1+V CC R2INT2OUT R2OUT0.117"(2.972mm)0.080"(2.032mm)V-C2+ C2-T2IN T1OUT R1INR1OUT T1INGNDR5INV-C2-C2+C1-V+C1+V CC T4OUTR3IN T3OUTT1OUT 0.174"(4.420mm)0.188"(4.775mm)T4IN R5OUT R4OUT T3IN R4IN EN (EN) SHDN (SHDN)R3OUT T2OUT GNDR1IN R1OUT T2IN R2OUTR2IN T1IN ( ) ARE FOR MAX213E ONLYTRANSISTOR COUNT: 123SUBSTRATE CONNECTED TO GNDTRANSISTOR COUNT: 542SUBSTRATE CONNECTED TO GNDMAX202E/MAX232EMAX211E/MAX213E/MAX241EMAX205E/MAX206E/MAX207E/MAX208E TRANSISTOR COUNT: 328SUBSTRATE CONNECTED TO GNDMAX202E–MAX213E, MAX232E/MAX241E Package InformationM A X 202E –M A X 213E , M A X 232E /M A X 241EPackage Information (continued)MAX202E–MAX213E, MAX232E/MAX241E±15kV ESD-Protected, +5V RS-232 TransceiversMaxim 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.Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 ____________________25©2005 Maxim Integrated ProductsPrinted USAis a registered trademark of Maxim Integrated Products, Inc.Package Information (continued)(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information go to /packages .)。

________________General DescriptionThe MAX6814 is a low-power watchdog circuit in a tiny 5-pin SC70 package. This device improves system reliability by monitoring the system for software code execution errors. When the watchdog input detects a transitional edge, the internal watchdog timer clears and restarts,then begins counting again. If the watchdog timer exceeds the watchdog timeout period (1.6s typ), the active-low, push-pull watchdog output asserts for the watchdog pulse period (140ms min) to alert the system of the fault.The MAX6814 consumes only 4µA of supply current and is fully specified over the extended temperature range.________________________ApplicationsComputers and Controllers Embedded Controllers Intelligent Instruments Automotive Systems Critical µP MonitoringFeatures♦4µA Operating Current♦Watchdog Timer with 1.6s Timeout ♦140ms (min) WDO Pulse Period ♦Push-Pull Active-Low WDO♦Fully Specified Over Extended Temperature Range♦No External ComponentsMAX68145-Pin Watchdog Timer Circuit________________________________________________________________Maxim Integrated Products 119-2804; Rev 1; 3/04Ordering InformationPin ConfigurationFor pricing, delivery, and ordering information,please contact Maxim/Dallas Direct!at1-888-629-4642, or visit Maxim’s website at .Typical Operating CircuitM A X 68145-Pin Watchdog Timer Circuit 2_______________________________________________________________________________________ABSOLUTE MAXIMUM RATINGSELECTRICAL CHARACTERISTICS(V= +2.25V to +5.5V, T = T to T , T = -40°C to +85°C, unless otherwise noted. Typical values are at T = +25°C.) 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 ........................................................................-0.3V to +6.0V All Other Pins..............................................-0.3V to (V CC + 0.3V)Input Current, WDI..............................................................20mA Output Current, WDO ..........................................................20mA Continuous Power Dissipation (T A = +70°C)5-Pin SC70 (derate 3.1mW/°C above +70°C)...............247mWOperating Temperature Range ...........................-40°C to +85°C Storage Temperature Range.............................-65°C to +150°C Junction Temperature......................................................+150°C Lead Temperature (soldering, 10s).................................+300°CNote 1:Overtemperature limits are guaranteed by design, production testing performed at +25°C only.Note 2:WDO is low when V CC falls below the undervoltage threshold. When V CC rises above the undervoltage threshold, WDO goeshigh after the watchdog pulse period.Note 3:Watchdog pulse period occurs when the watchdog times out or after V CC rises above the undervoltage threshold.Note 4:The WDO short-circuit current is the maximum pullup current when WDO is driven low.Note 5:WDI is internally serviced within the watchdog period if WDI is left unconnected.Note 6:The WDI input current is specified as the average input current when the WDI input is driven high or low. The WDI input isdesigned to drive a three-stated output device with a 10µA maximum leakage current and a maximum capacitive load of 200pF. This output device must be able to source and sink at least 200µA when active.MAX68145-Pin Watchdog Timer Circuit_______________________________________________________________________________________3__________________________________________Typical Operating Characteristics(V CC = +5V, T A = +25°C, unless otherwise noted.)132654879-402040-206080100120M A X 6814 t o c 01TEMPERATURE (°C)S U P P L Y C U R R E N T (m A )V CC SUPPLY CURRENT vs. TEMPERATURE250150-40-2040100WDO PULSE PERIOD vs. TEMPERATURE170160180230240M A X 6814 t o c 02TEMPERATURE (°C)W D O P U L S E P E R I O D (m s )208060210220190200 2.01.0-40-2040100WATCHDOG TIMEOUT PERIODvs. TEMPERATURE1.21.11.31.81.9M A X 6814 t o c 03TEMPERATURE (°C)W A T C H D O G T I M E O U T P E R I O D (s )2080601.61.71.41.5M A X 68145-Pin Watchdog Timer Circuit 4_______________________________________________________________________________________Figure 1. Functional Diagram_______________Detailed DescriptionWatchdog InputIn the MAX6814, the watchdog circuit monitors the µP’s activity. If the µP does not toggle the watchdog input (WDI) within t WD (1.6s), WDO asserts. The internal 1.6s timer is cleared by either a WDO pulse or by toggling WDI, which detects pulses as short as 50ns. While WDO is asserted, the timer remains cleared and does not count. As soon as WDO is released, the timer starts counting (Figure 3).Disable the watchdog function by leaving WDI uncon-nected or by three-stating the driver connected to WDI.The watchdog input is internally driven low during the first 7/8 of the watchdog timeout period and high for the last 1/8 of the watchdog timeout period. When WDI is left unconnected, this internal driver clears the 1.6s timer every 1.4s. When WDI is three-stated or unconnected,the maximum allowable leakage current is 10µA and the maximum allowable load capacitance is 200pF.Applications InformationWatchdog Input CurrentThe MAX6814 WDI inputs are internally driven through a buffer and series resistor from the watchdog counter (Figure 1). When WDI is left unconnected, the watch-dog timer is serviced within the watchdog timeout peri-od by a low-high-low pulse from the counter chain. For minimum watchdog input current (minimum overall power consumption), leave WDI low for the majority of the watchdog timeout period, pulsing it low-high-low once within the first 7/8 of the watchdog timeout period to clear the watchdog timer. If WDI is externally driven high for the majority of the timeout period, up to 160µA can flow into WDI.MAX68145-Pin Watchdog Timer Circuit_______________________________________________________________________________________5____________________Chip InformationTRANSISTOR COUNT: 607PROCESS: BiCMOSWatchdog Software ConsiderationsOne way to help the watchdog timer monitor software execution more closely is to set and clear the watchdog input at different points in the program, rather than pulsing the watchdog input high-low-high or low-high-low. This technique avoids a stuck loop, in which the watchdog timer would continue to be cleared inside the loop, keeping the watchdog from timing out.Figure 4 shows an example of a flow diagram where the I/O driving the watchdog input is set high at the beginning of the program, set low at the beginning ofevery subroutine or loop, then set high again when the program returns to the beginning. If the program should hang in any subroutine, the problem would quickly be corrected, since the I/O is continually set low and the watchdog timer is allowed to time out, causing an interrupt to be issued. This scheme results in higher time average WDI input current than does leaving WDI low for the majority of the timeout period and periodi-cally pulsing it low-high-low (see the Watchdog Input Current section).Figure 4. Watchdog Flow DiagramFigure 3. Watchdog Timing RelationshipMaxim 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.6___________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 (408) 737-7600©2004 Maxim Integrated ProductsPrinted USAis a registered trademark of Maxim Integrated Products.M A X 68145-Pin Watchdog Timer Circuit Package Information(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information go to /packages .)S C 70, 5L .E PS。

