50SEV330M125X135中文资料

General DescriptionThe MAX13080E–MAX13089E +5.0V, ±15kV ESD-protect-ed, RS-485/RS-422 transceivers feature one driver and one receiver. These devices include fail-safe circuitry,guaranteeing a logic-high receiver output when receiver inputs are open or shorted. The receiver outputs a logic-high if all transmitters on a terminated bus are disabled (high impedance). The MAX13080E–MAX13089E include a hot-swap capability to eliminate false transitions on the bus during power-up or hot insertion.The MAX13080E/MAX13081E/MAX13082E feature reduced slew-rate drivers that minimize EMI and reduce reflections caused by improperly terminated cables, allowing error-free data transmission up to 250kbps. The MAX13083E/MAX13084E/MAX13085E also feature slew-rate-limited drivers but allow transmit speeds up to 500kbps. The MAX13086E/MAX13087E/MAX13088E driver slew rates are not limited, making transmit speeds up to 16Mbps possible. The MAX13089E slew rate is pin selectable for 250kbps,500kbps, and 16Mbps.The MAX13082E/MAX13085E/MAX13088E are intended for half-duplex communications, and the MAX13080E/MAX13081E/MAX13083E/MAX13084E/MAX13086E/MAX13087E are intended for full-duplex communica-tions. The MAX13089E is selectable for half-duplex or full-duplex operation. It also features independently programmable receiver and transmitter output phase through separate pins.The MAX13080E–MAX13089E transceivers draw 1.2mA of supply current when unloaded or when fully loaded with the drivers disabled. All devices have a 1/8-unit load receiver input impedance, allowing up to 256transceivers on the bus.The MAX13080E/MAX13083E/MAX13086E/MAX13089E are available in 14-pin PDIP and 14-pin SO packages.The MAX13081E/MAX13082E/MAX13084E/MAX13085E/MAX13087E/MAX13088E are available in 8-pin PDIP and 8-pin SO packages. The devices operate over the com-mercial, extended, and automotive temperature ranges.ApplicationsUtility Meters Lighting Systems Industrial Control Telecom Security Systems Instrumentation ProfibusFeatures♦+5.0V Operation♦Extended ESD Protection for RS-485/RS-422 I/O Pins±15kV Human Body Model ♦True Fail-Safe Receiver While Maintaining EIA/TIA-485 Compatibility ♦Hot-Swap Input Structures on DE and RE ♦Enhanced Slew-Rate Limiting Facilitates Error-Free Data Transmission(MAX13080E–MAX13085E/MAX13089E)♦Low-Current Shutdown Mode (Except MAX13081E/MAX13084E/MAX13087E)♦Pin-Selectable Full-/Half-Duplex Operation (MAX13089E)♦Phase Controls to Correct for Twisted-Pair Reversal (MAX13089E)♦Allow Up to 256 Transceivers on the Bus ♦Available in Industry-Standard 8-Pin SO PackageMAX13080E–MAX13089E+5.0V , ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 Transceivers________________________________________________________________Maxim Integrated Products 1Ordering Information19-3590; Rev 1; 4/05For pricing, delivery, and ordering information,please contact Maxim/Dallas Direct!at 1-888-629-4642, or visit Maxim’s website at .Selector Guide, Pin Configurations, and Typical Operating Circuits appear at end of data sheet.Ordering Information continued at end of data sheet.M A X 13080E –M A X 13089E+5.0V , ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 Transceivers 2_______________________________________________________________________________________ABSOLUTE MAXIMUM RATINGSDC ELECTRICAL CHARACTERISTICS(V CC = +5.0V ±10%, T A = T MIN to T MAX , unless otherwise noted. Typical values are at V CC = +5.0V and T A = +25°C.) (Note 1)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.(All Voltages Referenced to GND)Supply Voltage (V CC ).............................................................+6V Control Input Voltage (RE , DE, SLR,H/F , TXP, RXP)......................................................-0.3V to +6V Driver Input Voltage (DI)...........................................-0.3V to +6V Driver Output Voltage (Z, Y, A, B).............................-8V to +13V Receiver Input Voltage (A, B)....................................-8V to +13V Receiver Input VoltageFull Duplex (A, B)..................................................-8V to +13V Receiver Output Voltage (RO)....................-0.3V to (V CC + 0.3V)Driver Output Current.....................................................±250mAContinuous Power Dissipation (T A = +70°C)8-Pin SO (derate 5.88mW/°C above +70°C).................471mW 8-Pin Plastic DIP (derate 9.09mW/°C above +70°C).....727mW 14-Pin SO (derate 8.33mW/°C above +70°C)...............667mW 14-Pin Plastic DIP (derate 10.0mW/°C above +70°C)...800mW Operating Temperature RangesMAX1308_EC_ _.................................................0°C to +75°C MAX1308_EE_ _..............................................-40°C to +85°C MAX1308_EA_ _............................................-40°C to +125°C Junction Temperature......................................................+150°C Storage Temperature Range.............................-65°C to +150°C Lead Temperature (soldering, 10s).................................+300°CMAX13080E–MAX13089E+5.0V , ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 Transceivers_______________________________________________________________________________________3DC ELECTRICAL CHARACTERISTICS (continued)(V CC = +5.0V ±10%, T A = T MIN to T MAX , unless otherwise noted. Typical values are at V CC = +5.0V and T A = +25°C.) (Note 1)M A X 13080E –M A X 13089E+5.0V , ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 Transceivers 4_______________________________________________________________________________________DRIVER SWITCHING CHARACTERISTICSMAX13080E/MAX13081E/MAX13082E/MAX13089E WITH SRL = UNCONNECTED (250kbps)(V CC = +5.0V ±10%, T A = T MIN to T MAX , unless otherwise noted. Typical values are at V CC = +5.0V and T A = +25°C.)RECEIVER SWITCHING CHARACTERISTICSMAX13080E/MAX13081E/MAX13082E/MAX13089E WITH SRL = UNCONNECTED (250kbps)(V CC = +5.0V ±10%, T A = T MIN to T MAX , unless otherwise noted. Typical values are at V CC = +5.0V and T A = +25°C.)MAX13080E–MAX13089E+5.0V , ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 Transceivers_______________________________________________________________________________________5DRIVER SWITCHING CHARACTERISTICSMAX13083E/MAX13084E/MAX13085E/MAX13089E WITH SRL = V CC (500kbps)(V CC = +5.0V ±10%, T A = T MIN to T MAX , unless otherwise noted. Typical values are at V CC = +5.0V and T A = +25°C.)RECEIVER SWITCHING CHARACTERISTICSMAX13083E/MAX13084E/MAX13085E/MAX13089E WITH SRL = V CC (500kbps)(V CC = +5.0V ±10%, T A = T MIN to T MAX , unless otherwise noted. Typical values are at V CC = +5.0V and T A = +25°C.)M A X 13080E –M A X 13089E+5.0V , ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 Transceivers 6_______________________________________________________________________________________DRIVER SWITCHING CHARACTERISTICSMAX13086E/MAX13087E/MAX13088E/MAX13089E WITH SRL = GND (16Mbps)(V CC = +5.0V ±10%, T A = T MIN to T MAX , unless otherwise noted. Typical values are at V CC = +5.0V and T A = +25°C.)RECEIVER SWITCHING CHARACTERISTICSMAX13086E/MAX13087E/MAX13088E/MAX13089E WITH SRL = GND (16Mbps)(V CC = +5.0V ±10%, T A = T MIN to T MAX , unless otherwise noted. Typical values are at V CC = +5.0V and T A = +25°C.)Note 2:∆V OD and ∆V OC are the changes in V OD and V OC , respectively, when the DI input changes state.Note 3:The short-circuit output current applies to peak current just prior to foldback current limiting. The short-circuit foldback outputcurrent applies during current limiting to allow a recovery from bus contention.MAX13080E–MAX13089E+5.0V , ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 Transceivers_______________________________________________________________________________________70.800.901.501.101.001.201.301.401.60-40-10520-253550958011065125SUPPLY CURRENT vs. TEMPERATURETEMPERATURE (°C)S U P P L Y C U R R E N T (m A )0201040305060021345OUTPUT CURRENTvs. RECEIVER OUTPUT-HIGH VOLTAGEM A X 13080E -89E t o c 02OUTPUT HIGH VOLTAGE (V)O U T P U T C U R R E N T (m A )20104030605070021345OUTPUT CURRENTvs. RECEIVER OUTPUT-LOW VOLTAGEM A X 13080E -89E t o c 03OUTPUT LOW VOLTAGE (V)O U T P U T C U R R E N T (m A )4.04.44.24.84.65.25.05.4RECEIVER OUTPUT-HIGH VOLTAGEvs. TEMPERATURETEMPERATURE (°C)O U T P U T H I G H V O L T A G E (V )-40-10520-2535509580110651250.10.70.30.20.40.50.60.8RECEIVER OUTPUT-LOW VOLTAGEvs. TEMPERATURETEMPERATURE (°C)O U T P U T L O W V O L T A G E (V )-40-10520-25355095801106512502040608010012014016012345DRIVER DIFFERENTIAL OUTPUT CURRENT vs. DIFFERENTIAL OUTPUT VOLTAGEDIFFERENTIAL OUTPUT VOLTAGE (V)D I F FE R E N T I A L O U T P U T C U R R E N T (m A )2.02.82.43.63.24.44.04.8DRIVER DIFFERENTIAL OUTPUT VOLTAGE vs. TEMPERATURED I F FE R E N T I A L O U T P U T V O L T A G E (V )-40-10520-253550958011065125TEMPERATURE (°C)40201008060120140180160200-7-5-4-6-3-2-1012354OUTPUT CURRENT vs. TRANSMITTEROUTPUT-HIGH VOLTAGEOUTPUT HIGH VOLTAGE (V)O U T P U T C U R R E N T (m A )60402080100120140160180200042681012OUTPUT CURRENT vs. TRANSMITTEROUTPUT-LOW VOLTAGEOUTPUT-LOW VOLTAGE (V)O U T P U T C U R R E N T (m A )Typical Operating Characteristics(V CC = +5.0V, T A = +25°C, unless otherwise noted.)M A X 13080E –M A X 13089E+5.0V , ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 Transceivers 8_______________________________________________________________________________________21543679810SHUTDOWN CURRENT vs. TEMPERATUREM A X 13080E -89E t o c 10S H U T D O W N C U R R E N T (µA )-40-10520-253550958011065125TEMPERATURE (°C)600800700100090011001200DRIVER PROPAGATION DELAY vs. TEMPERATURE (250kbps)D R I VE R P R O P A G A T I O N D E L A Y (n s )-40-10520-253550958011065125TEMPERATURE (°C)300400350500450550600DRIVER PROPAGATION DELAY vs. TEMPERATURE (500kbps)D R I VE R P R O P A G A T I O N D E L A Y (n s )-40-10520-253550958011065125TEMPERATURE (°C)1070302040506080DRIVER PROPAGATION DELAY vs. TEMPERATURE (16Mbps)D R I VE R P R O P A G A T I O N D E L A Y (n s )-40-10520-253550958011065125TEMPERATURE (°C)40201008060120140160180RECEIVER PROPAGATION DELAYvs. TEMPERATURE (250kpbs AND 500kbps)R E C E I V E R P R O P A G A T I O N D E L A Y (n s )-40-10520-253550958011065125TEMPERATURE (°C)40201008060120140160180RECEIVER PROPAGATION DELAYvs. TEMPERATURE (16Mbps)R EC E I V E R P R O P A G AT I O N D E L A Y (n s )-40-10520-253550958011065125TEMPERATURE (°C)2µs/div DRIVER PROPAGATION DELAY (250kbps)DI 2V/divV Y - V Z 5V/divR L = 100Ω200ns/divRECEIVER PROPAGATION DELAY(250kbps AND 500kbps)V A - V B 5V/divRO 2V/divTypical Operating Characteristics (continued)(V CC = +5.0V, T A = +25°C, unless otherwise noted.)MAX13080E–MAX13089E+5.0V , ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 Transceivers_______________________________________________________________________________________9Test Circuits and Waveforms400ns/divDRIVER PROPAGATION DELAY (500kbps)DI 2V/divR L = 100ΩV Y - V Z 5V/div10ns/div DRIVER PROPAGATION DELAY (16Mbps)DI 2V/divR L = 100ΩV Y 2V/divV Z 2V/div40ns/divRECEIVER PROPAGATION DELAY (16Mbps)V B 2V/divR L = 100ΩRO 2V/divV A 2V/divTypical Operating Characteristics (continued)(V CC = +5.0V, T A = +25°C, unless otherwise noted.)Figure 2. Driver Timing Test CircuitM A X 13080E –M A X 13089E+5.0V , ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 Transceivers 10______________________________________________________________________________________Test Circuits and Waveforms (continued)Figure 4. Driver Enable and Disable Times (t DHZ , t DZH , t DZH(SHDN))DZL DLZ DLZ(SHDN)MAX13080E–MAX13089E+5.0V , ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 TransceiversTest Circuits and Waveforms (continued)Figure 6. Receiver Propagation Delay Test CircuitM A X 13080E –M A X 13089E+5.0V , ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 TransceiversMAX13080E–MAX13089E+5.0V , ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 TransceiversMAX13080E/MAX13083E/MAX13086EMAX13081E/MAX13084E/MAX13086E/MAX13087EFunction TablesM A X 13080E –M A X 13089E+5.0V , ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 Transceivers MAX13082E/MAX13085E/MAX13088EFunction Tables (continued)MAX13089EDetailed Description The MAX13080E–MAX13089E high-speed transceivers for RS-485/RS-422 communication contain one driver and one receiver. These devices feature fail-safe circuit-ry, which guarantees a logic-high receiver output when the receiver inputs are open or shorted, or when they are connected to a terminated transmission line with all dri-vers disabled (see the Fail-Safe section). The MAX13080E/MAX13082E/MAX13083E/MAX13085E/ MAX13086E/MAX13088E/MAX13089E also feature a hot-swap capability allowing line insertion without