For free samples & the latest literature: , or phone 1-800-998-8800.For small orders, phone 1-800-835-8769.General DescriptionThe MAX4664/MAX4665/MAX4666 quad analog switch-es feature 5Ωmax on-resistance. On-resistance is matched between switches to 0.5Ωmax and is flat (0.5Ωmax) over the specified signal range. Each switch can handle Rail-to-Rail ®analog signals. The off-leakage cur-rent is only 5nA max at +85°C. These analog switches are ideal in low-distortion applications and are the pre-ferred solution over mechanical relays in automatic test equipment or in applications where current switching is required. They have low power requirements, require less board space, and are more reliable than mechanical relays.The MAX4664 has four normally closed (NC) switches,the MAX4665 has four normally open (NO) switches, and the MAX4666 has two NC and two NO switches that guarantee break-before-make switching times.These switches operate from a single +4.5V to +36V supply or from dual ±4.5V to ±20V supplies. All digital inputs have +0.8V and +2.4V logic thresholds, ensuring TTL/CMOS-logic compatibility when using ±15V sup-plies or a single +12V supply.ApplicationsReed Relay Replacement PBX, PABX Systems Test EquipmentAudio-Signal Routing Communication SystemsAvionicsFeatureso Low On-Resistance (5Ωmax)o Guaranteed R ON Match Between Channels (0.5Ωmax)o Guaranteed R ON Flatness over Specified Signal Range (0.5Ωmax)o Guaranteed Break-Before-Make (MAX4666)o Rail-to-Rail Signal Handlingo Guaranteed ESD Protection > 2kV per Method 3015.7o +4.5V to +36V Single-Supply Operation ±4.5V to ±20V Dual-Supply Operation o TTL/CMOS-Compatible Control InputsMAX4664/MAX4665/MAX46665Ω, Quad, SPST,CMOS Analog Switches________________________________________________________________Maxim Integrated Products1Pin Configurations/Functional Diagrams/Truth Tables19-1504; Rev 0; 7/99Ordering Information continued at end of data sheet.Ordering InformationRail-to-Rail is a registered trademark of Nippon Motorola, Ltd.M A X 4664/M A X 4665/M A X 46665Ω, Quad, SPST,CMOS Analog Switches 2_______________________________________________________________________________________ABSOLUTE MAXIMUM RATINGSNote 1:Signals on NC_, NO_, COM_, or IN_ exceeding V+ or V- are clamped by internal diodes. Limit forward-diode current tomaximum current rating.V+ to GND..............................................................-0.3V to +44V V- to GND..............................................................+0.3V to -44V V+ to V-...................................................................-0.3V to +44V V L to GND........................................(GND - 0.3V) to (V+ + 0.3V)All Other Pins to DGND (Note 1).........(V- - 0.3V) to (V+ + 0.3V) Continuous Current (COM_, NO_, NC_) ........................±100mA Peak Current (COM_, NO_, NC_)(pulsed at 1ms, 10% duty cycle)...............................±300mAContinuous Power Dissipation (T A = +70°C)Narrow SO (derate 8.70mW/°C above +70°C)...............696mW Plastic DIP (derate 10.53mW/°C above +70°C)..............842mW Operating Temperature RangesMAX466_C_E ......................................................0°C to +70°C MAX466_E_E....................................................-40°C to +85°C Storage Temperature Range.............................-65°C to +150°C Lead Temperature (soldering, 10sec).............................+300°CELECTRICAL CHARACTERISTICS—Dual Supplies(V+ = +15V, V- = -15V, V L = +5V, V IN_H = +2.4V, V IN_L = +0.8V, T A = T MIN to T MAX , unless otherwise noted. Typical values are at T A = +25°C.) (Note 2)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.ELECTRICAL CHARACTERISTICS—Dual Supplies (continued)MAX4664/MAX4665/MAX46665Ω, Quad, SPST,CMOS Analog Switches (V+ = +15V, V- = -15V, V L= +5V, V IN_H= +2.4V, V IN_L= +0.8V, T A= T MIN to T MAX, unless otherwise noted. Typical values are atT A= +25°C.) (Note 2)_______________________________________________________________________________________3M A X 4664/M A X 4665/M A X 46665Ω, Quad, SPST,CMOS Analog Switches 4_______________________________________________________________________________________ELECTRICAL CHARACTERISTICS—Single Supply(V+ = +12V, V- = 0, V L = +5V, V IN_H = +2.4V, V IN_L = +0.8V, T A = T MIN to T MAX , unless otherwise noted. Typical values are at T A = +25°C.)ELECTRICAL CHARACTERISTICS—Single Supply (continued)MAX4664/MAX4665/MAX46665Ω, Quad, SPST,CMOS Analog Switches (V+ = +12V, V- = 0, V L= +5V, V IN_H= +2.4V, V IN_L= +0.8V, T A= T MIN to T MAX, unless otherwise noted. Typical values are at T A= +25°C.)(Note 2)Note 2:The algebraic convention, where the most negative value is a minimum and the most positive value a maximum, is used in this data sheet.Note 3:Guaranteed by design.Note 4:∆R ON= R ON(MAX)- R ON(MIN).Note 5:Flatness is defined as the difference between the maximum and minimum value of on-resistance as measured over the specified analog signal range.Note 6:Leakage parameters are 100% tested at maximum-rated hot temperature and guaranteed by correlation at +25°C.Note 7:Off-isolation = 20log10[V COM_/ (V NC_or V NO_)], V COM_= output, V NC_or V NO_= input to off switch.Note 8:Between any two switches.Note 9:Leakage testing at single supply is guaranteed by testing with dual supplies._______________________________________________________________________________________5M A X 4664/M A X 4665/M A X 46665Ω, Quad, SPST,CMOS Analog Switches 6_______________________________________________________________________________________Typical Operating Characteristics(T A = +25°C, unless otherwise noted.)2.03.02.54.03.55.04.55.56.56.07.0-20-10-5-1505101520ON-RESISTANCEV COM (V)R O N (Ω)1.52.52.03.53.04.54.05.0-15-50-1051015ON-RESISTANCE vs. V COMAND TEMPERATURE (DUAL SUPPLIES)V COM (V)R O N (Ω)421086121416180693121518212427303336ON-RESISTANCE vs. V COM(SINGLE SUPPLY)V COM (V)R O N (Ω)3.04.54.03.55.05.56.06.57.07.58.0042681012ON-RESISTANCE vs. V COMAND TEMPERATURE (SINGLE SUPPLY)V COM (V)R O N (Ω)040201008060120140160180-10-6-4-8-22410ON/OFF TIMES vs. V COM(DUAL SUPPLIES)V COM (V)t O N , t O F F (n s )680.0110k 1010.11001k 100k-40-10520-253550100958065ON/OFF-LEAKAGE CURRENTvs. TEMPERATURETEMPERATURE (°C)L E A K A G E (p A )-200-1002001000300400500600-20-10-5-1505101520CHARGE INJECTIONvs. V V COM (V)Q (p C )15010025020030004628101214ON/OFF TIMES vs. V COM(SINGLE SUPPLY)V COM (V)t O N , t O F F (n s )5050807011010090120130140150101213111415161720ON/OFF TIMES vs. SUPPLY VOLTAGE(DUAL SUPPIES)V+ = -V (V)t O N , t O F F (n s )18196002001003004005006000101552025303540ON/OFF TIMES vs. SUPPLY VOLTAGE(SINGLE SUPPLY)V+ (V)t O N , t O F F (n s )8060100120140160-60-20-4020406080100ON/OFF TIMES vs. TEMPERATURE(DUAL SUPPLIES)TEMPERATURE (°C)t O N , t O F F (n s )40200.0110.1101001k 10k -60-20-4020406080100SUPPLY CURRENT vs. TEMPERATURETEMPERATURE (°C)I +, I - (p A )-1000.011100.1100FREQUENCY RESPONSEFREQUENCY (MHz)L O S S (d B )-90-80-70-60-50-40-30-20-100200150250300350400-60-200-4020406080100ON/OFF TIMES vs. TEMPERATURE(SINGLE SUPPLY)TEMPERATURE (°C)t O N , t O F F (n s )10050MAX4664/MAX4665/MAX46665Ω, Quad, SPST,CMOS Analog Switches_______________________________________________________________________________________7Typical Operating Characteristics (continued)(T A = +25°C, unless otherwise noted.)M A X 4664/M A X 4665/M A X 46665Ω, Quad, SPST,CMOS Analog Switches 8_______________________________________________________________________________________Applications InformationOvervoltage ProtectionProper power-supply sequencing is recommended for all CMOS devices. Do not exceed the absolute maxi-mum ratings, because stresses beyond the listed rat-ings can cause permanent damage to the devices.Always sequence V+ on first, then V-, followed by the logic inputs, NO, or COM. If power-supply sequencing is not possible, add two small signal diodes (D1, D2) in series with supply pins (Figure 1). Adding diodes reduces the analog signal range to one diode drop below V+ and one diode drop above V-, but does not affect the devices’ low switch resistance and low leak-age characteristics. Device operation is unchanged,and the difference between V+ and V- should not exceed 44V. These protection diodes are not recom-mended when using a single supply.Off-Isolation at High FrequenciesIn 50Ωsystems, the high-frequency on-response of these parts extends from DC to above 100MHz, with a typical loss of -2dB. When the switch is turned off, how-ever, it behaves like a capacitor, and off-isolation decreases with increasing frequency. (Above 300MHz,the switch actually passes more signal turned off than turned on.) This effect is more pronounced with higher source and load impedances.Figure 1. Overvoltage Protection Using External Blocking DiodesPin DescriptionMAX4664/MAX4665/MAX46665Ω, Quad, SPST,CMOS Analog Switches_______________________________________________________________________________________9Figure 2. Switching-Time Test CircuitAbove 5MHz, circuit board layout becomes critical,and it becomes difficult to characterize the response of the switch independent of the circuit. The graphs shown in the Typical Operating Characteristics were taken using a 50Ωsource and load connected with BNC connectors to a circuit board deemed “average,”that is, designed with isolation in mind, but not using stripline or other special RF circuit techniques. For criti-cal applications above 5MHz, use the MAX440,MAX441, and MAX442, which are fully characterized up to 160MHz.Figure 3. Charge-Injection Test CircuitM A X 4664/M A X 4665/M A X 46665Ω, Quad, SPST,CMOS Analog Switches 10______________________________________________________________________________________Figure 6. Switch Off-Capacitance Test Circuit Figure 7. Switch On-Capacitance Test CircuitFigure 4. Off-Isolation Test CircuitFigure 5. Crosstalk Test CircuitMAX4664/MAX4665/MAX46665Ω, Quad, SPST,CMOS Analog SwitchesChip InformationTRANSISTOR COUNT: 108Ordering Information (continued)Package InformationM A X 4664/M A X 4665/M A X 46665Ω, Quad, SPST,CMOS Analog Switches Maxim 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.12____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600©1999 Maxim Integrated ProductsPrinted USAis a registered trademark of Maxim Integrated Products.Package Information (continued)。