erroneous data transfer (see the Hot Swap Capability section). The MAX13080E/MAX13081E/MAX13082E feature reduced slew-rate drivers that minimize EMI and reduce reflec-tions caused by improperly terminated cables, allowing error-free data transmission up to 250kbps. The MAX13083E/MAX13084E/MAX13085E also offer slew-rate limits allowing transmit speeds up to 500kbps. The MAX13086E/MAX13087E/MAX13088Es’ driver slew rates are not limited, making transmit speeds up to 16Mbps possible. The MAX13089E’s slew rate is selectable between 250kbps, 500kbps, and 16Mbps by driving a selector pin with a three-state driver.The MAX13082E/MAX13085E/MAX13088E are half-duplex transceivers, while the MAX13080E/MAX13081E/ MAX13083E/MAX13084E/MAX13086E/MAX13087E are full-duplex transceivers. The MAX13089E is selectable between half- and full-duplex communication by driving a selector pin (H/F) high or low, respectively.All devices operate from a single +5.0V supply. Drivers are output short-circuit current limited. Thermal-shutdown circuitry protects drivers against excessive power dissi-pation. When activated, the thermal-shutdown circuitry places the driver outputs into a high-impedance state.Receiver Input Filtering The receivers of the MAX13080E–MAX13085E, and the MAX13089E when operating in 250kbps or 500kbps mode, incorporate input filtering in addition to input hysteresis. This filtering enhances noise immunity with differential signals that have very slow rise and fall times. Receiver propagation delay increases by 25% due to this filtering.Fail-Safe The MAX13080E family guarantees a logic-high receiver output when the receiver inputs are shorted or open, or when they are connected to a terminated transmission line with all drivers disabled. This is done by setting the receiver input threshold between -50mV and -200mV. If the differential receiver input voltage (A - B) is greater than or equal to -50mV, RO is logic-high. If (A - B) is less than or equal to -200mV, RO is logic-low. In the case of a terminated bus with all transmitters disabled, the receiv-er’s differential input voltage is pulled to 0V by the termi-nation. With the receiver thresholds of the MAX13080E family, this results in a logic-high with a 50mV minimumnoise margin. Unlike previous fail-safe devices, the-50mV to -200mV threshold complies with the ±200mVEIA/TIA-485 standard.Hot-Swap Capability (Except MAX13081E/MAX13084E/MAX13087E)Hot-Swap InputsWhen circuit boards are inserted into a hot or powered backplane, differential disturbances to the data buscan lead to data errors. Upon initial circuit board inser-tion, the data communication processor undergoes itsown power-up sequence. During this period, the processor’s logic-output drivers are high impedanceand are unable to drive the DE and RE inputs of these devices to a defined logic level. Leakage currents up to±10µA from the high-impedance state of the proces-sor’s logic drivers could cause standard CMOS enableinputs of a transceiver to drift to an incorrect logic level. Additionally, parasitic circuit board capacitance couldcause coupling of V CC or GND to the enable inputs. Without the hot-swap capability, these factors could improperly enable the transceiver’s driver or receiver.When V CC rises, an internal pulldown circuit holds DElow and RE high. After the initial power-up sequence,the pulldown circuit becomes transparent, resetting thehot-swap tolerable input.Hot-Swap Input CircuitryThe enable inputs feature hot-swap capability. At theinput there are two NMOS devices, M1 and M2 (Figure 9). When V CC ramps from zero, an internal 7µstimer turns on M2 and sets the SR latch, which alsoturns on M1. Transistors M2, a 1.5mA current sink, andM1, a 500µA current sink, pull DE to GND through a5kΩresistor. M2 is designed to pull DE to the disabledstate against an external parasitic capacitance up to100pF that can drive DE high. After 7µs, the timer deactivates M2 while M1 remains on, holding DE low against three-state leakages that can drive DE high. M1 remains on until an external source overcomes the required input current. At this time, the SR latch resetsand M1 turns off. When M1 turns off, DE reverts to a standard, high-impedance CMOS input. Whenever V CCdrops below 1V, the hot-swap input is reset.For RE there is a complementary circuit employing two PMOS devices pulling RE to V CC. MAX13080E–MAX13089E+5.0V, ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 TransceiversM A X 13080E –M A X 13089EMAX13089E ProgrammingThe MAX13089E has several programmable operating modes. Transmitter rise and fall times are programma-ble, resulting in maximum data rates of 250kbps,500kbps, and 16Mbps. To select the desired data rate,drive SRL to one of three possible states by using a three-state driver: V CC , GND, or unconnected. F or 250kbps operation, set the three-state device in high-impedance mode or leave SRL unconnected. F or 500kbps operation, drive SRL high or connect it to V CC .F or 16Mbps operation, drive SRL low or connect it to GND. SRL can be changed during operation without interrupting data communications.Occasionally, twisted-pair lines are connected backward from normal orientation. The MAX13089E has two pins that invert the phase of the driver and the receiver to cor-rect this problem. F or normal operation, drive TXP and RXP low, connect them to ground, or leave them uncon-nected (internal pulldown). To invert the driver phase,drive TXP high or connect it to V CC . To invert the receiver phase, drive RXP high or connect it to V CC . Note that the receiver threshold is positive when RXP is high.The MAX13089E can operate in full- or half-duplex mode. Drive H/F low, leave it unconnected (internal pulldown), or connect it to GND for full-duplex opera-tion. Drive H/F high for half-duplex operation. In full-duplex mode, the pin configuration of the driver and receiver is the same as that of a MAX13080E. In half-duplex mode, the receiver inputs are internally connect-ed to the driver outputs through a resistor-divider. This effectively changes the function of the device’s outputs.Y becomes the noninverting driver output and receiver input, Z becomes the inverting driver output and receiver input. In half-duplex mode, A and B are still connected to ground through an internal resistor-divider but they are not internally connected to the receiver.±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 of the MAX13080E family of devices have extra protection against static electricity. Maxim’s engineers have devel-oped state-of-the-art structures to protect these pins against ESD of ±15kV without damage. The ESD struc-tures withstand high ESD in all states: normal operation,shutdown, and powered down. After an ESD event, the MAX13080E–MAX13089E keep working without latchup or damage.ESD protection can be tested in various ways. The transmitter outputs and receiver inputs of the MAX13080E–MAX13089E are characterized for protec-tion to the following limits:•±15kV using the Human Body Model•±6kV using the Contact Discharge method specified in IEC 61000-4-2ESD 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 10a shows the Human Body Model, and Figure 10b shows the current waveform it generates when dis-charged 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.IEC 61000-4-2The IEC 61000-4-2 standard covers ESD testing and performance of finished equipment. However, it does not specifically refer to integrated circuits. The MAX13080E family of devices helps you design equip-ment to meet IEC 61000-4-2, without the need for addi-tional ESD-protection components.+5.0V , ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 TransceiversThe major difference between tests done using the Human Body Model and IEC 61000-4-2 is higher peak current in IEC 61000-4-2 because series resistance is lower in the IEC 61000-4-2 model. Hence, the ESD with-stand voltage measured to IEC 61000-4-2 is generally lower than that measured using the Human Body Model. Figure 10c shows the IEC 61000-4-2 model, and Figure 10d shows the current waveform for IEC 61000-4-2 ESD Contact Discharge test.Machine Model The machine model for ESD tests all pins using a 200pF storage capacitor and zero discharge resis-tance. The objective is to emulate the stress caused when I/O pins are contacted by handling equipment during test and assembly. Of course, all pins require this protection, not just RS-485 inputs and outputs.Applications Information256 Transceivers on the BusThe standard RS-485 receiver input impedance is 12kΩ(1-unit load), and the standard driver can drive up to 32-unit loads. The MAX13080E family of transceivers has a1/8-unit load receiver input impedance (96kΩ), allowingup to 256 transceivers to be connected in parallel on one communication line. Any combination of these devices,as well as other RS-485 transceivers with a total of 32-unit loads or fewer, can be connected to the line.Reduced EMI and ReflectionsThe MAX13080E/MAX13081E/MAX13082E feature reduced slew-rate drivers that minimize EMI and reduce reflections caused by improperly terminated cables, allowing error-free data transmission up to250kbps. The MAX13083E/MAX13084E/MAX13085Eoffer higher driver output slew-rate limits, allowing transmit speeds up to 500kbps. The MAX13089E withSRL = V CC or unconnected are slew-rate limited. WithSRL unconnected, the MAX13089E error-free data transmission is up to 250kbps. With SRL connected toV CC,the data transmit speeds up to 500kbps. MAX13080E–MAX13089E+5.0V, ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 TransceiversM A X 13080E –M A X 13089ELow-Power Shutdown Mode (Except MAX13081E/MAX13084E/MAX13087E)Low-power shutdown mode is initiated by bringing both RE high and DE low. In shutdown, the devices typically draw only 2.8µA of supply current.RE and DE can be driven simultaneously; the devices 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 700ns, the devices are guaranteed to enter shutdown.Enable times t ZH and t ZL (see the Switching Characteristics section) assume the devices were not in a low-power shutdown state. Enable times t ZH(SHDN)and t ZL(SHDN)assume the devices were in shutdown state. It takes drivers and receivers longer to become enabled from low-power shutdown mode (t ZH(SHDN), t ZL(SHDN))than from driver/receiver-disable mode (t ZH , t ZL ).Driver Output ProtectionTwo mechanisms prevent excessive output current and power dissipation caused by faults or by bus contention.The first, a foldback current limit on the output stage,provides immediate protection against short circuits over the whole common-mode voltage range (see the Typical Operating Characteristics ). The second, a thermal-shut-down circuit, forces the driver outputs into a high-imped-ance state if the die temperature exceeds +175°C (typ).Line LengthThe RS-485/RS-422 standard covers line lengths up to 4000ft. F or line lengths greater than 4000ft, use the repeater application shown in Figure 11.Typical ApplicationsThe MAX13082E/MAX13085E/MAX13088E/MAX13089E transceivers are designed for bidirectional data commu-nications on multipoint bus transmission lines. F igures 12 and 13 show typical network applications circuits. To minimize reflections, terminate the line at both ends in its characteristic impedance, and keep stub lengths off the main line as short as possible. The slew-rate-lim-ited MAX13082E/MAX13085E and the two modes of the MAX13089E are more tolerant of imperfect termination.Chip InformationTRANSISTOR COUNT: 1228PROCESS: BiCMOS+5.0V , ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 TransceiversFigure 11. Line Repeater for MAX13080E/MAX13081E/MAX13083E/MAX13084E/MAX13086E/MAX13087E/MAX13089E in Full-Duplex Mode+5.0V, ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 TransceiversMAX13080E–MAX13089EM A X 13080E –M A X 13089E+5.0V , ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 TransceiversPin Configurations and Typical Operating CircuitsMAX13080E–MAX13089E+5.0V , ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 Transceivers______________________________________________________________________________________21Pin Configurations and Typical Operating Circuits (continued)M A X 13080E –M A X 13089E+5.0V , ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 Transceivers 22______________________________________________________________________________________Ordering Information (continued)MAX13080E–MAX13089E+5.0V , ±15kV ESD-Protected, Fail-Safe, Hot-Swap, RS-485/RS-422 Transceivers______________________________________________________________________________________23Package 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 .)。