For pricing, delivery, and ordering information,please contact Maxim/Dallas Direct!at 1-888-629-4642, or visit Maxim’s website at .General DescriptionThe MAX481, MAX483, MAX485, MAX487–MAX491, and MAX1487 are low-power transceivers for RS-485 and RS-422 communication. Each part contains one driver and one receiver. The MAX483, MAX487, MAX488, and MAX489feature reduced slew-rate drivers that minimize EMI and reduce reflections caused by improperly terminated cables,thus allowing error-free data transmission up to 250kbps.The driver slew rates of the MAX481, MAX485, MAX490,MAX491, and MAX1487 are not limited, allowing them to transmit up to 2.5Mbps.These transceivers draw between 120µA and 500µA of supply current when unloaded or fully loaded with disabled drivers. Additionally, the MAX481, MAX483, and MAX487have a low-current shutdown mode in which they consume only 0.1µA. All parts operate from a single 5V supply.Drivers are short-circuit current limited and are protected against excessive power dissipation by thermal shutdown circuitry that places the driver outputs into a high-imped-ance state. The receiver input has a fail-safe feature that guarantees a logic-high output if the input is open circuit.The MAX487 and MAX1487 feature quarter-unit-load receiver input impedance, allowing up to 128 MAX487/MAX1487 transceivers on the bus. Full-duplex communi-cations are obtained using the MAX488–MAX491, while the MAX481, MAX483, MAX485, MAX487, and MAX1487are designed for half-duplex applications.________________________ApplicationsLow-Power RS-485 Transceivers Low-Power RS-422 Transceivers Level TranslatorsTransceivers for EMI-Sensitive Applications Industrial-Control Local Area Networks__Next Generation Device Features♦For Fault-Tolerant ApplicationsMAX3430: ±80V Fault-Protected, Fail-Safe, 1/4Unit Load, +3.3V, RS-485 TransceiverMAX3440E–MAX3444E: ±15kV ESD-Protected,±60V Fault-Protected, 10Mbps, Fail-Safe, RS-485/J1708 Transceivers♦For Space-Constrained ApplicationsMAX3460–MAX3464: +5V, Fail-Safe, 20Mbps,Profibus RS-485/RS-422 TransceiversMAX3362: +3.3V, High-Speed, RS-485/RS-422Transceiver in a SOT23 PackageMAX3280E–MAX3284E: ±15kV ESD-Protected,52Mbps, +3V to +5.5V, SOT23, RS-485/RS-422,True Fail-Safe ReceiversMAX3293/MAX3294/MAX3295: 20Mbps, +3.3V,SOT23, RS-855/RS-422 Transmitters ♦For Multiple Transceiver ApplicationsMAX3030E–MAX3033E: ±15kV ESD-Protected,+3.3V, Quad RS-422 Transmitters ♦For Fail-Safe ApplicationsMAX3080–MAX3089: Fail-Safe, High-Speed (10Mbps), Slew-Rate-Limited RS-485/RS-422Transceivers♦For Low-Voltage ApplicationsMAX3483E/MAX3485E/MAX3486E/MAX3488E/MAX3490E/MAX3491E: +3.3V Powered, ±15kV ESD-Protected, 12Mbps, Slew-Rate-Limited,True RS-485/RS-422 TransceiversMAX481/MAX483/MAX485/MAX487–MAX491/MAX1487Low-Power, Slew-Rate-Limited RS-485/RS-422 Transceivers______________________________________________________________Selection Table19-0122; Rev 8; 10/03Ordering Information appears at end of data sheet.M A X 481/M A X 483/M A X 485/M A X 487–M A X 491/M A X 1487Low-Power, Slew-Rate-Limited RS-485/RS-422 Transceivers 2_______________________________________________________________________________________ABSOLUTE MAXIMUM RATINGSSupply Voltage (V CC ).............................................................12V Control Input Voltage (RE , DE)...................-0.5V to (V CC + 0.5V)Driver Input Voltage (DI).............................-0.5V to (V CC + 0.5V)Driver Output Voltage (A, B)...................................-8V to +12.5V Receiver Input Voltage (A, B).................................-8V to +12.5V Receiver Output Voltage (RO).....................-0.5V to (V CC +0.5V)Continuous Power Dissipation (T A = +70°C)8-Pin Plastic DIP (derate 9.09mW/°C above +70°C)....727mW 14-Pin Plastic DIP (derate 10.00mW/°C above +70°C)..800mW 8-Pin SO (derate 5.88mW/°C above +70°C).................471mW14-Pin SO (derate 8.33mW/°C above +70°C)...............667mW 8-Pin µMAX (derate 4.1mW/°C above +70°C)..............830mW 8-Pin CERDIP (derate 8.00mW/°C above +70°C).........640mW 14-Pin CERDIP (derate 9.09mW/°C above +70°C).......727mW Operating Temperature RangesMAX4_ _C_ _/MAX1487C_ A...............................0°C to +70°C MAX4__E_ _/MAX1487E_ A.............................-40°C to +85°C MAX4__MJ_/MAX1487MJA...........................-55°C to +125°C Storage Temperature Range.............................-65°C to +160°C Lead Temperature (soldering, 10sec).............................+300°CDC ELECTRICAL CHARACTERISTICS(V CC = 5V ±5%, T A = T MIN to T MAX , unless otherwise noted.) (Notes 1, 2)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 V IN = -7VV IN = 12V V IN = -7V V IN = 12V Input Current (A, B)I IN2V TH k Ω48-7V ≤V CM ≤12V, MAX487/MAX1487R INReceiver Input Resistance -7V ≤V CM ≤12V, all devices except MAX487/MAX1487R = 27Ω(RS-485), Figure 40.4V ≤V O ≤2.4VR = 50Ω(RS-422)I O = 4mA, V ID = -200mV I O = -4mA, V ID = 200mV V CM = 0V-7V ≤V CM ≤12V DE, DI, RE DE, DI, RE MAX487/MAX1487,DE = 0V, V CC = 0V or 5.25VDE, DI, RE R = 27Ωor 50Ω, Figure 4R = 27Ωor 50Ω, Figure 4R = 27Ωor 50Ω, Figure 4DE = 0V;V CC = 0V or 5.25V,all devices except MAX487/MAX1487CONDITIONSk Ω12µA ±1I OZRThree-State (high impedance)Output Current at ReceiverV 0.4V OL Receiver Output Low Voltage 3.5V OH Receiver Output High Voltage mV 70∆V TH Receiver Input Hysteresis V -0.20.2Receiver Differential Threshold Voltage-0.2mA 0.25mA-0.81.01.55V OD2Differential Driver Output (with load)V 2V 5V OD1Differential Driver Output (no load)µA±2I IN1Input CurrentV 0.8V IL Input Low Voltage V 2.0V IH Input High Voltage V 0.2∆V OD Change in Magnitude of Driver Common-Mode Output Voltage for Complementary Output States V 0.2∆V OD Change in Magnitude of Driver Differential Output Voltage for Complementary Output States V 3V OC Driver Common-Mode Output VoltageUNITS MINTYPMAX SYMBOL PARAMETERMAX481/MAX483/MAX485/MAX487–MAX491/MAX1487Low-Power, Slew-Rate-Limited RS-485/RS-422 Transceivers_______________________________________________________________________________________3SWITCHING CHARACTERISTICS—MAX481/MAX485, MAX490/MAX491, MAX1487(V CC = 5V ±5%, T A = T MIN to T MAX , unless otherwise noted.) (Notes 1, 2)DC ELECTRICAL CHARACTERISTICS (continued)(V CC = 5V ±5%, T A = T MIN to T MAX , unless otherwise noted.) (Notes 1, 2)ns 103060t PHLDriver Rise or Fall Time Figures 6 and 8, R DIFF = 54Ω, C L1= C L2= 100pF ns MAX490M, MAX491M MAX490C/E, MAX491C/E2090150MAX481, MAX485, MAX1487MAX490M, MAX491MMAX490C/E, MAX491C/E MAX481, MAX485, MAX1487Figures 6 and 8, R DIFF = 54Ω,C L1= C L2= 100pF MAX481 (Note 5)Figures 5 and 11, C RL = 15pF, S2 closedFigures 5 and 11, C RL = 15pF, S1 closed Figures 5 and 11, C RL = 15pF, S2 closed Figures 5 and 11, C RL = 15pF, S1 closed Figures 6 and 10, R DIFF = 54Ω,C L1= C L2= 100pFFigures 6 and 8,R DIFF = 54Ω,C L1= C L2= 100pF Figures 6 and 10,R DIFF = 54Ω,C L1= C L2= 100pF CONDITIONS ns 510t SKEW ns50200600t SHDNTime to ShutdownMbps 2.5f MAX Maximum Data Rate ns 2050t HZ Receiver Disable Time from High ns 103060t PLH 2050t LZ Receiver Disable Time from Low ns 2050t ZH Driver Input to Output Receiver Enable to Output High ns 2050t ZL Receiver Enable to Output Low 2090200ns ns 134070t HZ t SKD Driver Disable Time from High |t PLH - t PHL |DifferentialReceiver Skewns 4070t LZ Driver Disable Time from Low ns 4070t ZL Driver Enable to Output Low 31540ns51525ns 31540t R , t F 2090200Driver Output Skew to Output t PLH , t PHL Receiver Input to Output4070t ZH Driver Enable to Output High UNITS MIN TYP MAX SYMBOL PARAMETERFigures 7 and 9, C L = 100pF, S2 closed Figures 7 and 9, C L = 100pF, S1 closed Figures 7 and 9, C L = 15pF, S1 closed Figures 7 and 9, C L = 15pF, S2 closedM A X 481/M A X 483/M A X 485/M A X 487–M A X 491/M A X 1487Low-Power, Slew-Rate-Limited RS-485/RS-422 Transceivers 4_______________________________________________________________________________________SWITCHING CHARACTERISTICS—MAX483, MAX487/MAX488/MAX489(V CC = 5V ±5%, T A = T MIN to T MAX , unless otherwise noted.) (Notes 1, 2)SWITCHING CHARACTERISTICS—MAX481/MAX485, MAX490/MAX491, MAX1487 (continued)(V CC = 5V ±5%, T A = T MIN to T MAX , unless otherwise noted.) (Notes 1, 2)3001000Figures 7 and 9, C L = 100pF, S2 closed Figures 7 and 9, C L = 100pF, S1 closed Figures 5 and 11, C L = 15pF, S2 closed,A - B = 2VCONDITIONSns 40100t ZH(SHDN)Driver Enable from Shutdown toOutput High (MAX481)nsFigures 5 and 11, C L = 15pF, S1 closed,B - A = 2Vt ZL(SHDN)Receiver Enable from Shutdownto Output Low (MAX481)ns 40100t ZL(SHDN)Driver Enable from Shutdown toOutput Low (MAX481)ns 3001000t ZH(SHDN)Receiver Enable from Shutdownto Output High (MAX481)UNITS MINTYP MAX SYMBOLPARAMETERt PLH t SKEW Figures 6 and 8, R DIFF = 54Ω,C L1= C L2= 100pFt PHL Figures 6 and 8, R DIFF = 54Ω,C L1= C L2= 100pFDriver Input to Output Driver Output Skew to Output ns 100800ns ns 2000MAX483/MAX487, Figures 7 and 9,C L = 100pF, S2 closedt ZH(SHDN)Driver Enable from Shutdown to Output High2502000ns2500MAX483/MAX487, Figures 5 and 11,C L = 15pF, S1 closedt ZL(SHDN)Receiver Enable from Shutdown to Output Lowns 2500MAX483/MAX487, Figures 5 and 11,C L = 15pF, S2 closedt ZH(SHDN)Receiver Enable from Shutdown to Output Highns 2000MAX483/MAX487, Figures 7 and 9,C L = 100pF, S1 closedt ZL(SHDN)Driver Enable from Shutdown to Output Lowns 50200600MAX483/MAX487 (Note 5) t SHDN Time to Shutdownt PHL t PLH , t PHL < 50% of data period Figures 5 and 11, C RL = 15pF, S2 closed Figures 5 and 11, C RL = 15pF, S1 closed Figures 5 and 11, C RL = 15pF, S2 closed Figures 5 and 11, C RL = 15pF, S1 closed Figures 7 and 9, C L = 15pF, S2 closed Figures 6 and 10, R DIFF = 54Ω,C L1= C L2= 100pFFigures 7 and 9, C L = 15pF, S1 closed Figures 7 and 9, C L = 100pF, S1 closed Figures 7 and 9, C L = 100pF, S2 closed CONDITIONSkbps 250f MAX 2508002000Maximum Data Rate ns 2050t HZ Receiver Disable Time from High ns 25080020002050t LZ Receiver Disable Time from Low ns 2050t ZH Receiver Enable to Output High ns 2050t ZL Receiver Enable to Output Low ns ns 1003003000t HZ t SKD Driver Disable Time from High I t PLH - t PHL I DifferentialReceiver SkewFigures 6 and 10, R DIFF = 54Ω,C L1= C L2= 100pFns 3003000t LZ Driver Disable Time from Low ns 2502000t ZL Driver Enable to Output Low ns Figures 6 and 8, R DIFF = 54Ω,C L1= C L2= 100pFns 2502000t R , t F 2502000Driver Rise or Fall Time ns t PLH Receiver Input to Output2502000t ZH Driver Enable to Output High UNITS MIN TYP MAX SYMBOL PARAMETERMAX481/MAX483/MAX485/MAX487–MAX491/MAX1487Low-Power, Slew-Rate-Limited RS-485/RS-422 Transceivers_______________________________________________________________________________________530002.5OUTPUT CURRENT vs.RECEIVER OUTPUT LOW VOLTAGE525M A X 481-01OUTPUT LOW VOLTAGE (V)O U T P U T C U R R E N T (m A )1.515100.51.02.0203540450.90.1-50-252575RECEIVER OUTPUT LOW VOLTAGE vs.TEMPERATURE0.30.7TEMPERATURE (°C)O U T P U TL O W V O L T A G E (V )500.50.80.20.60.40100125-20-41.5 2.0 3.0 5.0OUTPUT CURRENT vs.RECEIVER OUTPUT HIGH VOLTAGE-8-16M A X 481-02OUTPUT HIGH VOLTAGE (V)O U T P U T C U R R E N T (m A )2.5 4.0-12-18-6-14-10-203.54.5 4.83.2-50-252575RECEIVER OUTPUT HIGH VOLTAGE vs.TEMPERATURE3.64.4TEMPERATURE (°C)O U T P UT H I G H V O L T A G E (V )0504.04.63.44.23.83.01001259000 1.0 3.0 4.5DRIVER OUTPUT CURRENT vs.DIFFERENTIAL OUTPUT VOLTAGE1070M A X 481-05DIFFERENTIAL OUTPUT VOLTAGE (V)O U T P U T C U R R E N T (m A )2.0 4.05030806040200.5 1.5 2.53.5 2.31.5-50-2525125DRIVER DIFFERENTIAL OUTPUT VOLTAGEvs. TEMPERATURE1.72.1TEMPERATURE (°C)D I F FE R E N T I A L O U T P U T V O L T A G E (V )751.92.21.62.01.8100502.4__________________________________________Typical Operating Characteristics(V CC = 5V, T A = +25°C, unless otherwise noted.)NOTES FOR ELECTRICAL/SWITCHING CHARACTERISTICSNote 1:All currents into device pins are positive; all currents out of device pins are negative. All voltages are referenced