三星窄边框液晶拼接专用方案北京彩讯科技股份有限公司二零零九年三月1、概述 (3)2 系统组成： (5)2.1、3×5 DID LCD拼接系统组成 (5)2.2、3×5 DID LCD拼接尺寸图 (1)2.3、3×5 DID LCD系统连接图 (1)2.4、TRD1046S2拼接系统工作原理： (4)3 系统主要设备技术指标： (5)3.1、窄边 DID LCD拼接单元举例 (5)3.1.1 窄边拼接单元的产品特性 (5)3.1.2、DID液晶拼接产品的优势： (5)3.1TRD1046S2 (基本技术参数) (6)3.2 TRD1046S2 显示功能 (7)4 图像拼接处理器 (9)4.1、TMC4100大屏幕处理器简介 (9)4.2、TMC4116E4V16大屏幕处理器功能 (9)4.3、TMC4116E4V16系统配置： (11)4.4 、输入和输出 (12)4.4.1 、信号输入 (12)4.4.2 、信号输出 (12)4.5 、系统设置 (13)4.5.1 、服务端主界面： (13)4.5.2 、系统设置界面： (13)4.5.3 、图片信号源设置界面： (14)4.5.4 、输入端口预览界面： (15)4.6 、控制软件的使用 (15)4.6.1 、主窗体组成： (15)4.7 、窗口的相关操作 (21)4.8 、远程受控端 (23)4.9 、用户管理 (25)4.10 、远程桌面 (26)5 安装条件 (28)1、概述在信息化越来越普遍，深入人们工作和生活的时代背景下，监控和大屏幕显示广泛应用于楼宇、交通、安全生产、公共安全等各个领域，行业覆盖房地产、交通运输、企业厂矿、公安电信等等各行各业。

选用不同的显示单元和拼接单元，以满足具体的显示需求，成为我们公司制定不同方案的首要考虑。

随着三星大尺寸工业用液晶显示器不断推出，针对监控领域的细分化产品也不断趣于成熟，为拼接方案提供了更专业和更实用的选择。

ThinkSystem SE350 Purpose-built IoT, Edge serverPurpose Built Edge Server for Compute & StorageToday, remote locations are forced to make a choice between underpowered IOT gateways and PCs, or overpowered and non-rugged datacenter centric servers. Now they have an option—a right-sized compact compute and storage server designed specifically to meet the needs of remote locations. The Lenovo ThinkSystem SE350 is an Intel® Xeon® D-2100-based 1U height, half-width, and short-depth Edge server that can go anywhere. It can be hung on a wall, stacked on a shelf, or mounted in a rack. This rugged Edge server can handle temperatures from0-55°C as well as tolerance to locations with high-dust and vibration.The SE350 is designed to virtualize traditional IT and OT applications as well as new transformative IOT and AI systems, providing the processing power, storage, accelerator, and networking techniques required for today’s Edge workloads.Secure, Connected and ReliableAt Lenovo, security begins with design and continues through supply chain, delivery, and the full lifecycle of the system.The SE350 equips ThinkShield security with cybersecurity capabilities with key encrypted storage and secured bios, and physical security capabilities such as a locking bezel, intrusion and tamper protection mechanisms.The SE350 provides numerous connectivity options with wired and secure wireless Wi-Fi and LTE connection abilities. Reliability features such as wireless failover, redundant boot and data drives, high temperature components and support for hyperconverged clustering keep critical Edge workloads running.Agility and Remote ManageabilityIt is costly and time consuming to send IT staff to remote sites. The SE350 features XClarity Controller, an enterprise-grade embedded management engine. It also supports XClarity Administrator, which enables IT managers to efficiently maintain server, storage, and networking infrastructure and accelerate services provisioning.In addition to a dedicated wired networking management port, the SE350 can deliver management over a secure wireless connection so IT managers can perform updates, management tasks, and access sites even when the primary site internet connection isdown.© 2023 Lenovo. All rights reserved.Availability: Offers, prices, specifications and availability may change without notice. Lenovo is not responsible for photographic or typographic errors. Warranty: For a copy of applicable warranties, write to: Lenovo Warranty Information, 1009 Think Place, Morrisville, NC, 27560. Lenovo makes no representation or warranty regarding third-party products or services.Trademarks: Lenovo, the Lenovo logo, ThinkAgile®, ThinkShield®, ThinkSystem®, TruDDR4, and XClarity® are trademarks or registered trademarks of Lenovo. Intel® and Xeon® are trademarks of Intel Corporation or its subsidiaries. Microsoft®, Windows Server®, and Windows® are trademarks of Microsoft Corporation in the United States, other countries, or both. Other company, product, or service names may be trademarks or service marks of others.Document number DS0088, published August 12, 2020. For the latest version, go to /ds0088.。

REGULATED DC POWER SUPPLY MODEL: SEC-1235CEPlease read this manual before operating your power supply.TABLE OF CONTENTSTopic PageImportant safety instructions2Description and features3Operation from AC iput voltage of 230 VAC3Connections and operation4Cooling fan control / thermal protection4Battery charging and battery back up5Trouble shooting6Limiting electromagnetic interference7Switching power supplies & RF noise 8,9,10 Specifications 11 Warranty 12RISK OF ELECTRIC SHOCKDO NOT OPENWARNING—TO REDUCE THE RISK OF FIRE OR ELECTRIC SHOCK, DO NOT EXPOSE THIS APPLIANCE TO RAIN OR MOISTURE. THERE ARE NO USER SERVICEABLE P ARTS INSIDE—REFER TO QUALIFIED SERVICE PERSONNEL.IMPORTANT SAFETY INSTRUCTIONSPlease read before using your power supply.1) It Is recommended that you return your power supply to a qualified dealer for any service or repair. Incorrect assembly may result in electric shock or fire.2) To reduce the risk of electric shock, unplug the power supply from the outlet before attempting any maintenance or cleaning. Turning off controls will not re-duce this risk.3) If an extension cord is used, make sure that it has grounded male plug Type EU1-16P (CEE-7/7, “Schuko”) and grounded female receptacle(s) Type EU1-16R (CEE-7/4, “Schuko”). The size of the current carrying conductors should be such that they are able to carry at least 5 A for the length of the extension.4) Place the unit in an area that will allow air to flow freely around the unit. DO NOT block or obstruct vent openings on the side/bottom of the unit.5) Keep the unit away from moisture and water.6) NEVER OPERATE THE UNITS IN PARALLELWARNING! Your power supply should be grounded to reduce the risk of electric shock. The power supply comes with a detachable power cord that has a grounded male plug Type EU1-16P (CEE-7/7, “Schuko”). The flat contact strips on the circumference of the plug get connected to the chassis of the unit. When the power cord is plugged into the corresponding receptacle Type EU1-16R (CEE-7/ 4, “Schuko”), the chassis of the unit is automatically connected to the earth ground through the equipment grounding conductor that is connected to the spring con-tacts of the power outlet receptacle Type EU1-16R (CEE-7/4, “Schuko”).The power cord must be plugged into a Type EU1-16R (CEE-7/4, “Schuko”) outlet that is properly installed and grounded in accordance with all local codes and ordinances. Never alter the power cord that has been provided. If the plug of the cord will not fit the outlet, have a proper outlet installed by a qualified electrician. Improper connection can result in risk of electric shock.DO NOT USE THE POWER SUPLY FOR DIRECT CHARGING OF BATTERY OR DI-RECT CONNECTION TO A BATTERY FOR BATTERY BACK-UP. (Please read the section on “Battery Charging and Battery Back-up” on page 5).2.SEC-1235CE is a Switched Mode Power Supply (SMPS) which converts 230 V, 50 Hz AC power to regulated 13.8 V DC power based onPulse Width Modulation (PWM) control.•Based on switched mode technology and PWM control•Compact and light weight•High efficiency and less heat dissipation•Protected against short circuit, over load and over temperature•Cooling by temperature controlled fan•Safety compliance to European Low Voltage Directive 2006/95/EC •EMI/EMC compliance to European EMC Directive 2004/108/EC3.4.NOTE : The DC output connectors (RED + and Black -) have a tubular hole of diameter 0.2” (5mm) with a set screw. If bare wire with stranded conductors is used to connect the load to the above output connectors of the power supply, the strands will spread out as the set screw is tightened and hence, the set screw will not pinch all the strands. As a result, the effective cross section of the current conducting area of the wire will be reduced resulting in voltage drop at the load end, reduced efficiency and also overheating. For a firm connection, crimp / sol-der a suitable pin type of copper terminal on the wire end to be connected to the power supply. For convenience, a pair of terminals has been provided for crimp-ing / soldering to the wire end.OPERATION• Ensure that the on / off switch on the power supply is switched off and it is un-plugged from the AC outlet • Switch off the 12 V load to be connected to the power supply. Connect the positive input wire of the load to the RED (Positive) terminal of the power supply and the negative input wire of the load to the BLACK (Negative) terminal of the power supply. Ensure that the connections are secure and tight • Plug the power supply into the AC outlet. Press the On / Off switch of the power supply to the On position and check that the switch is illuminated indicating availability of the AC input power. If the On / Off switch is not illuminated, recheck the AC input connection, AC outlet and the fuse inside the power supply.• Now switch on the DC load • Ensure that the continuous load is limited to 30 AWARNING! Operate the unit in a well ventilated, open and cool area. Do not block the openings at the fan discharge on the bottom of the unit and the suction openings on the sides.The units are cooled by convection and by forced air cooling. A temperature controlled fan has been provided to improve cooling at higher loads and at higher ambient temperatures. The switching on of the fan is controlled by a sen-sor mounted on the power transformer. The fan will be switched on when the temperature of the sensor reaches 60° C +/- 5° C. The fan will be automatically switched off when the sensor cools down to 50° C +/- 5° C. Thus, at lower loads or during lower ambient temperatures, the fan may remain switched off.An additional protection is provided to shut down the power supply in case the fan fails or if the air flow is blocked or if the ambient temperature is very high. A second temperature sensor is also mounted on the power transformer and will activate at 105° C +/- 5° C and shut down the output of the power supply. After the power supply cools down to 95° C +/- 5° C, the temperature sensor will de-activate and the power supply will resume operation automaticallyThe output voltage can be adjusted with the help of the internal potentiometer marked “VR2”. Adjustment range is (11V to 16 V).WARNING! At output voltages higher than 13.8 V, the maximum output current should be reduced linearly from 30 A at 13.8 V to 25 A at 16 V.OVERLOAD / SHORT CIRCUITThe units are protected against overload by constant current limiting at 35 A. If the load tries to draw more than 35A, the output voltage will drop and will no longer be regulated. The output voltage will drop to near 0 V in case of a dead short. The unit will recover automatically once the overload condition is removed.OVER TEMPERATUREProtection is provided to shut down the power supply in case the fan fails or if the air flow is blocked or if the ambient temperature is very high. A temperature sensor is mounted on the power transformer and will activate at 105° C +/- 5° C and shut down the output of the power supply. After the power supply cools down to 95° C +/- 5° C, the temperature sensor will de-activate and the power supply will re-sume operation automaticallyWARNING!These units are power supplies and not battery chargers.Do not connect these units directly to a batteryThe voltage of a 12 V battery in a deep discharged condition will be around 10 to 11.4 V. When a deeply discharged 12 V battery is charged at say 13.8 V, it will initially draw a very large current. As the battery capacity is restored, the battery voltage increases to around 13.8 V when fully charged and the current drawn by the battery reduces a few hundred mA.If a deeply discharged battery is directly charged by SEC-1235CE, the battery will initially draw a very large current and thus, will force the power supply into current limit mode for prolonged period of time. This is harmful for the power supply as operating under prolonged periods under current limit conditions is an abnormal operating condition.SEC-1235CE may be used for battery charging and battery backup application only when the battery is charged through a suitable external isolating diode and charge limiting resistor in series with the power supply. The isolating diode will ensure that the battery does not feed power back into the power supply and the series connected charge limiting resistor will limit the maximum charging current to a value less than the current limit.It is recommended that the optional Battery Backup Module BBM-12100 may be used in conjunction with the power supply for battery charging / backup application.Call Technical Support at 1-800-561-5885 for further assistance5.PROBLEM : Power ON/OFF switch does not illuminate when turned on.PROBABLE CAUSE SUGGESTED REMEDYNo power in the AC outlet Check there is power in the outlet.AC side fuse inside the power Replace the fuse inside the unit. supply is blown See fuse ratings at page 11PROBLEM : AC side fuse blows as soon as power is turned on.PROBABLE CAUSE SUGGESTED REMEDYUnit is defective Call technical support. PROBLEM : The output voltage is 0 V or very lowPROBABLE CAUSE SUGGESTED REMEDYInput voltage is very low Check that the input voltage is230VACThe unit is in current limit condition Check the output terminals are not due to overload caused by large reactive shorted. Remove the load. If the loading or by the output being short output voltage gets restored, the circuited load is shorted or is offering largereactive impedance.Unit is shut down due to over Check that the fan has not failed or temperature.the vent openings are not blockedPROBLEM : Output voltage drops as soon as the load is switched on PROBABLE CAUSE SUGGESTED REMEDYThe unit is going into current Reduce the load currentlimit protection mode to less than the current limit value.Motors, pumps, compressors,relays, incandescent and halogenlamps and large capacitors in theinput section of the DC devicesdraw very high inrush or startingcurrents of up to 10 times theirnormal operating currents. Ensurethat these inrush/starting currents6.This equipment has been tested and found to comply with the limits as laid down under European Standards EN55022 (Class-B) & EN610000-3 - 2 & 3. These limits are designed to provide reasonable protection against a harmful interference in a residential installation. This equipment generates, uses and can radiate radio frequency energy and, if not installed and used in accor-dance with the instructions, may cause harmful interference to radio commu-nications. However, this does not guarantee that interference will not occur in a particular installation. If this equipment does cause harmful interference to radio or television reception, which can be determined by turning the equip-ment off and on, the user is encouraged to try to correct the interference by one or more of the following measures:•Reorient or relocate the receiving antenna.•Increase the separation between the equipment and receiver.•Connect the equipment into an outlet on a circuit different from that to which the receiver is connected.•Consult the dealer or an experienced radio / TV technician for help.7.1. Switched mode power supplies ( SMPS ) employ high frequency switch-ing and thus, are a source of radio interference, a recipient of radio interfer-ence and a conduit of radio interference. ( Older linear type transformer based power supplies do not employ high frequency switching voltages and will be quieter as compared to switching type of supplies).2. The primary emission sources originate in the switching devices due to their fast switching current transitions: harmonics of the switching frequency and broadband noise created by under-damped oscillations in the switching circuit. The secondary source is from the bridge rectifier, both rectifier noise and diode recovery. The AC input rectifier / capacitor in the front end of the switching power supplies ( excepting those with power factor correction ) are notorious for generating power supply harmonics due to the non linear input current waveform. The noise is both conducted and radiated through the input power cord and the DC output wiring to the radio.3. Switching power supplies are also recipients of radio interference. The normal operation of the power supply can be disturbed due to RF noise getting coupled into the power supply. Thus, the power supply may generate excessive RF noise and lose output voltage regulation due to excessive trans-mitter energy being coupled through the AC / DC lines to the power supply’s regulator feedback path. This may be due to antenna being too close or due to the antenna or feed system not radiating properly. First check the antenna system SWR. Then, if necessary, relocate either the antenna or the power supply farther apart.4. The receiver may “hear” the power supply. A slowly moving, slightly buzz-ing carrier heard in the receiver may be caused by the antenna being too close. As with the transmitter related noise pick up, a loose coaxial connec-tor or a broken or a missing ground may aggravate this problem. Normally these noises will be below the background or “band” noise. Increase the separation between the power supply and the receiving antenna. Use an outdoor antenna. This will reduce the amount of signal picked up from the power supply and also increase the amount of the desired signal.8.5. The conducted and radiated noises are limited as per the applicable na-tional / international standards. In North America, the applicable standard is as per FCC Part 15(B) for Class “B” digital devices. The European standard is as per EN55022, Class “B” & EN610000-3-2, 3. Thus, the RF interfer-ence is limited but not entirely eliminated.6. The conducted RF noise from these power supplies is limited to the maxi-mum allowable levels by internal filtration. The filtered RF noise currents (normally < 5mA ) are bypassed to the chassis of the power supply. The chassis is, in turn, connected to the earth ground pin of the AC input power cord (for Class 1 units). Thus, the filtered noise currents are intentionally leaked to the earth ground. This is termed as the “Earth Leakage Current”. For safety against electric shock, this earth leakage current is also required to be limited. It will be seen that these two requirements are conflicting. NOTE: In some cases, to prevent electric shock hazard due to abnor-mal leakage current (like in marinas, spas, hot tubs, wet spaces etc.), the AC outlet circuits / receptacles in these areas are served through a GFCI (Ground Fault Circuit Interrupter ). This GFCI is normally set to trip when it senses an earth leakage current > 5 mA. A single GFCI may be serving multiple AC outlet circuits / receptacles and therefore, will be sensing the sum of all the leakage currents of the devices connected to these. As the switching power supplies have intentional leakage current as explained above, it may trip a GFCI feeding multiple AC outlet circuits / receptacles. In such cases, disconnect devices connected to the other AC outlet circuits / recep-tacles served by this GFCI.9.7. Following additional guidelines may be followed to reduce the effects of RF noise:e additional appropriate AC radio frequency interference (RFI)power line filter rated for minimum 5 A immediately before the ACinput of the power supply. For example, consider suitability ofmodel # 6VN1 from “N” series by Corcom, Inc. () orsimilar. Filtered, ferrite coated cord set ( ) isanother choice. These cord sets, with integral line interferencefilters, reduce common and differential mode interferences over awide frequency range. Because they are shielded, they are alsoeffective against radiated interferences. In addition to the built-infilter networks, the cable conductors are coated with an RF ab-sorbing ferrite compound. This provides additional attenuation athigh frequencies that is lacking in most regular LC filters. The RFabsorption of the ferrite-coated cable avoids resonances at highfrequencies, reducing the conducted and radiated RF noises evenfurthere additional appropriate DC radio frequency interference (RFI)power line filter rated for minimum 40 A immediately after the DCoutput of the power supply. For example, consider suitability ofmodel # “FD10B050” from “FD” series by Curtis Industries() or similar.c.Twist the positive and negative wires from the output of the powersupply to the radio.d.The DC side positive and negative outputs of these power sup-plies are isolated from the chassis. As explained at paragraph 6above, the noise currents are filtered to the chassis ground andthe chassis ground is connected to the earth ground through theearth ground pin of the AC power outlet receptacle. Avoid con-necting (referencing) the DC negative output terminal of the powersupply to the earth ground.e.Connect a 1/4” wave length of wire on the negative terminal of thepower supply. Connect one end of the wire to the negatvie termi-nal and leave the other end free. The wave length corresponds tothe wave length of the interfering frequency. (May not be practicalfor long wave lengths).[ Formula: Wave length (Meters) = 300 / frequency in MHz ]10.Model No.SEC-1235CENominal Input Voltage230 VAC, 50Hz (Range: 207 to 253 VAC)Input current 3.5 A at 230 VACOutput Voltage13.8 VDCOutput voltage adjustment11.5 V to 15.5 V with the help of internal potentiometer Output current30 A continuousCurrent limit35 A, constant current limiting, auto recoveryNo load current draw130 mA at 230 VAC, 50 HzRipple50 mV peak to peakNoise150 mV peak to peakPeak Efficiency85%Cooling Temperature controlled fanProtections against Overload, short circuitOver temperatureOperating temperature0° to 40° CSafety compliance Comforms to European Low Voltage Directive 2006/95/EC • Standards• IEC 60950-1; EN 60950-1EMI/EMC compliance Comforms to European EMC Directive 2004/108/EC • Standards• EN 55022 (class B); EN 61000-3-2; EN 61000-3-3• EN 55024 :EN 61000-4-2 to 6; EN 61000-4-8; EN 61000-4-11 AC input connections Male AC inlet connector Type “IEC 320-C14”Detachable AC power cord with:• Female connector Type “IEC 320-C13” on one end tomate with AC power inlet connector on the power supply• Male, 2 pole, 3 Wire grounding plug Type EU1-16P(CEE 7/7) (Schuko) on the other end for connection to theAC outlet.DC output connections RED (+) and BLACK (-) terminals with tubular hole and setscrew. Hole diameter 0.2 “, (5 mm). Includes a pair of copper terminal lugs for crimping to output wires to the load Input side fuse250V, 4 A(5 mmX20mm, glass ferrule,Manufacturer: Ltttel Fuse, Model 218004delayed action)Weight 3.4 lbsDimensions (L X W X H)8” X 7.3” X 2.5”Note:The above specifications are subject to change without notice11.SEC-1235CE manufactured by Samlex America, Inc. (the “Warrantor“) is war-ranted to be free from defects in workmanship and materials under normal use and service. This warranty is in effect for 3 years from the date of purchase by the user (the “Purchaser “)For a warranty claim, the Purchaser should contact the place of purchase to obtain a Return Authorization Number.The defective part or unit should be returned at the Purchaser’s expense to the authorized location. A written statement describing the nature of the defect, the date of purchase, the place of purchase, and the Purchaser’s name, address and telephone number should also be included.If upon the Warrantor’s examination, the defect proves to be the result of defective material or workmanship, the equipment will be repaired or replaced at the Warrantor’s option without charge, and returned to the Purchaser at the Warrantor’s expense.No refund of the purchase price will be granted to the Purchaser, unless the Warrantor is unable to remedy the defect after having a reasonable number of opportunities to do so.Warranty service shall be performed only by the Warrantor. Any attempt to remedy the defect by anyone other than the Warrantor shall render this warranty void.There shall be no warranty for defects or damages caused by faulty installation or hook-up, abuse or misuse of the equipment including exposure to excessive heat, salt or fresh water spray, or water immersion.No other express warranty is hereby given and there are no warranties which extend beyond those described herein. This warranty is expressly in lieu of any other expressed or implied warranties, including any implied warranty of mer-chantability, fitness for the ordinary purposes for which such goods are used, or fitness for a particular purpose, or any other obligations on the part of the Warran-tor or its employees and representatives.There shall be no responsibility or liability whatsoever on the part of the Warrantor or its employees and representatives for injury to any persons, or damage to person or persons, or damage to property, or loss of income or profit, or any other consequential or resulting damage which may be claimed to have been incurred through the use or sale of the equipment, including any possible failure of mal-function of the equipment, or part thereof.The Warrantor assumes no liability for incidental or consequential damages of any kind.Samlex America Inc. (the “Warrantor”)110-17 Fawcett RoadCoquitlam BC V3K6V2 Canada(604) 525-383612.Notes:Attach copy of receipt here:Version SEC1235CE(Nov2007)Thank you purchasing a Samlex power supply product!。