to deviceground unless otherwise specified.Note 2:All typical specifications are given for V CC = 5V and T A = +25°C.Note 3:Supply current specification is valid for loaded transmitters when DE = 0V.Note 4:Applies to peak current. See Typical Operating Characteristics.Note 5:The MAX481/MAX483/MAX487 are put into shutdown by bringing RE high and DE low. If the inputs are in this state for lessthan 50ns, the parts are guaranteed not to enter shutdown. If the inputs are in this state for at least 600ns, the parts are guaranteed to have entered shutdown. See Low-Power Shutdown Mode section.M A X 481/M A X 483/M A X 485/M A X 487–M A X 491/M A X 1487Low-Power, Slew-Rate-Limited RS-485/RS-422 Transceivers 6___________________________________________________________________________________________________________________Typical Operating Characteristics (continued)(V CC = 5V, T A = +25°C, unless otherwise noted.)120008OUTPUT CURRENT vs.DRIVER OUTPUT LOW VOLTAGE20100M A X 481-07OUTPUT LOW VOLTAGE (V)O U T P U T C U R R E N T (m A )6604024801012140-1200-7-5-15OUTPUT CURRENT vs.DRIVER OUTPUT HIGH VOLTAGE-20-80M A X 481-08OUTPUT HIGH VOLTAGE (V)O U T P U T C U R R E N T (m A )-31-603-6-4-2024-100-40100-40-60-2040100120MAX1487SUPPLY CURRENT vs. TEMPERATURE300TEMPERATURE (°C)S U P P L Y C U R R E N T (µA )20608050020060040000140100-50-2550100MAX481/MAX485/MAX490/MAX491SUPPLY CURRENT vs. TEMPERATURE300TEMPERATURE (°C)S U P P L Y C U R R E N T (µA )257550020060040000125100-50-2550100MAX483/MAX487–MAX489SUPPLY CURRENT vs. TEMPERATURE300TEMPERATURE (°C)S U P P L Y C U R R E N T (µA )257550020060040000125MAX481/MAX483/MAX485/MAX487–MAX491/MAX1487Low-Power, Slew-Rate-Limited RS-485/RS-422 Transceivers_______________________________________________________________________________________7______________________________________________________________Pin DescriptionFigure 1. MAX481/MAX483/MAX485/MAX487/MAX1487 Pin Configuration and Typical Operating CircuitM A X 481/M A X 483/M A X 485/M A X 487–M A X 491/M A X 1487__________Applications InformationThe MAX481/MAX483/MAX485/MAX487–MAX491 and MAX1487 are low-power transceivers for RS-485 and RS-422 communications. The MAX481, MAX485, MAX490,MAX491, and MAX1487 can transmit and receive at data rates up to 2.5Mbps, while the MAX483, MAX487,MAX488, and MAX489 are specified for data rates up to 250kbps. The MAX488–MAX491 are full-duplex trans-ceivers while the MAX481, MAX483, MAX485, MAX487,and MAX1487 are half-duplex. In addition, Driver Enable (DE) and Receiver Enable (RE) pins are included on the MAX481, MAX483, MAX485, MAX487, MAX489,MAX491, and MAX1487. When disabled, the driver and receiver outputs are high impedance.MAX487/MAX1487:128 Transceivers on the BusThe 48k Ω, 1/4-unit-load receiver input impedance of the MAX487 and MAX1487 allows up to 128 transceivers on a bus, compared to the 1-unit load (12k Ωinput impedance) of standard RS-485 drivers (32 trans-ceivers maximum). Any combination of MAX487/MAX1487 and other RS-485 transceivers with a total of 32 unit loads or less can be put on the bus. The MAX481/MAX483/MAX485 and MAX488–MAX491 have standard 12k ΩReceiver Input impedance.Low-Power, Slew-Rate-Limited RS-485/RS-422 Transceivers 8_______________________________________________________________________________________Figure 2. MAX488/MAX490 Pin Configuration and Typical Operating CircuitFigure 3. MAX489/MAX491 Pin Configuration and Typical Operating CircuitMAX483/MAX487/MAX488/MAX489:Reduced EMI and ReflectionsThe MAX483 and MAX487–MAX489 are slew-rate limit-ed, minimizing EMI and reducing reflections caused by improperly terminated cables. Figure 12 shows the dri-ver output waveform and its Fourier analysis of a 150kHz signal transmitted by a MAX481, MAX485,MAX490, MAX491, or MAX1487. High-frequency har-monics with large amplitudes are evident. Figure 13shows the same information displayed for a MAX483,MAX487, MAX488, or MAX489 transmitting under the same conditions. Figure 13’s high-frequency harmonics have much lower amplitudes, and the potential for EMI is significantly reduced.MAX481/MAX483/MAX485/MAX487–MAX491/MAX1487Low-Power, Slew-Rate-Limited RS-485/RS-422 Transceivers_______________________________________________________________________________________9_________________________________________________________________Test CircuitsFigure 4. Driver DC Test Load Figure 5. Receiver Timing Test LoadFigure 6. Driver/Receiver Timing Test Circuit Figure 7. Driver Timing Test LoadM A X 481/M A X 483/M A X 485/M A X 487–M A X 491/M A X 1487Low-Power, Slew-Rate-Limited RS-485/RS-422 Transceivers 10_______________________________________________________Switching Waveforms_________________Function Tables (MAX481/MAX483/MAX485/MAX487/MAX1487)Figure 8. Driver Propagation DelaysFigure 9. Driver Enable and Disable Times (except MAX488 and MAX490)Figure 10. Receiver Propagation DelaysFigure 11. Receiver Enable and Disable Times (except MAX488and MAX490)Table 1. TransmittingTable 2. ReceivingLow-Power Shutdown Mode (MAX481/MAX483/MAX487)A low-power shutdown mode is initiated by bringing both RE high and DE low. The devices will not shut down unless both the driver and receiver are disabled.In shutdown, the devices typically draw only 0.1µA of supply current.RE and DE may be driven simultaneously; the parts are guaranteed not to enter shutdown if RE is high and DE is low for less than 50ns. If the inputs are in this state for at least 600ns, the parts are guaranteed to enter shutdown.For the MAX481, MAX483, and MAX487, the t ZH and t ZL enable times assume the part was not in the low-power shutdown state (the MAX485/MAX488–MAX491and MAX1487 can not be shut down). The t ZH(SHDN)and t ZL(SHDN)enable times assume the parts were shut down (see Electrical Characteristics ).It takes the drivers and receivers longer to become enabled from the low-power shutdown state (t ZH(SHDN ), t ZL(SHDN)) than from the operating mode (t ZH , t ZL ). (The parts are in operating mode if the –R —E –,DE inputs equal a logical 0,1 or 1,1 or 0, 0.)Driver Output ProtectionExcessive output current and power dissipation caused by faults or by bus contention are prevented by two mechanisms. A foldback current limit on the output stage provides immediate protection against short cir-cuits over the whole common-mode voltage range (see Typical Operating Characteristics ). In addition, a ther-mal shutdown circuit forces the driver outputs into a high-impedance state if the die temperature rises excessively.Propagation DelayMany digital encoding schemes depend on the differ-ence between the driver and receiver propagation delay times. Typical propagation delays are shown in Figures 15–18 using Figure 14’s test circuit.The difference in receiver delay times, | t PLH - t PHL |, is typically under 13ns for the MAX481, MAX485,MAX490, MAX491, and MAX1487 and is typically less than 100ns for the MAX483 and MAX487–MAX489.The driver skew times are typically 5ns (10ns max) for the MAX481, MAX485, MAX490, MAX491, and MAX1487, and are typically 100ns (800ns max) for the MAX483 and MAX487–MAX489.MAX481/MAX483/MAX485/MAX487–MAX491/MAX1487Low-Power, Slew-Rate-Limited RS-485/RS-422 Transceivers______________________________________________________________________________________1110dB/div0Hz5MHz500kHz/div10dB/div0Hz5MHz500kHz/divFigure 12. Driver Output Waveform and FFT Plot of MAX481/MAX485/MAX490/MAX491/MAX1487 Transmitting a 150kHz SignalFigure 13. Driver Output Waveform and FFT Plot of MAX483/MAX487–MAX489 Transmitting a 150kHz SignalM A X 481/M A X 483/M A X 485/M A X 487–M A X 491/M A X 1487Low-Power, Slew-Rate-Limited RS-485/RS-422 Transceivers 12______________________________________________________________________________________V CC = 5V T A = +25°CV CC = 5V T A = +25°CV CC = 5V T A = +25°CV CC = 5V T A = +25°CFigure 14. Receiver Propagation Delay Test CircuitFigure 15. MAX481/MAX485/MAX490/MAX491/MAX1487Receiver t PHLFigure 16. MAX481/MAX485/MAX490/MAX491/MAX1487Receiver t PLHPHL Figure 18. MAX483, MAX487–MAX489 Receiver t PLHLine Length vs. Data RateThe RS-485/RS-422 standard covers line lengths up to 4000 feet. For line lengths greater than 4000 feet, see Figure 23.Figures 19 and 20 show the system differential voltage for the parts driving 4000 feet of 26AWG twisted-pair wire at 110kHz into 120Ωloads.Typical ApplicationsThe MAX481, MAX483, MAX485, MAX487–MAX491, and MAX1487 transceivers are designed for bidirectional data communications on multipoint bus transmission lines.Figures 21 and 22 show typical network applications circuits. These parts can also be used as line repeaters, with cable lengths longer than 4000 feet, as shown in Figure 23.To minimize reflections, the line should be terminated at both ends in its characteristic impedance, and stub lengths off the main line should be kept as short as possi-ble. The slew-rate-limited MAX483 and MAX487–MAX489are more tolerant of imperfect termination.MAX481/MAX483/MAX485/MAX487–MAX491/MAX1487Low-Power, Slew-Rate-Limited RS-485/RS-422 Transceivers______________________________________________________________________________________13DIV Y -V ZRO5V 0V1V0V -1V5V 0V2µs/divFigure 19. MAX481/MAX485/MAX490/MAX491/MAX1487 System Differential Voltage at 110kHz Driving 4000ft of Cable Figure 20. MAX483, MAX487–MAX489 System Differential Voltage at 110kHz Driving 4000ft of CableFigure 21. MAX481/MAX483/MAX485/MAX487/MAX1487 Typical Half-Duplex RS-485 NetworkM A X 481/M A X 483/M A X 485/M A X 487–M A X 491/M A X 1487Low-Power, Slew-Rate-Limited RS-485/RS-422 Transceivers 14______________________________________________________________________________________Figure 22. MAX488–MAX491 Full-Duplex RS-485 NetworkFigure 23. Line Repeater for MAX488–MAX491Isolated RS-485For isolated RS-485 applications, see the MAX253 and MAX1480 data sheets.MAX481/MAX483/MAX485/MAX487–MAX491/MAX1487Low-Power, Slew-Rate-Limited RS-485/RS-422 Transceivers______________________________________________________________________________________15_______________Ordering Information_________________Chip TopographiesMAX481/MAX483/MAX485/MAX487/MAX1487N.C. RO 0.054"(1.372mm)0.080"(2.032mm)DE DIGND B N.C.V CCARE * Contact factory for dice specifications.__Ordering Information (continued)M A X 481/M A X 483/M A X 485/M A X 487–M A X 491/M A X 1487Low-Power, Slew-Rate-Limited RS-485/RS-422 Transceivers 16______________________________________________________________________________________TRANSISTOR COUNT: 248SUBSTRATE CONNECTED TO GNDMAX488/MAX490B RO 0.054"(1.372mm)0.080"(2.032mm)N.C. DIGND Z A V CCYN.C._____________________________________________Chip Topographies (continued)MAX489/MAX491B RO 0.054"(1.372mm)0.080"(2.032mm)DE DIGND Z A V CCYREMAX481/MAX483/MAX485/MAX487–MAX491/MAX1487Low-Power, Slew-Rate-Limited RS-485/RS-422 Transceivers______________________________________________________________________________________17Package Information(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information go to /packages .)S O I C N .E P SM A X 481/M A X 483/M A X 485/M A X 487–M A X 491/M A X 1487Low-Power, Slew-Rate-Limited RS-485/RS-422 Transceivers 18______________________________________________________________________________________Package Information (continued)(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information go to /packages .)MAX481/MAX483/MAX485/MAX487–MAX491Low-Power, Slew-Rate-Limited RS-485/RS-422 TransceiversMaxim 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.Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 ____________________19©2003 Maxim Integrated ProductsPrinted USAis a registered trademark of Maxim Integrated Products.M A X 481/M A X 483/M A X 485/M A X 487–M A X 491/M A X 1487P D I P N .E PSPackage Information (continued)(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information go to /packages .)。