产品手册目录产品手册 (1)一、65E900U产品简介 (2)（一）产品定位 (2)（二）2/4构成 (2)（三）沟通要点 (3)（四）备注 (3)二、E790U产品简介 (4)（一）产品定位 (4)（二）2/4构成 (4)（三）沟通要点 (4)（四）备注 (5)三、E710U产品简介 (4)（一）产品定位 (4)（二）2/4构成 (4)（三）沟通要点 (4)四、E690U产品简介 (5)（一）产品定位 (7)（二）2/4构成 (8)（三）沟通要点 (8)（四）备注 (9)五、E730A 产品简介 (9)（一）产品定位 (9)（二）2/4 构成 (9)（三）沟通要点 (9)（四）备注 (10)六、E660E产品简介 (10)（一）产品定位 (10)（二）2/4 构成 (10)（三）沟通要点 (11)（四）备注 (11)七、E510E产品简介 (11)（一）产品定位 (11)（二）2/4构成 (12)（三）沟通要点 (12)（四）备注 (13)八、E360E产品简介 (13)（一）产品定位 (13)（二）2/4构成 (13)（三)沟通要点 (13)（四）备注 (14)九、E200E产品简介 (14)（一）产品定位 (14)（二）2/4 构成 (14)（三）沟通要点 (14)（四）备注 (15)第二章：模块简介 (15)一、天赐派 ............................................................................................................................... 错误!未定义书签。

（一）定义 ........................................................................................................................ 错误!未定义书签。

CD4013中文资料(真值表,引脚图,电气参数等)CD4013中文资料(真值表,引脚图,电气参数等)CD4013功能:CD4013是一双D触发器,由两个相同的、相互独立的数据型触发器构成。

每个触发器有独立的数据、置位、复位、时钟输入和Q及Q输出，此器件可用作移位寄存器，且通过将Q输出连接到数据输入，可用作计算器和触发器。

在时钟上升沿触发时，加在D输入端的逻辑电平传送到Q输出端。

置位和复位与时钟无关，而分别由置位或复位线上的高电平完成。

CD4013 Truth Table 真值表功能:CL (Note 1) D R S Q Q↑0 0 0 0 1↑ 1 0 0 1 0↓x 0 0 Q Qx x 1 0 0 1x x 0 1 1 0x x 1 1 1 1CD4013引脚图:图１CD4013引脚图CD4013内部结构图:图２CD4013内部电路图图3 CD4013逻辑图CD4013电气参数:Absolute Maximum Ratings 绝对最大额定值:DC Supply Voltage 直流供电电压 (VDD) -0.5 VDC to +18 VDC Input Voltage输入电压 (VIN) -0.5 VDC to VDD +0.5 VDC Storage Temperature Range储存温度范围 (TS) -65℃ to +150℃Recommended Operating Conditions 建议操作条件:DC Electrical Characteristics 直流电气特性:AC Electrical Characteristics 交流电气特性:图4 切换时间波形CD4013应用电路：图5（左）和图（右）中的CD4013是CMOS双D触发器，这类电路置位和复位信号是高电平有效，由于开关闭合时电容可视为短路而产生高电平，使RD=1，Q=0；若将此信号加到SD，则SD=1，Q=1;置位、复位过后，电容充电而使RD（SD）变为0，电路可进入计数状态。