General DescriptionThe MAX3030E–MAX3033E family of quad RS-422transmitters send digital data transmission signals over twisted-pair balanced lines in accordance with TIA/EIA-422-B and ITU-T V.11 standards. All transmitter outputs are protected to ±15kV using the Human Body Model.The MAX3030E–MAX3033E are available with either a 2Mbps or 20Mbps guaranteed baud rate. The 2Mbps baud rate transmitters feature slew-rate-limiting to mini-mize EMI and reduce reflections caused by improperly terminated cables.The 20Mbps baud rate transmitters feature low-static current consumption (I CC < 100µA), making them ideal for battery-powered and power-conscious applications.They have a maximum propagation delay of 16ns and a part-to-part skew less than 5ns, making these devices ideal for driving parallel data. The MAX3030E–MAX3033E feature hot-swap capability that eliminates false transitions on the data cable during power-up or hot insertion.The MAX3030E–MAX3033E are low-power, ESD-pro-tected, pin-compatible upgrades to the industry-stan-dard 26LS31 and SN75174. They are available in space-saving 16-pin TSSOP and SO packages.ApplicationsTelecom Backplanes V.11/X.21 Interface Industrial PLCs Motor ControlFeatureso Meet TIA/EIA-422-B (RS-422) and ITU-T V.11Recommendation o ±15kV ESD Protection on Tx Outputs o Hot-Swap Functionalityo Guaranteed 20Mbps Data Rate (MAX3030E,MAX3032E)o Slew-Rate-Controlled 2Mbps Data Rate (MAX3031E, MAX3033E)o Available in 16-Pin TSSOP and Narrow SO Packages o Low-Power Design (<330µW, V CC = 3.3V Static) o +3.3V Operationo Industry-Standard Pinout o Thermal ShutdownMAX3030E–MAX3033E±15kV ESD-Protected, 3.3V QuadRS-422 Transmitters________________________________________________________________Maxim Integrated Products 1Ordering Information19-2671; Rev 0; 10/02For pricing, delivery, and ordering information,please contact Maxim/Dallas Direct!at 1-888-629-4642, or visit Maxim’s website at .Pin ConfigurationsM A X 3030E –M A X 3033E±15kV ESD-Protected, 3.3V Quad RS-422 Transmitters 2_______________________________________________________________________________________ABSOLUTE MAXIMUM RATINGSDC ELECTRICAL CHARACTERISTICSStresses 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.(All Voltages Are Referenced to Device Ground, Unless Otherwise Noted)V CC ........................................................................................+6V EN1&2, EN3&4, EN, EN ............................................-0.3V to +6V DI_............................................................................-0.3V to +6V DO_+, DO_- (normal condition).................-0.3V to (V CC + 0.3V)DO_+, DO_- (power-off or three-state condition).....-0.3V to +6V Driver Output Current per Pin.........................................±150mAContinuous Power Dissipation (T A = +70°C)16-Pin SO (derate 8.70mW/°C above +70°C)..............696mW 16-Pin TSSOP (derate 9.40mW/°C above +70°C).......755mW Operating Temperature RangesMAX303_EC_......................................................0°C to +70°C MAX303_EE_...................................................-40°C to +85°C Junction Temperature......................................................+150°C Storage Temperature Range.............................-65°C to +160°C Lead Temperature (soldering, 10s).................................+300°CMAX3030E–MAX3033E±15kV ESD-Protected, 3.3V QuadRS-422 TransmittersSWITCHING CHARACTERISTICS—MAX3030E, MAX3032ESWITCHING CHARACTERISTICS —MAX3031E, MAX3033EM A X 3030E –M A X 3033E±15kV ESD-Protected, 3.3V Quad RS-422 Transmitters 4_______________________________________________________________________________________SWITCHING CHARACTERISTICS —MAX3031E, MAX3033E (continued)(3V ≤V CC ≤3.6V, T A = T MIN to T MAX , unless otherwise noted. Typical values are at V CC = +3.3V and T A = +25°C.)Note 1:All currents into the device are positive; all currents out of the device are negative. All voltages are referenced to deviceground, unless otherwise noted.Note 2:∆V OD and ∆V OC are the changes in V OD and V OC , respectively, when DI changes state. Note 3:Only one output shorted at a time.Note 4:This input current is for the hot-swap enable (EN_, EN, EN ) inputs and is present until the first transition only. After the firsttransition, the input reverts to a standard high-impedance CMOS input with input current I LEAK .DIFFERENTIAL OUTPUT VOLTAGEvs. OUTPUT CURRENTOUTPUT CURRENT (mA)D I F FE R E N T I A L O U T P U T V O L T A G E (V )906030123400120OUTPUT CURRENTvs. TRANSMITTER OUTPUT LOW VOLTAGEM A X 3030E t o c 02OUTPUT LOW VOLTAGE (V)O U T P U T C U R R E N T (m A )32150100150200004OUTPUT CURRENTvs. TRANSMITTER OUTPUT HIGH VOLTAGEM A X 3030E t o c 03OUTPUT HIGH VOLTAGE (V)O U T P U T C U R R E N T (m A )321255075100125150004Typical Operating Characteristics(V CC = +3.3V and T A = +25°C, unless otherwise noted.)MAX3030E–MAX3033E±15kV ESD-Protected, 3.3V QuadRS-422 Transmitters_______________________________________________________________________________________5SUPPLY CURRENT vs. SUPPLY VOLTAGESUPPLY VOLTAGE (V)S U P P L Y C U R R E N T (µA )32120406080100004MAX3030E/MAX3032ESUPPLY CURRENT vs. DATA RATEDATA RATE (bps)S U P P L Y C U R R E N T (m A )10M1M100k10k1k5101520253000.1k100MMAX3031E/MAX3033ESUPPLY CURRENT vs. DATA RATEDATA RATE (bps)S U P P L Y C U R R E N T(m A )1M100k10k1k0.51.01.52.02.50.1k10MMAX3030E/MAX3032ESUPPLY CURRENT vs. DATA RATEDATA RATE (bps)S U P P L Y C U R R E N T (m A )10M1M100k10k1k90100110120130800.1k100MMAX3031E/MAX3033ESUPPLY CURRENT vs. DATA RATEDATA RATE (bps)S U P P L Y C U R R E N T (m A )1M100k10k1k919497100880.1k10MMAX3030EDRIVER PROPAGATION DELAY(LOW TO HIGH)MAX3030E toc0910ns/divDIFFERENTIAL OUTPUT 2V/divDI_1V/divMAX3030EDRIVER PROPAGATION DELAY(HIGH TO LOW)MAX3030E toc1010ns/divDIFFERENTIAL OUTPUT 2V/divDI_1V/divMAX3031EDRIVER PROPAGATION DELAY(LOW TO HIGH)MAX3030E toc1120ns/divDIFFERENTIAL OUTPUT 2V/divDI_1V/divMAX3031EDRIVER PROPAGATION DELAY(HIGH TO LOW)MAX3030E toc1220ns/divDIFFERENTIAL OUTPUT 2V/divDI_1V/divTypical Operating Characteristics (continued)(V CC = +3.3V and T A = +25°C, unless otherwise noted.)M A X 3030E –M A X 3033E±15kV ESD-Protected, 3.3V Quad RS-422 TransmittersENABLE RESPONSE TIMEMAX3030E toc1320ns/div ENABLE 1V/divDIFFERENTIAL OUTPUT 2V/divMAX3033E EYE DIAGRAMMAX3030E toc14100ns/divDO_+1V/divDO_-1V/divTypical Operating Characteristics (continued)(V CC = +3.3V and T A = +25°C, unless otherwise noted.)MAX3030E–MAX3033E±15kV ESD-Protected, 3.3V QuadRS-422 Transmitters_______________________________________________________________________________________7Test Circuits and Timing DiagramsTime Test CircuitFigure 4. Driver Enable/Disable Delays Test CircuitFigure 3. Differential Driver Propagation Delay and Transition WaveformM A X 3030E –M A X 3033EDetailed DescriptionThe MAX3030E –MAX3033E are high-speed quad RS-422 transmitters designed for digital data transmission over balanced lines. They are designed to meet the requirements of TIA/EIA-422-B and ITU-T V.11. The MAX3030E –MAX3033E are available in two pinouts to be compatible with both the 26LS31 and SN75174industry-standard devices. Both are offered in 20Mbps and 2Mbps baud rate. All versions feature a low-static current consumption (I CC < 100µA) that makes them ideal for battery-powered and power-conscious appli-cations. The 20Mbps version has a maximum propaga-tion delay of 16ns and a part-to-part skew less than 5ns, allowing these devices to drive parallel data. The 2Mbps version is slew-rate-limited to reduce EMI and reduce reflections caused by improperly terminated cables.Outputs have enhanced ESD protection providing ±15kV tolerance. All parts feature hot-swap capability that eliminates false transitions on the data cable dur-ing power-up or hot insertion.±15kV ESD ProtectionAs with all Maxim devices, ESD-protection structures are incorporated on all pins to protect against electro-static discharges encountered during handling and assembly. The driver outputs and receiver inputs have extra protection against static electricity. Maxim ’s engi-neers developed state-of-the-art structures to protect these pins against ESD of ±15kV without damage. The ESD structures withstand high ESD in all states: normal operation and power-down. After an ESD event, the MAX3030E –MAX3033E keep working without latchup.ESD protection can be tested in various ways; thetransmitter outputs of this product family are character-ized for protection to ±15kV using the Human Body Model. Other ESD test methodologies include IEC10004-2 Contact Discharge and IEC1000-4-2 Air-Gap Discharge (formerly IEC801-2).ESD Test ConditionsESD performance depends on a variety of conditions.Contact Maxim for a reliability report that documents test setup, test methodology, and test results.Human Body ModelFigure 8 shows the Human Body Model, and Figure 9shows the current waveform it generates when dis-charged into low impedance. This model consists of a 100pF capacitor charged to the ESD voltage of interest,which is then discharged into the test device through a 1.5k Ωresistor.±15kV ESD-Protected, 3.3V Quad RS-422 Transmitters 8_______________________________________________________________________________________Figure 7. Power-Off MeasurementsTest Circuits andTiming Diagrams (continued)Machine ModelThe Machine Model for ESD tests all pins using a 200pF storage capacitor and zero discharge resis-tance. Its objective is to emulate the stress caused by contact that occurs with handling and assembly during manufacturing. Of course, all pins require this protec-tion during manufacturing, not just inputs and outputs.Therefore, after PC board assembly, the Machine Model is less relevant to I/O ports.Hot SwapWhen circuit boards are plugged into a “hot ” back-plane, there can be disturbances to the differential sig-nal levels that could be detected by receivers connected to the transmission line. This erroneous data could cause data errors to an RS-422 system. To avoid this, the MAX3030E –MAX3033E have hot-swap capa-ble inputs.When a circuit board is plugged into a “hot ” backplane,there is an interval during which the processor is going through its power-up sequence. During this time, the processor ’s output drivers are high impedance and are unable to drive the enable inputs of the MAX3030E –MAX3033E (EN, EN , EN_) to defined logic levels.Leakage currents from these high-impedance drivers,of as much as 10µA, could cause the enable inputs of the MAX3030E –MAX3033E to drift high or low.Additionally, parasitic capacitance of the circuit board could cause capacitive coupling of the enable inputs to either G ND or V CC . These factors could cause the enable inputs of the MAX3030E –MAX3033E to drift to levels that may enable the transmitter outputs. To avoid this problem, the hot-swap input provides a method of holding the enable inputs of the MAX3030E –MAX3033E in the disabled state as V CC ramps up. This hot-swap input is able to overcome the leakage currents and par-asitic capacitances that can pull the enable inputs to the enabled state.Hot-Swap Input CircuitryIn the MAX3030E –MAX3033E, the enable inputs feature hot-swap capability. At the input there are two NMOS devices, M1 and M2 (Figure 10). When V CC is ramping up from zero, an internal 6µs timer turns on M2 and sets the SR latch, which also turns on M1. Transistors M2, a 2mA current sink, and M1, a 100µA current sink, pull EN to GND through a 5.6k Ωresistor. M2 is designed to pull the EN input to the disabled state against an external parasitic capacitance of up to 100pF that is trying to enable the EN input. After 6µs, the timer turns M2 off and M1 remains on, holding the EN input low against three-state output leakages that might enable EN. M1 remains on until an external source overcomes the required inputcurrent. At this time the SR latch resets and M1 turns off.When M1 turns off, EN reverts to a standard, high-impedance CMOS input. Whenever V CC drops below 1V, the hot-swap input is reset. The EN1&2 and EN3&4input structures are identical to the EN input. For the EN input, there is a complementary circuit employing two PMOS devices pulling the EN input to V CC .Hot-Swap Line TransientThe circuit of Figure 11 shows a typical offset termina-tion used to guarantee a greater than 200mV offset when a line is not driven. The 50pF capacitor repre-MAX3030E–MAX3033E±15kV ESD-Protected, 3.3V QuadRS-422 Transmitters_______________________________________________________________________________________9Figure 10. Simplified Structure of the Driver Enable Pin (EN)Figure 11. Differential Power-Up Glitch (Hot Swap)M A X 3030E –M A X 3033Esents the minimum parasitic capacitance that would exist in a typical application. In most cases, more capacitance exists in the system and reduces the mag-nitude of the glitch. During a “hot-swap ” event when the driver is connected to the line and is powered up, the driver must not cause the differential signal to drop below 200mV (Figures 12 and 13).Operation of Enable PinsThe MAX3030E –MAX3033E family has two enable-func-tional versions.The MAX3030E/MAX3031E are compatible with 26LS31, where the two enable signals control all four transmitters (global enable).The MAX3032E/MAX3033E are compatible with the SN75174. EN1&2 controls transmitters 1 and 2, and EN 3&4 controls transmitters 3 and 4 (dual enable).Typical ApplicationsThe MAX3030E –MAX3033E offer optimum performance when used with the MAX3094E/MAX3096 3.3V quad differential line receivers. Figure 14 shows a typical RS-422 connection for transmitting and receiving data.±15kV ESD-Protected, 3.3V Quad RS-422 Transmitters 10______________________________________________________________________________________4µs/divFigure 12. Differential Power-Up Glitch (0.1V/µs) 1.0µs/divDO_+DO_+ - DO_-DO_-V 1V/divFigure 13. Differential Power-Up Glitch (1V/µs)EN TX1TX4MODE0Active Active All transmitters active 1High-Z High-Z High-Z All transmitters disabled 0Active Active All transmitters active 1ActiveActiveAll transmitters activeTable 1. MAX3030E/MAX3031E Transmitter ControlsTable 2. MAX3032E/MAX3033E Transmitter ControlsMAX3030E–MAX3033E±15kV ESD-Protected, 3.3V QuadRS-422 Transmitters______________________________________________________________________________________11Figure 14. Typical Connection of a Quad Transmitter and Quad Receiver as a PairM A X 3030E –M A X 3033E±15kV ESD-Protected, 3.3V Quad RS-422 Transmitters 12______________________________________________________________________________________Figure 15. MAX3030E/MAX3031E Functional DiagramFigure 16. MAX3032E/MAX3033E Functional DiagramChip InformationTRANSISTOR COUNT: 1050PROCESS: BiCMOSMAX3030E–MAX3033E±15kV ESD-Protected, 3.3V QuadRS-422 Transmitters______________________________________________________________________________________13Package Information(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,go to /packages .)M A X 3030E –M A X 3033E±15kV ESD-Protected, 3.3V Quad RS-422 Transmitters Maxim 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.14____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600©2002 Maxim Integrated ProductsPrinted USAis a registered trademark of Maxim Integrated Products.Package Information (continued)(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,go to /packages .)。

MAX266中文数据手册MAX266/265中文数据手册By Hi_Cracker @whu引脚电阻可编程通用高效滤波器-----MAX266/265General Description和MAX265是高效的容滤波器，专门设计用于需要高精度滤波的应用MAX266场合。

内置了两个独立的滤波模块，可以配置成低通，高通，带通，带阻，全通滤波器。

中心频率或者截止频率的控制需要外接电阻以及6 Pin-Strapped 的输入特性来编程实现，然而，Q值仅用电阻连接实现。

各种各样类型的滤波器都可以实现（巴特沃斯，切比雪夫，椭圆滤波器等等）。

内部集成了两个运算放大器。

MAX265可以将中心/截止频率可以最高调到40Khz，然而，MAX266，通过使用一个低范围的fclk/fo比例系数，可以将fos 调到140Khz。

4MHZ系统时钟，可以通过一个晶振或是额外的源获得。

滤波器的操作电压为从±2.37v到±6.3v或者+5V的单电源供电。

Application：声纳电子设备Anti-Aliasing 滤波器数字信号处理震动音频分析远程通信测试仪器Features滤波器参数设置软件化256bit的频率控制字电阻调整Q值和fo140Khz频率调节范围±5V或者单电源﹢5V操作电压Introduction每个MAX266/265都包含的两个可配置滤波器模块已经显示在数据手册前面的功能框图上。