三极管---3AD、3AG、3AK、3AX、3CA（国产系列）资料3AD11 锗PNP 20W 5A 20V 3k3AD12 锗PNP 30V 5A 20W ≥3KHz β=15-403AD150 锗PNP 15W 3A 25V 4k3AD18B 锗PNP 50W 15A 20V 100k3AD30 锗PNP 20W 6A 24V 2k3AD30C 锗PNP 20W 4A 24V 2k3AD4 锗PNP 10W 2A 30V 100k3AD40 锗PNP 15W 5A 25V3AD503 锗PNP 15W 5A 30V 4k3AD50A 锗PNP 18V 3A 10W 4KHz β≥20封装F-13AD50B 锗PNP 24V 3A 10W 4KHz β≥20封装F-13AD50C 锗PNP 30V 3A 10W 4KHz β≥20封装F-13AD51A 锗PNP 18V 2A 10W 4KHz β≥20封装圆-13AD51B 锗PNP 24V 2A 10W 4KHz β≥20封装圆-13AD51C 锗PNP 30V 2A 10W 4KHz β≥20封装圆-13AD52A 锗PNP 18V 2A 10W 4KHz β≥20封装F-13AD52B 锗PNP 24V 2A 10W 4KHz β≥20封装F-13AD52C 锗PNP 30V 2A 10W 4KHz β≥20封装F-13AD53A 锗PNP 12V 5A 20W 2KHz β≥20封装F-23AD53B 锗PNP 18V 5A 20W 2KHz β≥20封装F-23AD53C 锗PNP 24V 5A 20W 2KHz β≥20封装F-2 3AD54A 锗PNP 15V 5A 20W 3KHz β≥20封装圆-2 3AD54A 锗PNP 20V 5A 20W 3KHz β≥20封装圆-2 3AD54A 锗PNP 30V 5A 20W 3KHz β≥20封装圆-2 3AD55A 锗PNP 20W 5A 15V 3KHz β≥20封装F-2 3AD55B 锗PNP 20W 5A 20V 3KHz β≥20封装F-2 3AD55C 锗PNP 20W 5A 30V 3KHz β≥20封装F-2 3AD56A 锗P NP 50W 15A 30V 3KHz β≥20封装方盘型3AD56B 锗PNP 50W 15A 45V 3KHz β≥20封装方盘型3AD56C 锗PNP 50W 15A 60V 3KHz β≥20封装方盘型3AD57A 锗PNP 100W 30A 30V 3KHz β≥20封装方型3AD57B 锗PNP 100W 30A 45V 3KHz β≥20封装方型3AD57C 锗PNP 100W 30A 60V 3KHz β≥20封装方型3AD6C 锗PNP 70V/30V 2A 10W ≥4KHz β≥123AD725B = 3AD57A 100W 30A 30V 3KHz3AD725C = 3AD57B 100W 30A 45V 3KHz3AD725D = 3AD57C 100W 30A 60V 3KHz3AD75D 锗PNP 75W 16A 90V 100k3AF54E 锗PNP 100mW 30mA 15V 300M3AG10 锗PNP 50mW 10mA 10V 30.0M3AG11 锗PNP 50mW 10mA 10V 20.0M3AG12 锗PNP 100mW 50mA 15V 30.0M3AG13 锗PNP 100mW 50mA 15V 465k 3AG13 锗PNP 50mW 10mA 10V 40.0M 3AG14 锗PNP 100mW 50mA 20V 465k 3AG1A 锗PNP 50mW 10mA 10V 15.0M 3AG1B 锗PNP 50mW 10mA 10V 60.0M 3AG1C 锗PNP 50mW 10mA 10V 40.0M 3AG1C 锗PNP 50mW 10mA 10V 80.0M 3AG1C 锗PNP 50mW 10mA 11V3AG1D 锗PNP 50mW 10mA 10V 50.0M 3AG1E 锗PNP 50mW 10mA 10V 65.0M 3AG1E 锗PNP 50mW 10mA 11V3AG21 锗PNP 50mW 10mA 10V 20.0M 3AG21 锗PNP 50mW 10mA 10V 40.0M 3AG22 锗PNP 50mW 10mA 10V 30.0M 3AG22B 锗PNP 50mW 10mA 10V 25.0M 3AG23 锗PNP 50mW 10mA 10V 50.0M 3AG24D 锗PNP 50mW 10mA 10V 65.0M 3AG24E 锗PNP 50mW 10mA 10V 80.0M 3AG25 锗PNP 50mW 10mA 10V 40.0M 3AG26 锗PNP 50mW 10mA 10V 60.0M 3AG27 锗PNP 100mW 10mA 200k3AG28 锗PNP 100mW 10mA 200k3AG29 锗PNP 100mW 10mA 200k3AG29A 锗PNP 150mW 50mA 15V 150M 3AG29B 锗PNP 150mW 50mA 15V 150M 3AG29C 锗PNP 150mW 50mA 15V 200M 3AG29D 锗PNP 150mW 50mA 15V 200M 3AG31 锗PNP 50mW 50mA 20V 8.0M3AG31 锗PNP 75mW 50mA 30V 8.0M3AG31A 锗PNP 100mW 120mA 12V3AG31D 锗PNP 100mW 100mA 12V3AG31H 锗PNP 75mW 50mA 30V 8.0M 3AG32 锗PNP 50mW 50mA 20V 8.0M3AG32 锗PNP 75mW 50mA 30V 8.0M3AG32H 锗PNP 75mW 50mA 30V 8.0M 3AG35 锗PNP 60mW 30mA 10V 100.0M 3AG36 锗PNP 60mW 20mA 10V 200M3AG37 锗PNP 60mW 20mA 10V 300M3AG41 锗PNP 60mW 30mA 10V 30.0M3AG41H 锗PNP 100mW 30mA 12V 30.0M 3AG42 锗PNP 50mW 10mA 12V 50.0M3AG43 锗PNP 50mW 10mA 10V 100M3AG45 锗PNP 50mW 10mA 12V 200M3AG45 锗PNP 60mW 20mA 10V 300M3AG46 锗PNP 100mW 100mA 20V 8.0M 3AG47 锗PNP 100mW 100mA 20V 8.0M 3AG48 锗PNP 120mW 50mA 25V 100M 3AG50 锗PNP 100mW 30mA 12V 300M 3AG51A 锗PNP 100mW 100mA 12V3AG51A 锗PNP 50mW 10mA 10V 15.0M 3AG51B 锗PNP 100mW 100mA 12V3AG51C 锗PNP 100mW 100mA 18V3AG51D 锗PNP 100mW 100mA 24V3AG51D 锗PNP 50mW 10mA 10V 50.0M 3AG53A 锗PNP 50mW 10mA 15V 30.0M 3AG53B 锗PNP 50mW 10mA 12V 50.0M 3AG53B 锗PNP 50mW 10mA 15V 50.0M 3AG53C 锗PNP 50mW 10mA 10V 100M3AG53D 锗PNP 50mW 10mA 15V 200M3AG54A 锗PNP 100mW 30mA 15V 30.0M 3AG54B 锗PNP 100mW 30mA 15V 50.0M 3AG54C 锗PNP 100mW 30mA 12V 100M 3AG54D 锗PNP 100mW 30mA 12V 200M3AG54E 锗PNP 100mW 30mA 15V 200M 3AG55A 锗PNP 150mW 50mA 15V 100M 3AG55B 锗PNP 150mW 50mA 15V 200M 3AG55C 锗PNP 150mW 50mA 15V 300M 3AG56A 锗PNP 50mW 10mA 10V 25.0M 3AG56B 锗PNP 50mW 10mA 10V 25.0M 3AG56C 锗PNP 50mW 10mA 10V 50.0M 3AG56D 锗PNP 50mW 10mA 10V 65M3AG56E 锗PNP 50mW 10mA 10V 80M3AG56E1 锗PNP 50mW 10mA 10V 80M 3AG56E2 锗PNP 50mW 10mA 10V 100M 3AG61 锗PNP 500mW 150mA 20V3AG62 锗PNP 500mW 150mA 30V3AG63 锗PNP 500mW 150mA 35V3AG64 锗PNP 500mW 150mA 35V3AG71A 锗PNP 50mW 10mA 11V3AG71B 锗PNP 50mW 10mA 10V 3.0M 3AG71C 锗PNP 50mW 10mA 15V 3.0M 3AG72 锗PNP 50mW 10mA 15V 7.0M3AG73 锗PNP 300mW 150m 20V3AG74 锗PNP 250mW 120m 35V3AG802 锗PNP 50mW 30mA 10V3AG80C 锗PNP 50mW 10mA 15V 400M3AG87A 锗PNP 300mW 50mA 15V3AG87B 锗PNP 300mW 50mA 20V3AG87C 锗PNP 300mW 50mA 20V3AG87D 锗PNP 300mW 50mA 20V3AG9 锗PNP 50mW 10mA 10V 20.0M3AG95B 锗PNP 150mW 30mA 20V 700M3AG95C 锗PNP 150mW 30mA 20V 1.0G3AK20 锗PNP 100mW 30mA 12V 80.0M3AK20B 锗PNP 50mW 20mA 15V 150M3AK20C 锗PNP 50mW 20mA 15V 210M3AK25 锗PNP 100mW 30mA 15V 150M3AX2 锗PNP 150mW 50mA 15.0V 230k3AX21E 锗PNP 150mW 150mA 12.0V 8.0k 3AX22 锗PNP 125mW 100mA 30V3AX221B 锗PNP 150mW 150mA 18.0V3AX23 锗PNP 125mW 100mA 25V3AX24 锗PNP 125mW 100mA 25.0V3AX25A 锗PNP 200mW 500mA 40.0V3AX25C 锗PNP 200mW 500mA 50.0V3AX31 锗PNP 125mW 125mA 6V3AX31A 锗PNP 125mW 120mA 12V3AX31A 锗PNP 125mW 120mA 12V3AX31A 锗PNP 150mW 125mA 12 V3AX31A 锗PNP 150mW 125mA 12V3AX31B 锗PNP 150mW 125mA 18V3AX31C 锗PNP 125mW 100mA 27V3AX31E 锗PNP 150mW 125mA 12V 8k3AX31M 锗PNP 125mW 125mA 6V3AX31M 锗PNP 150mW 150mA 6V3AX45C 锗PNP 200mW 200mA 10V3AX52 锗PNP 150mW 150mA 12V3AX52D 锗PNP 150mW 150mA 24V3AX54B 锗PNP 200mW 500mA 40V3AX54G 锗PNP 200mW 500mA 70V3AX54G2 锗PNP 200mW 500mA 70V3AX54G4 锗PNP 200mW 500mA 60V3AX55A 锗PNP 500m 500m 20V3AX55M 锗PNP 500mW 500mA 12.0V 5.0k 3AX7 锗PNP 150mW 150mA 12.0V 465k 3AX7 锗PNP 150mW 50mA 15.0V 500k3AX81 锗PNP 200mW 200mA 8.0V3AX81A 锗PNP 200mW 200mA 10V3AX81B 锗PNP 200mW 200mA 15V3AX81B 锗PNP 500mW 500mA 15V3AX81C 锗PNP 200mW 200mA 10V3AX83A 锗PNP 500mW 500mA 20V3AX85A 锗PNP 300mW 300mA 12V3AX85B 锗PNP 300mW 300mA 12V3AX9 锗PNP 150mW 50mA 12V 1M3AX91 锗PNP 600mW 500mA 20V3AX93A 锗PNP 700mW 700mA 15V3AX93B 锗PNP 700mW 700mA 25V3AX93C 锗PNP 700mW 700mA 35V3AX93D 锗PNP 700mW 700mA 45V3AX93E 锗PNP 700mW 700mA 55V3BG1 锗NPN 50m 20m 15.0 70.0M 124 国产3BX31A 锗NPN 125m 125m 10.0 124 国产3BX31B 锗NPN 125m 125m 18.0 172 国产3BX31C 锗NPN 125m 125m 24.0 172 国产3BX31M 锗NPN 125m 125m 6.0 124 国产3BX55A 锗NPN 500m 500m 20.0 158 国产3BX55B 锗NPN 500m 500m 30.0 158 国产3BX55C 锗NPN 500m 500m 45.0 5.0k 158 国产3BX55M 锗NPN 500m 500m 12.0 国产3BX81A 锗NPN 200m 200m 10.0 178 国产3BX81B 锗NPN 200m 200m 15.0 国产3BX81C 锗NPN 200m 200m 10.0 12.0k 172 国产3BX81M 锗NPN 200m 200m 8.0 国产3BX83 锗NPN 500m 500m 15.0 国产3BX85A 锗NPN 300m 300m 12.0 国产3BX85B 锗NPN 300m 300m 18.0 国产3BX85C 锗NPN 300m 300m 24.0 国产3CA1 硅PNP 5.0 0.5 40.0 60.0M 155 国产3CA104A 硅PNP 10.0 1 40.0 60.0M 155 国产3CA104B 硅PNP 10.0 1 60.0 60.0M 155 国产3CA104C 硅PNP 10.0 1 80.0 60.0M 155 国产3CA10F 硅PNP 25.0 2.5 150.0 30.0M 155 国产3CA10G 硅PNP 25.0 2.5 200.0 30.0M 155 国产3CA11A 硅PNP 10.0 1.5 40.0 60.0M 155 国产3CA11B 硅PNP 10.0 1.5 60.0 60.0M 155 国产3CA11C 硅PNP 10.0 1.5 80.0 60.0M 155 国产3CA11D 硅PNP 10.0 1.5 100.0 60.0M 155 国产3CA11E 硅PNP 10.0 1.5 120.0 60.0M 155 国产3CA11F 硅PNP 10.0 1.5 140.0 60.0M 155 国产3CA11G 硅PNP 10.0 1.5 180.0 60.0M 155 国产3CA1A 硅PNP 5.0 0.5 40.0 60.0M 155 国产3CA1B 硅PNP 5.0 0.5 60.0 60.0M 155 国产3CA1C 硅PNP 5.0 0.5 80.0 60.0M 155 国产3CA1D 硅PNP 5.0 0.5 100.0 60.0M 155 国产3CA1E 硅PNP 5.0 0.5 120.0 60.0M 155 国产3CA1F 硅PNP 5.0 0.5 140.0 60.0M 155 国产3CA2 硅PNP 3.0 0.3 30.0 50.0M 155 国产3CA2A 硅PNP 3.0 0.3 30.0 50.0M 155 国产3CA2B 硅PNP 3.0 0.3 30.0 50.0M 155 国产3CA2C 硅PNP 3.0 0.3 80.0 50.0M 155 国产3CA2D 硅PNP 3.0 0.3 100.0 50.0M 155 国产3CA2E 硅PNP 3.0 0.3 130.0 50.0M 155 国产3CA2F 硅PNP 3.0 0.3 150.0 50.0M 155 国产3CA3 硅PNP 5.0 0.5 30.0 30.0M 155 国产3CA3A 硅PNP 5.0 0.5 30.0 30.0M 155 国产3CA3B 硅PNP 5.0 0.5 50.0 30.0M 155 国产3CA3C 硅PNP 5.0 0.5 80.0 30.0M 155 国产3CA3D 硅PNP 5.0 0.5 100.0 30.0M 155 国产3CA3E 硅PNP 5.0 0.5 150.0 30.0M 164 国产3CA3F 硅PNP 5.0 0.5 200.0 30.0M 164 国产3CA4 硅PNP 7.5 0.8 30.0 30.0M 155 国产3CA4B 硅PNP 7.5 0.8 50.0 30.0M 164 国产3CA4C 硅PNP 7.5 0.8 80.0 30.0M 164 国产3CA4D 硅PNP 7.5 0.8 100.0 30.0M 164 国产3CA4E 硅PNP 7.5 0.8 130.0 30.0M 164 国产3CA4F 硅PNP 10.0 1 120.0 30.0M 155 国产3CA5 硅PNP 15.0 1.5 30.0 30.0M 155 国产3CA55A 硅PNP 5.0 0.5 15.0 300M 164 国产3CA55B 硅PNP 5.0 0.5 15.0 500M 164 国产3CA5A 硅PNP 15.0 1.5 30.0 30.0M 155 国产3CA5B 硅PNP 15.0 1.5 50.0 30.0M 155 国产3CA5D 硅PNP 15.0 1.5 100.0 30.0M 155 国产3CA5E 硅PNP 15.0 1.5 130.0 30.0M 155 国产3CA5F 硅PNP 15.0 1.5 120.0 30.0M 155 国产3CA6A 硅PNP 20.0 2 40.0 30.0M 155 国产3CA6B 硅PNP 20.0 2 40.0 30.0M 155 国产3CA6C 硅PNP 20.0 2 60.0 30.0M 155 国产3CA6D 硅PNP 20.0 2 80.0 30.0M 155 国产3CA6F 硅PNP 20.0 2 120.0 30.0M 155 国产3CA72A 硅PNP 2.0 0.3 15.0 500M 164 国产3CA72B 硅PNP 2.0 0.3 15.0 700M 164 国产3CA80 硅PNP 0.1 0.3 15.0 300M 178 国产3CA9E 硅PNP 75.0 7.5 120.0 20.0M 165 国产。

基本参数 特性雷达、非标光学高精度超薄（10-15mm）多种孔径可选（mm）：6/20/30/40/50/9025bit分辨率标准接口：SSI、BiSS、RS485、MODBUS-RTU 高防护等级一体化结构无需二次安装校准简易安装外径/内径: 130mm / 90mm测量范围 : 0°- 360°分 辨 率 : 25bit（Max）精 度 : ≤±20″重复精度 : ≤±2″通讯协议 : RS485自由协议/Modbus-RTU/SSI/BISS-C 接 口 : RS485/RS422电压/电流: DC5V / 50mA（Max）码 制 : 二进制、格雷码工作温度 : -40℃ - +65℃储存温度 : -55℃ - +85℃抗 冲 击 : 20g、200Hz抗 振 动 : 5g、8-2000Hz 相对湿度 : ≤90%、无结露防护等级 : IP54工作转速 : 4000RPM（Max）重 量 : 0.44KGT型 产品装配图Y型 产品装配图通讯形式：定时发送波特率：2MB/s、921.6KB/s、115.2KB/s、57.6KB/s、9.6KB/s 更新率：10KHz、 4KHz、 1KHz、 0.5KHz、 0.1KHz 数据格式：起始位1bit、 数据位8bit 、停止位1bit 、无校验位数据帧说明：自由协议(RS485接口)：数据说明：主站角度数据读取(站号01)：主站设置编码器波特率（站号01，波特率设定为115200）：设置成功从站响应数据：从站响应位置数据：2134角度数据高八位。

角度数据中八位。

角度数据低八位。

帧头和角度数据的校验和，取低八位。

注：角度换算：以16位及以下数据为例，角度=（Byte3*256+Byte4）/2n �，n为编码器位数，为提高数据可靠性，需对帧头和校验位判断通讯形式：总线命令波特率： 115.2KB/s、57.6KB/s、19.2KB/s、9.6KB/s（默认19.2KB/s）数据帧格式：起始位1bit、 数据位8bit 、停止位1bit 、无校验位注： 波特率 115.2KB/s、57.6KB/s、19.2KB/s、9.6KB/s时序图：时序图：P OSITION:编码器位数。

三键多士炉专用芯片CMS12530功能说明书CMS12530是一块用于多士炉系列产品的专用集成电路。

CMS12530可以通过调节外部振荡电阻来控制多士炉的加热时间。

除正常模式外，CMS12530可以通过DEFROST键和REHEAT键实现解冻和再加热功能。

一、 管脚说明：(DIP8)脚位 功 能PIN1 DEFROST（解冻）输入及LED指示PIN2 REHEAT（再热）输入及LED指示PIN3 电源自锁线圈控制输出PIN4 VDDPIN5 振荡控制1PIN6 振荡输入PIN7 振荡控制2PIN8 VSS二、主要参数指标：参 数 测试条件符 号最小值 典型值 最大值 单 位 工作电压VDD 4 5 5.5 V 高电平输出电压 VDD=5V(无负载) Voh 4.5V 低电平输出电压 VDD=5V(无负载) Vol 0.5 V 输出口高电平输出电流 VDD=5V(Voh=3.5V) Ioh 5 mA 输出口低电平输出电流 VDD=5V(Vol=1.5V)Iol 5 mA 0℃ VDD=5V t 30 S 25℃ VDD=5V t 30 S 50℃ VDD=5V t 30 S 不同温度下定时稳定性（定时时间为30S ） 85℃ VDD=5V t 30 S 0℃ VDD=5V t 60 S 25℃ VDD=5V t 60 S 50℃ VDD=5V t 60 S 不同温度下定时稳定性(定时时间为60S) 85℃ VDD=5V t 61 S 0℃ VDD=5V t 200 S 25℃ VDD=5V t 200 S 50℃ VDD=5V t 201 S 不同温度下定时稳定性(定时时间为200S)85℃VDD=5V t 202 S 工作温度 Top 0 85 ℃ 贮存温度Tst-20105℃三、功能说明：1、控制面板示意图：2、功能描述：芯片通电开始工作，输出口输出高电平控制电磁铁自锁，多士炉持续工作。