fclk/fo编程输入（F0-F5）被两个滤波模块共用,然而，每个部分的fo仍然受到各自外接电阻的独立调节。

各个模块的的Q值也是受到各自的外接电阻的独立调节的。

MAX266使用比MAX265更低范围的取样比率（fclk/fo），这样就可以产生更高的信号带宽以及fo的可编程范围。

降低fclk/fo产生的影响主要就是比MAX265的滤波器参数的连续性稍微差了一些，但是这些不同可以通过使用图23所示的图形或是美信得滤波器软件来补偿。

________________General DescriptionThe MAX1668/MAX1805/MAX1989 are precise multi-channel digital thermometers that report the tempera-ture of all remote sensors and their own packages. The remote sensors are diode-connected transistors—typi-cally low-cost, easily mounted 2N3904 NPN types—that replace conventional thermistors or thermocouples.Remote accuracy is ±3°C for multiple transistor manu-facturers, with no calibration needed. The remote chan-nels can also measure the die temperature of other ICs,such as microprocessors, that contain an on-chip,diode-connected transistor.The 2-wire serial interface accepts standard system management bus (SMBus™) write byte, read byte, send byte, and receive byte commands to program the alarm thresholds and to read temperature data. The data for-mat is 7 bits plus sign, with each bit corresponding to 1°C, in two’s-complement format.The MAX1668/MAX1805/MAX1989 are available in small, 16-pin QSOP surface-mount packages. The MAX1989 is also available in a 16-pin TSSOP.________________________Applications____________________________Featureso Multichannel4 Remote, 1 Local (MAX1668/MAX1989)2 Remote, 1 Local (MAX1805)o No Calibration Required o SMBus 2-Wire Serial Interfaceo Programmable Under/Overtemperature Alarms o Supports SMBus Alert Response o Accuracy±2°C (+60°C to +100°C, Local)±3°C (-40°C to +125°C, Local)±3°C (+60°C to +100°C, Remote)o 3µA (typ) Standby Supply Current o 700µA (max) Supply Currento Small, 16-Pin QSOP/TSSOP PackagesMAX1668/MAX1805/MAX1989†Multichannel Remote/LocalTemperature Sensors________________________________________________________________Maxim Integrated Products119-1766; Rev 2; 5/03SMBus is a trademark of Intel Corp.†Patents PendingDesktop and Notebook Computers LAN Servers Industrial ControlsCentral-Office Telecom EquipmentTest and Measurement Multichip ModulesFor pricing, delivery, and ordering information,please contact Maxim/Dallas Direct!at 1-888-629-4642, or visit Maxim’s website at .M A X 1668/M A X 1805/M A X 1989†Multichannel Remote/Local Temperature Sensors 2_______________________________________________________________________________________ABSOLUTE MAXIMUM RATINGSELECTRICAL CHARACTERISTICS(V CC = +3.3V, STBY = V CC , configuration byte = X0XXXX00, T A = 0°C to +125°C , unless otherwise noted.)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 +6V DXP_, ADD_, STBY to GND........................-0.3V to (V CC + 0.3V)DXN_ to GND ........................................................-0.3V to +0.8V SMBCLK, SMBDATA, ALERT to GND......................-0.3V to +6V SMBDATA, ALERT Current.................................-1mA to +50mA DXN_ Current......................................................................±1mA Continuous Power Dissipation (T A = +70°C)QSOP (derate 8.30mW/°C above +70°C)....................667mW TSSOP (derate 9.40mW/°C above +70°C)..................755mWOperating Temperature Range .........................-55°C to +125°C Junction Temperature......................................................+150°C Storage Temperature Range.............................-65°C to +150°C Lead Temperature (soldering, 10s).................................+300°CMAX1668/MAX1805/MAX1989†Multichannel Remote/LocalTemperature Sensors_______________________________________________________________________________________3ELECTRICAL CHARACTERISTICS (continued)(V CC = +3.3V, STBY = V CC , configuration byte = X0XXXX00, T A = 0°C to +125°C , unless otherwise noted.)ELECTRICAL CHARACTERISTICS(V CC = +5V, STBY = V CC , configuration byte = X0XXXX00, T A = -55°C to +125°C , unless otherwise noted.) (Note 6)08416122024FREQUENCY (MHz)T E M P E R A T U R E E R R O R (°C )TEMPERATURE ERROR vs. SUPPLY NOISE FREQUENCY0.111010020-20110100TEMPERATURE ERROR vs. PC BOARD RESISTANCE-10LEAKAGE RESISTANCE (M Ω)T E M P E R A T U R E E R R O R (°C )10-2-101234-50-10-301030507090110TEMPERATURE ERROR vs. TEMPERATURETEMPERATURE (°C)T E M P E R A T U R E E R R O R (°C )Typical Operating Characteristics(Typical Operating Circuit , V CC = +5V, STBY = V CC , configuration byte = X0XXXX00, T A = +25°C, unless otherwise noted.)M A X 1668/M A X 1805/M A X 1989†Multichannel Remote/Local Temperature Sensors 4_______________________________________________________________________________________ELECTRICAL CHARACTERISTICS (continued)(V= +5V, STBY = V , configuration byte = X0XXXX00, T = -55°C to +125°C , unless otherwise noted.) (Note 6)Note 1:Guaranteed by design, but not production tested.Note 2:Quantization error is not included in specifications for temperature accuracy. For example, if the MAX1668/MAX1805/MAX1989 device temperature is exactly +66.7°C, the ADC may report +66°C, +67°C, or +68°C (due to the quantization error plus the +0.5°C offset used for rounding up) and still be within the guaranteed ±1°C error limits for the +60°C to +100°C temperature range. See Table 2.Note 3: A remote diode is any diode-connected transistor from Table 1. T R is the junction temperature of the remote diode. See theRemote-Diode Selection section for remote-diode forward-voltage requirements.Note 4:The SMBus logic block is a static design that works with clock frequencies down to DC. While slow operation is possible, itviolates the 10kHz minimum clock frequency and SMBus specifications, and can monopolize the bus.Note 5:Note that a transition must internally provide at least a hold time in order to bridge the undefined region (300ns max) ofSMBCLK’s falling edge t HD:DAT.Note 6:Specifications from -55°C to +125°C are guaranteed by design, not production tested.020406080100120140160012345STANDBY SUPPLY CURRENT vs. SUPPLY VOLTAGESUPPLY VOLTAGE (V)S U P P L Y C U R R E N T (µA )257550100125-220468RESPONSE TO THERMAL SHOCKTIME (s)T E M P E R A T U R E (°C )MAX1668/MAX1805/MAX1989†Multichannel Remote/LocalTemperature Sensors_______________________________________________________________________________________50.111000TEMPERATURE ERRORvs. COMMON-MODE NOISE FREQUENCYFREQUENCY (MHz)T E M P E R A T U R E E R R O R (°C )1010000.60.40.20.81.01.21.41.61.82.0Typical Operating Characteristics (continued)(Typical Operating Circuit , V CC = +5V, STBY = V CC , configuration byte = X0XXXX00, T A = +25°C, unless otherwise noted.)TEMPERATURE ERRORvs. DXP_ TO DXN_ CAPACITANCEM A X 16681805 t o c 05DXP_ TO DXN_ CAPACITANCE (nF)T E M P E R A T U R E E R R O R (°C )-10-6-8-2-42040203010405060STANDBY SUPPLY CURRENT vs. CLOCK FREQUENCYSMBCLK FREQUENCY (kHz)S U P P L Y C U R R E N T (µA )6010203040501101001000M A X 1668/M A X 1805/M A X 1989†Multichannel Remote/Local Temperature Sensors 6______________________________________________________________________________________________________Detailed DescriptionThe MAX1668/MAX1805/MAX1989 are temperature sensors designed to work in conjunction with an exter-nal microcontroller (µC) or other intelligence in thermo-static, process-control, or monitoring applications. The µC is typically a power-management or keyboard con-troller, generating SMBus serial commands by “bit-banging” general-purpose input-output (GPIO) pins or through a dedicated SMBus interface block.These devices are essentially 8-bit serial analog-to-digi-tal converters (ADCs) with sophisticated front ends.However, the MAX1668/MAX1805/MAX1989 also contain a switched current source, a multiplexer, an ADC, an SMBus interface, and associated control logic (Figure 1).In the MAX1668 and MAX1989, temperature data from the ADC is loaded into five data registers, where it is automatically compared with data previously stored in 10 over/undertemperature alarm registers. In the MAX1805, temperature data from the ADC is loaded into three data registers, where it is automatically compared with data previously stored in six over/undertemperature alarm registers.ADC and MultiplexerThe ADC is an averaging type that integrates over a 64ms period (each channel, typical), with excellent noise rejection.The multiplexer automatically steers bias currents through the remote and local diodes, measures their forward voltages, and computes their temperatures.Each channel is automatically converted once the con-version process has started. If any one of the channels is not used, the device still performs measurements on these channels, and the user can ignore the results of the unused channel. If any remote-diode channel is unused, connect DXP_ to DXN_ rather than leaving the pins open.The DXN_ input is biased at 0.65V above ground by an internal diode to set up the A/D inputs for a differential measurement. The worst-case DXP_ to DXN_ differential input voltage range is 0.25V to 0.95V.Excess resistance in series with the remote diode caus-es about +0.5°C error per ohm. Likewise, 200µV of offset voltage forced on DXP_ to DXN_causes about 1°C error.MAX1668/MAX1805/MAX1989†Multichannel Remote/LocalTemperature Sensors_______________________________________________________________________________________7Figure 1. MAX1668/MAX1805/MAX1989 Functional DiagramA/D Conversion SequenceIf a start command is written (or generated automatically in the free-running autoconvert mode), all channels are converted, and the results of all measurements are available after the end of conversion. A BUSY status bit in the status byte shows that the device is actually per-forming a new conversion; however, even if the ADC is busy, the results of the previous conversion are always available.Remote-Diode SelectionTemperature accuracy depends on having a good-qual-ity, diode-connected small-signal transistor. Accuracy has been experimentally verified for all of the devices listed in Table 1. The MAX1668/MAX1805/MAX1989 can also directly measure the die temperature of CPUs and other ICs having on-board temperature-sensing diodes.The transistor must be a small-signal type, either NPN or PNP, with a relatively high forward voltage; other-wise, the A/D input voltage range can be violated. The forward voltage must be greater than 0.25V at 10µA;check to ensure this is true at the highest expected temperature. The forward voltage must be less than 0.95V at 100µA; check to ensure this is true at the low-est expected temperature. Large power transistors do not work at all. Also, ensure that the base resistance is less than 100Ω. Tight specifications for forward-current gain (+50 to +150, for example) indicate that the manu-facturer has good process controls and that the devices have consistent VBE characteristics.F or heat-sink mounting, the 500-32BT02-000 thermal sensor from Fenwal Electronics is a good choice. This device consists of a diode-connected transistor, an aluminum plate with screw hole, and twisted-pair cable (Fenwal Inc., Milford, MA, 508-478-6000).Thermal Mass and Self-HeatingThermal mass can seriously degrade the MAX1668/MAX1805/MAX1989s’ effective accuracy. The thermal time constant of the 16-pin QSOP package is about 140s in still air. F or the MAX1668/MAX1805/MAX1989junction temperature to settle to within +1°C after a sudden +100°C change requires about five time con-stants or 12 minutes. The use of smaller packages for remote sensors, such as SOT23s, improves the situa-tion. Take care to account for thermal gradients between the heat source and the sensor, and ensure that stray air currents across the sensor package do not interfere with measurement accuracy.Self-heating does not significantly affect measurement accuracy. Remote-sensor self-heating due to the diode current source is negligible. F or the local diode, theworst-case error occurs when sinking maximum current at the ALERT output. For example, with ALERT sinking 1mA, the typical power dissipation is V CC x 400µA plus 0.4V x 1mA. Package theta J-A is about 150°C/W, so with V CC = 5V and no copper PC board heat sinking,the resulting temperature rise is:dT = 2.4mW x 150°C/W = 0.36°CEven with these contrived circumstances, it is difficult to introduce significant self-heating errors.ADC Noise FilteringThe ADC is an integrating type with inherently good noise rejection, especially of low-frequency signals such as 60Hz/120Hz power-supply hum. Micropower opera-tion places constraints on high-frequency noise rejec-tion; therefore, careful PC board layout and proper external noise filtering are required for high-accuracy remote measurements in electrically noisy environments. High-frequency EMI is best filtered at DXP_ and DXN_with an external 2200pF capacitor. This value can be increased to about 3300pF (max), including cable capacitance. Higher capacitance than 3300pF intro-duces errors due to the rise time of the switched cur-rent source.Nearly all noise sources tested cause additional error measurements, typically by +1°C to +10°C, depending on the frequency and amplitude (see the Typical Operating Characteristics ).PC Board Layout1)Place the MAX1668/MAX1805/MAX1989 as close aspractical to the remote diode. In a noisy environment,such as a computer motherboard, this distance canM A X 1668/M A X 1805/M A X 1989†Multichannel Remote/Local Temperature Sensors 8_______________________________________________________________________________________Table 1. Remote-Sensor Transistor ManufacturersNote:Transistors must be diode connected (base shorted to collector).be 4in to 8in (typ) or more as long as the worst noise sources (such as CRTs, clock generators, memory buses, and ISA/PCI buses) are avoided.2)Do not route the DXP_ to DXN_ lines next to thedeflection coils of a CRT. Also, do not route the traces across a fast memory bus, which can easily introduce +30°C error, even with good filtering.Otherwise, most noise sources are fairly benign.3)Route the DXP_ and DXN_ traces in parallel and inclose proximity to each other, away from any high-voltage traces such as +12VDC. Leakage currents from PC board contamination must be dealt with carefully, since a 20M Ωleakage path from DXP_ to ground causes about +1°C error.4)Connect guard traces to GND on either side of theDXP_ to DXN_ traces (Figure 2). With guard traces in place, routing near high-voltage traces is no longer an issue. 5)Route through as few vias and crossunders as possi-ble to minimize copper/solder thermocouple effects. 6)When introducing a thermocouple, make sure thatboth the DXP_ and the DXN_ paths have matching thermocouples. In general, PC board-induced ther-mocouples are not a serious problem. A copper-sol-der thermocouple exhibits 3µV/°C, and it takes about 200µV of voltage error at DXP_ to DXN_ to cause a +1°C measurement error. So, most para-sitic thermocouple errors are swamped out.7)Use wide traces. Narrow ones are more inductiveand tend to pick up radiated noise. The 10mil widths and spacings recommended in Figure 2 are not absolutely necessary (as they offer only a minor improvement in leakage and noise), but try to use them where practical.8)Copper cannot be used as an EMI shield, and onlyferrous materials such as steel work well. Placing a copper ground plane between the DXP_ to DXN_traces and traces carrying high-frequency noise sig-nals does not help reduce EMI.PC Board Layout Checklist•Place the MAX1668/MAX1805/MAX1989as close as possible to the remote diodes.•Keep traces away from high voltages (+12V bus).•Keep traces away from fast data buses and CRTs.•Use recommended trace widths and spacings.•Place a ground plane under the traces.•Use guard traces flanking DXP_ and DXN_ and con-necting to GND.•Place the noise filter and the 0.1µF V CC bypass capacitors close to the MAX1668/MAX1805/MAX1989.•Add a 200Ωresistor in series with V CC for best noise filtering (see the Typical Operating Circuit ).Twisted-Pair and Shielded CablesFor remote-sensor distances longer than 8in, or in partic-ularly noisy environments, a twisted pair is recommend-ed. Its practical length is 6ft to 12ft (typ) before noise becomes a problem, as tested in a noisy electronics lab-oratory. F or longer distances, the best solution is a shielded twisted pair like that used for audio micro-phones. For example, Belden #8451 works well for dis-tances up to 100ft in a noisy environment. Connect the twisted pair to DXP_ and DXN_ and the shield to GND,and leave the shield’s remote end unterminated.Excess capacitance at DX_ _ limits practical remote-sen-sor distances (see the Typical Operating Characteristics ).F or very long cable runs, the cable’s parasitic capaci-tance often provides noise filtering, so the 2200pF capac-itor can often be removed or reduced in value.Cable resistance also affects remote-sensor accuracy;1Ωseries resistance introduces about +0.5°C error.Low-Power Standby ModeStandby mode disables the ADC and reduces the sup-ply-current drain to less than 12µA. Enter standby mode by forcing the STBY pin low or through the RUN/STOP bit in the configuration byte register.Hardware and software standby modes behave almost identically: all data is retained in memory, and the SMB interface is alive and listening for reads and writes.Activate hardware standby mode by forcing the STBY pin low. In a notebook computer, this line can be con-nected to the system SUSTAT# suspend-state signal. The STBY pin low state overrides any software conversion command. If a hardware or software standby command is received while a conversion is in progress, the conver-MAX1668/MAX1805/MAX1989†Multichannel Remote/LocalTemperature Sensors_______________________________________________________________________________________9Figure 2. Recommended DXP_/DXN_ PC Tracession cycle is truncated, and the data from that conversion is not latched into either temperature-reading register. The previous data is not changed and remains available.In standby mode, supply current drops to about 3µA.At very low supply voltages (under the power-on-reset threshold), the supply current is higher due to the address pin bias currents. It can be as high as 100µA,depending on ADD0 and ADD1 settings.SMBus Digital InterfaceF rom a software perspective, the MAX1668/MAX1805/MAX1989appear as a set of byte-wide registers that contain temperature data, alarm threshold values, or control bits. A standard SMBus 2-wire serial interface is used to read temperature data and write control bits and alarm threshold data. Each A/D channel within the devices responds to the same SMBus slave address for normal reads and writes.The MAX1668/MAX1805/MAX1989employ four standard SMBus protocols: write byte, read byte, send byte, and receive byte (Figure 3). The shorter receive byte protocol allows quicker transfers, provided that the correct data register was previously selected by a read byte instruc-tion. Use caution with the shorter protocols in multimaster systems, since a second master could overwrite the com-mand byte without informing the first master.The temperature data format is 7 bits plus sign in two’s-com-plement form for each channel, with each data bit represent-ing 1°C (Table 2), transmitted MSB first. Measurements are offset by +0.5°C to minimize internal rounding errors; for example, +99.6°C is reported as +100°C.Alarm Threshold RegistersTen (six for MAX1805) registers store alarm threshold data, with high-temperature (T HIGH ) and low-tempera-ture (T LOW ) registers for each A/D channel. If either measured temperature equals or exceeds the corre-sponding alarm threshold value, an ALERT interrupt is asserted.The power-on-reset (POR) state of all T HIGH registers of the MAX1668 and MAX1805 is full scale (0111 1111, or +127°C). The POR state of the channel 1 T HIGH register of the MAX1989 is 0110 1110 or +110°C, while all other channels are at +127°C. The POR state of all T LOW reg-isters is 1100 1001 or -55°C.M A X 1668/M A X 1805/M A X 1989†Multichannel Remote/Local Temperature Sensors 10______________________________________________________________________________________Figure 3. SMBus ProtocolsThere is a continuity fault detector at DXP_ that detects whether the remote diode has an open-circuit condi-tion. At the beginning of each conversion, the diode fault is checked, and the status byte is updated. This fault detector is a simple voltage detector; if DXP_ rises above V CC - 1V (typ) due to the diode current source, a fault is detected. Note that the diode fault is not checked until a conversion is initiated, so immediately after power-on reset, the status byte indicates no fault is present, even if the diode path is broken.If any remote channel is shorted (DXP_ to DXN_ or DXP_ to GND), the ADC reads 0000 0000 so as not to trip either the T HIGH or T LOW alarms at their POR set-tings. In applications that are never subjected to 0°C in normal operation, a 0000 0000 result can be checked to indicate a fault condition in which DXP_ is acciden-tally short circuited. Similarly, if DXP_ is short circuited to V CC , the ADC reads +127°C for all remote and local channels, and the device alarms.A L E R T InterruptsThe ALERT interrupt output signal is latched and can only be cleared by reading the alert response address.Interrupts are generated in response to T HIGH and T LOW comparisons and when a remote diode is disconnected (for continuity fault detection). The interrupt does not halt automatic conversions; new temperature data continues to be available over the SMBus interface after ALERT is asserted. The interrupt output pin is open drain so that devices can share a common interrupt line. The interrupt rate can never exceed the conversion rate.The interface responds to the SMBus alert response address, an interrupt pointer return-address feature (see Alert R esponse Address section). Prior to taking corrective action, always check to ensure that an inter-rupt is valid by reading the current temperature.Alert Response AddressThe SMBus alert response interrupt pointer provides quick fault identification for simple slave devices that lack the complex, expensive logic needed to be a bus master. Upon receiving an ALERT interrupt signal, the host master can broadcast a receive byte transmission to the alert response slave address (0001 100). Then any slave device that generated an interrupt attempts to identify itself by putting its own address on the bus (Table 3).The alert response can activate several different slave devices simultaneously, similar to the I 2C general call. If more than one slave attempts to respond, bus arbitra-tion rules apply, and the device with the lower address code wins. The losing device does not generate an acknowledge and continues to hold the ALERT line low until serviced (implies that the host interrupt input isMAX1668/MAX1805/MAX1989†Multichannel Remote/LocalTemperature Sensors______________________________________________________________________________________11Table 3. Read Format for Alert Response Address (0001100)ADD66Provide the currentMAX1668/MAX1805/MAX1989slave address that was latched at POR (Table 8)FUNCTIONADD55ADD44ADD33ADD22ADD11ADD77(MSB)10(LSB)Logic 1BIT NAMElevel sensitive). Successful reading of the alert response address clears the interrupt latch.Command Byte FunctionsThe 8-bit command byte register (Table 4) is the master index that points to the various other registers within the MAX1668/MAX1805/MAX1989. The register ’s PORstate is 0000 0000, so that a receive byte transmission (a protocol that lacks the command byte) that occurs immediately after POR returns the current local temper-ature data.M A X 1668/M A X 1805/M A X 1989†Multichannel Remote/Local Temperature Sensors 12______________________________________________________________________________________**Not available for MAX1805.MAX1668/MAX1805/MAX1989†Multichannel Remote/LocalTemperature Sensors______________________________________________________________________________________13Manufacturer and DeviceID CodesTwo ROM registers provide manufacturer and device ID codes. Reading the manufacturer ID returns 4Dh,which is the ASCII code M (for Maxim). Reading the device ID returns 03h for MAX1668, 05h for MAX1805,and 0Bh for MAX1989. If the read word 16-bit SMBus protocol is employed (rather than the 8-bit Read Byte),the least significant byte contains the data and the most significant byte contains 00h in both cases.Configuration Byte FunctionsThe configuration byte register (Table 5) is used to mask (disable) interrupts and to put the device in soft-ware standby mode.Status Byte FunctionsThe two status byte registers (Tables 6 and 7) indicate which (if any) temperature thresholds have been exceeded. The first byte also indicates whether the ADC is converting and whether there is an open circuit in a remote-diode DXP_ to DXN_ path. After POR, the normal state of all the flag bits is zero, assuming none of the alarm conditions are present. The status byte is cleared by any successful read of the status byte,unless the fault persists. Note that the ALERT interrupt latch is not automatically cleared when the status flag bit is cleared.When reading the status byte, you must check for inter-nal bus collisions caused by asynchronous ADC timing,or else disable the ADC prior to reading the status byte (through the RUN/STOP bit in the configuration byte).To check for internal bus collisions, read the status byte. If the least significant 7 bits are ones, discard the data and read the status byte again. The status bits LHIGH, LLOW, RHIGH, and RLOW are refreshed on the SMBus clock edge immediately following the stop con-dition, so there is no danger of losing temperature-relat-ed status data as a result of an internal bus collision.The OPEN status bit (diode continuity fault) is only refreshed at the beginning of a conversion, so OPEN data is lost. The ALERT interrupt latch is independent of the status byte register, so no false alerts are generated by an internal bus collision.If the THIGH and TLOW limits are close together, it ’s possible for both high-temp and low-temp status bits to be set, depending on the amount of time between sta-tus read operations (especially when converting at the fastest rate). In these circumstances, it ’s best not to relyon the status bits to indicate reversals in long-term tem-perature changes and instead use a current tempera-ture reading to establish the trend direction.Conversion RateThe MAX1668/MAX1805/MAX1989 are continuously measuring temperature on each channel. The typical conversion rate is approximately three conversions/s (for both devices). The resulting data is stored in the temperature data registers.Slave AddressesThe MAX1668/MAX1805/MAX1989 appear to the SMBus as one device having a common address for all ADC channels. The device address can be set to one of nine different values by pin-strapping ADD0 and ADD1 so that more than one MAX1668/MAX1805/MAX1989 can reside on the same bus without address conflicts (Table 8).The address pin states are checked at POR only, and the address data stays latched to reduce quiescent supply current due to the bias current needed for high-Z state detection.The MAX1668/MAX1805/MAX1989 also respond to the SMBus alert response slave address (see the Alert Response Address section).POR and Undervoltage LockoutThe MAX1668/MAX1805/MAX1989 have a volatile memory. To prevent ambiguous power-supply condi-tions from corrupting the data in memory and causing erratic behavior, a POR voltage detector monitors V CC and clears the memory if V CC falls below 1.8V (typ, see the Electrical Characteristics table). When power is first applied and V CC rises above 1.85V (typ), the logic blocks begin operating, although reads and writes at V CC levels below 3V are not recommended. A second V CC comparator, the ADC UVLO comparator, prevents the ADC from converting until there is sufficient head-room (V CC = 2.8V typ).Power-Up Defaults•Interrupt latch is cleared.•Address select pins are sampled.•ADC begins converting.•Command byte is set to 00h to facilitate quick remote receive byte queries.•T HIGH and T LOW registers are set to max and min limits, respectively.。