当定时时间到后，输出口输出低电平，电磁铁释放，电源回路断开，多士炉停止工作。

DESCRIPTIONThe SM5K3/5K4/5K5 are CMOS 4-bit single-chip microcomputers incorporating 4-bit parallel pro-cessing function, ROM, RAM, 10-bit A/D converter and timer/counters.It provides three kinds of interrupts and 4 levels subroutine stack. Being fabricated through CMOS process, the chip requires less power and available in a small package : best suitable for Low power controlling, compact equipment like a precision charger.FEATURES• ROM capacity : 2 048 x 8 bits• RAM capacity : 128 x 4 bits• Instruction sets : 50• Subroutine nesting : 4 levels• I/O port :Input8Output4Input/output12 (36QFP/32SOP)11 (30SDIP)8 (28SOP)• Interrupts :Internal interrupt x 1 (timer)External interrupt x 2 (2 external interruptinputs)• A/D converter :Resolution10 bitsChannels4• Timer/counter : 8-bit x 1• Built-in main clock oscillator for system clock Ceramic/crystal oscillator (SM5K3/5K5)CR oscillator (SM5K4)• Signal generation for real time clock∗(SM5K3/5K5)• Built-in 15 stages divider(for real time clock∗: SM5K3/5K5)• Instruction cycle time :1 µs (MIN.) (2 MHz, at 5 V ±10%) (SM5K3/5K5)2 µs (MIN.) (1 MHz, at 2.2 to 5.5 V) (SM5K3/5K5)1 µs (MIN.) (1.67 MHz ±20%, at 5 V ±10%) (SM5K4)• Large current output pins (LED direct drive) : 15mA (TYP.)x 4 (sink current)• Supply voltages:2.2 to 5.5 V (SM5K3/5K5)2.7 to 5.5 V (SM5K4)• Packages :30-pin SDIP (SDIP030-P-0400)32-pin SOP (SOP032-P-0525)36-pin QFP (QFP036-P-1010)28-pin SOP (SOP028-P-0450) (SM5K3/5K5)24-pin SSOP (SSOP024-P-0275) (SM5K4)∗In case of using crystal oscillatorSM5K3/SM5K4 SM5K54-Bit Single-Chip Microcomputers (Controllers With 10-Bit A/D Converter)In the absence of confirmation by device specification sheets, SHARP takes no responsibility for any defects that may occur in equipment using any SHARP devices shown in catalogs, data books, etc. Contact SHARP in order to obtain the latest device specification sheets before using any SHARP device.NomenclatureA : A registerA/D : A/D converter unitALU : Arithmetic logic unitB M, B L: RAM address registerC : Carry flagIFA, IFB, IFT : Interrupt request flagIME : Interrupt master enable flag INST. DEC. : Instruction decoder INT : Interrupt control unit P0-P5 : Port registerP U, P L: Program counterR8, R9, RC, RE, RF : Mode registerRA : Count registerRB : Modulo registerSB : SB registerSR : Stack registerRECOMMENDED OPERATING CONDITIONSNOTES :• The typical oscillation frequency shall be determined in consideration of operating condition and fluctuation frequency.• Mount Rf, RD, C 1, C 2, Oscillator (SM5K3/5K5)/Rf (SM5K4)as close as possible to the oscillator pins of the LSI, in order to reduce an influence from floating capacitance.• Since the value of resistor Rf, RD, C 1, C 2, Oscillator (SM5K3/5K5)/Rf (SM5K4) varies depending on circuit pattern and others, the final Rf, RD, C 1, C 2, Oscillator (SM5K3/5K5)/Rf (SM5K4) value shall be determined on the actual unit.• Don't connect any line to OSC IN and OSC OUT except oscillator circuit.• Don't put any signal line across the oscillator circuit line.• On the multilayer circuit, do not let the oscillator circuit wiring cross other circuit.• Minimize the wiring capacitance of GND and V DD .OSCILLATION CIRCUITDegree of fluctuation frequency : ±20%OSC OUTOSC INRf = 33 k Ω(fosc = 1.67 MHz, TYP.)• SM5K3/5K5∗Reference only : Circuit configuration varies according tooscillator used.• SM5K4C 2NOTES :1. Applicable pins : P12, P13, P20-P23, P30-P33(digital inputmode), P40-P43P50-P532. Applicable pins : OSC IN , RESET, P10, P113. Applicable pins : RESET, P10-P13, P20-P23, P40-P43,P50-P53 (digital input mode)4. Applicable pins : P30-P33(analog input mode)03(high current mode)6. Applicable pins : P20-P23, P40-P43, P50-P53(output mode)∗17. Applicable pins : P30-P33∗28. No load (A/D conversion is stop.)9. A/D conversion in operation (operation enable)10. A/D conversion in stop (operation disable)∗1 In case of 32-pin SOP and 36-pin QFP.(In case of 30-pin SDIP, P52dose not exist. In case of 28-pin SOP, P50-P53do not exist.)∗2 P3 ports are normally used for input ports with pull-up resistor. These ports can be also used.V IH10.8 x V DDV DDV 1V IL100.2 x V DDV IH20.9 x V DDV DDV 2V IL200.1 x V DDV DD = 2.2 to 3.3 V 22590I IL1V IN = 0 V V DD = 4.5 to 5.5 V 2570250µA 3I IH1V IN = V DD 2I IL2V IN = 0 V 1.010µA4I IH2V IN = V DD 1.010V DD = 2.2 to 3.3 V 515I OL1V O = 1.0 V V DD = 4.5 to 5.5 V 1525mA 5V DD = 2.2 to 3.3 V 0.3 1.5I OH1V O = V DD – 0.5 V V DD = 4.5 to 5.5 V 1.0 2.2V DD = 2.2 to 3.3 V 1.2 5.0I OL2V O = 1.5 V V DD = 4.5 to 5.5 V 59.0mA 6V DD = 2.2 to 3.3 V 0.3 2.0I OH2V O = V DD – 0.5 V V DD = 4.5 to 5.5 V 1.0 2.4V DD = 2.2 to 3.3 V 0.15I OH3V OH = V DD – 1.0 V mA7V DD = 4.5 to 5.5 V 0.5f OSC = 2 MHZ V DD = 4.5 to 5.5 V 1 200 2 500V DD = 2.2 to 3.3 V 300800f OSC = 1 MHzI DDV DD= 4.5 to 5.5 V 600 1 200f OSC = 32.768 kHzV DD= 2.2 to 3.3 V 20120(Crystal OSC mode)f OSC = 2 MHzV DD = 4.5 to 5.5 V 760 1 500V DD= 2.2 to 3.3 V 200600µA8f OSC = 1 MHzI HLT V DD = 4.5 to 5.5 V 400900f OSC = 32.768 kHzV DD= 2.2 to 3.3 V 2075(Crystal OSC mode)Ceramic OSC mode V DD= 2.2 to 3.3 V 2I STOP f OSC = 32.768 MHzV DD= 2.2 to 3.3 V 1540(Crystal OSC mode)A/D in operation V DD = 4.5 to 5.5 V 220450µA 9I VRA/D in stopV DD = 4.5 to 5.5 V 2µA 10Resolution 10bit Differential f OSC = 1 MHzV DD= VR = 5.0 V ±2.5±4.0linearity error T OPR = 25°CSequential f OSC = 1 MHzV DD = VR = 5.0 V ±3.2±5.0LSB linearity error T OPR = 25°Cf OSC = 1 MHzTotal error V DD= VR = 5.0 V±4.0±6.0TOPR = 25°CA/D conversion Input voltage Input currentOutput currentSupply cerrentDC CHARACTERISTICS• SM5K3(T OPR = –20 to +70°C, TYP. value : V DD = 5.0 or 3.0 V, Unless otherwise noted.)PARAMETER SYMBOLCONDITIONSMIN.TYP.MAX.UNIT NOTE1. Applicable pins:P12, P13, P20-P23, P30-P33(digital inputmode), P40-P43, P50-P53∗12. Applicable pins:OSC IN0, P113. Applicable pins:RESET, P10-P13, P20-P23, P40-P43,P50-P53(digital input mode)∗14. Applicable pins:P30-P33(analog input mode)5. Applicable pins:P00-P03(high current output)6. Applicable pins:P20-P23, P40-P43, P50-P53(output mode)∗17. Applicable pins:P30-P33∗29. A/D conversion in operation (A/D conversion enable)10. A/D conversion in stop (A/D conversion disable)∗1 In case of 32-pin SOP and 36-pin QFP.(In case of 30-pin SDIP, P52pin dose not exist. In case of 24-pin SSOP, P12, P13, P33, P50-P53pins do not exist.)∗2 P3 ports are normally used for input port with pull-up resistor. These ports can be also used as a suspected case of output port.Data Memory (RAM)The data memory (RAM) is used to store data upFig. 3 B Register and SB RegisterFig. 4 RAM File and WordB Register and SB Register• B register (B M , B L )The B register is an 8-bit register that is used to specify the RAM address. The upper 4-bit section is called B M register and lower 4-bit B L .• SB registerThe SB register is an 8-bit register used as the save register for the B register. The contents of B register and SB register can be exchanged throughEX instruction.The program counter PC specifies the ROM address. The PC consists of 12-bit as shown in Fig. 5 : The upper 6-bit (P U ) represents a page while the lower 6-bit (P L ) denotes a step. The P U section is a register and the P L section, a binary counter.Execution of interrupt handling and the table reference instruction PAT also automatically uses 1stage of the stack register SR.Program Memory (ROM)The ROM is used to store the program. The capacity of the ROM is 2 048-step (32-page by 64-step. See Fig. 6). The configuration of the ROM and program jumps are illustrated in Fig. 7.Fig. 6 Page and Step for ROMFig. 5 Program Counter PC and Stack Register SRProgram Counter PC and Stack Register SRFig. 7 ROM Configuration and Program Jump ExampleOutput Latch Register and Mode RegisterThe SM5K3/5K4/5K5 contain 6 output-latch registers and 8 mode-registers which either latch contents of output ports or control some functions of the SM5K3/5K4/5K5.These registers, their functions and available transfer instructions are shown in Table 1 below.An output latch register sets the output level of the pin to which it is connected.Refer to the section of “MODE REGISTERS”concerning about the details mode registers.Table 1 Output Latch Registers and Mode RegistersNOTE :Bit 4 (R84) in the R8 register is read only.(Read or write operation of this bit does not affect any other operation.)FUNCTIONAL DESCRIPTION Hardware Reset FunctionReset function initializes the SM5K3/5K4/5K5systems. When the input on the RESET pin goes Low, the system enters reset condition after 2level, the reset condition is removed as the inputpulse from OSC IN pin repeats 215times, forcing the program counter to start at 0 page and 0 address.Initialized status of the system immediately after resetting is shown below.Reset causes the following changes.1) I/O pins are set input.2) All mode registers are reset.3) Output latch register P0 is reset, causing P00to P03pins go High level.4) Interrupt request flags (IFA, IFB, and IFT),interrupt master enable flag (IME) are reset,disabling all interrupts.Standby FeatureThe standby function saves power by stopping the program whenever it is not necessary to run. The mode in which the microcomputer is executing the program is called the run mode and the mode in which it stops the program is called the standby mode. Standby mode is further divided into two modes : stop mode and halt mode, one of which is selected by halt instruction or stop instruction. Upon removal of standby condition, the SM5K3/5K4/5K5return from the standby mode to the normal run mode. To enter the standby mode, select either stop mode or halt mode whichever is appropriate (Fig. 8).∗The content of the bit R84 is undefined because it is read only.• Blocks stopped during standby modeIn the halt modeThe system clock generating circuit stops during the halt mode, deactivating all the blocks driven by the system clock. The main clock and dividers remain active. This means that timers can be used while in the halt mode. Both internal and external clocks can be used as the count clock.In the stop modeThe main clock and system clock stop upon entering the stop mode. Therefore, only timers using the external clock remain active.• Counters that the system retains during standby modeThe contents that will be retained in the halt mode will also be retained in the stop mode. These items are shown in Table 3.Fig. 8 Operation Shift of Program• Releasing events of standby mode (6-type)• Interrupt used with SM5K3/5K4/5K5Interrupt event occurs on the falling edge of P10or P11pin input, or the overflow at the timer. These events set flags IFA, IFB and IFT respectively, that then serve as interrupt request flag.Table 4 shows interrupt handling priority level and jump address.• Usage of halt mode and stop modeThe system returns back to the normal operation mode upon occurring of a standby mode releasing condition. The halt mode should be used when the system must enter and exit normal operation frequently as in the case of key operation.The halt mode should also be used to keep timers that are operating from the internal clock, while in the standby mode.The stop mode further saves power than the halt mode but requires slightly longer time to return tothe normal mode. Therefore, the stop mode should be used when the system will not be required to return to the normal mode in a short time.Interrupt FeatureThe interrupt block consists of mask flags (bits RE0,RE1 and RE2), IME flag and interrupt request handling circuit. Fig. 9 shows the configuration of the interrupt block.Fig. 9 Interrupt Block Diagram• IME flag (master enable flag)The IME enables or disables all interrupts at the same time. The IE command, when executed, sets the IME flag and enables the interrupt specified by the mask flag setting. The ID command resets the IME flag, disabling process of any interrupt request.Setting the IME flag to reset after releasing hardware reset, all interrupts are inhibited.• Mode register RE (interrupt mask flag)The mode register RE (RE0, RE1 and RE2;interrupt mask flag) individually enables or disables three type of interrupts.Timer/CounterThe SM5K3/5K4/5K5 have a pair of built-in timer/counter. The timer/counter are used to handle periodic interrupts and to count. The overflowing timer can be used to disable the halt mode. The timer/counter serve as interval timer.The timer/counter consists of an 8-bit count register RA, modulo register RB (for counter initial value setting), 15-bit divider and 4-bit mode register RC (for count clock selection). The configuration of the timer/counter is shown in Fig. 10.Fig. 10 Configuration of Timer/Counter• Selecting count clockA count clock is selected by the bit settings in the mode register RC.Table 5 Count Clock SelectionA/D CONVERSION MODEIn the A/D conversion mode, the converter converts the analog input voltage to the digital value. The analog input voltage is successively compared with the internal voltage charged on the weighted capacitor array until its digital equivalent is determined. The resultant digital data is stored into the mode registers R8 and R9.The conversion requires 152.5 µs (main clock at 400 kHz/system clock at 5 µs) or 1.86 ms (main clock at 32.768 kHz/system clock at 61 µs).COMPARISON MODEIn the comparison mode, the analog voltage from one of P30to P33pins is compared, in amplitude, with internally generated voltage whose value is set by the mode registers R8 and R9. The result data of the comparison is saved into the bit 4 (bit R84) position of the mode register R8. The comparison cycle lasts 62.5 µs (main clock at 400 kHz, system clock at 5 µs) or 763 µs (main clock at 32.768 kHz/system clock at 61 µs).A/D ConversionThe SM5K3/5K4/5K5 are provided with a built-in 10-bit A/D converter having 4-channel multiplexer analog inputs. The A/D converter operates in A/D conversion mode and comparison mode. In the A/D conversion mode, the converter converts the analog input from the P3 pin to the digital value; and in the comparison mode, it compares the input analog amplitude with that of a reference voltage set inside the SM5K3/5K4/5K5. The P30to P33 pins can be used as analog voltage inputs. One or more of these 4 inputs can be set to assume A/D pin by the bit operation of the mode register R3. One of these A/D pins is further set as analog input by the bit operation of the mode register R8. The A/D converter is controlled by the bits set in the mode register R8. For details of the mode register R8, refer to " MODE REGISTERS R8 ". Configuration of the A/D converter is illustrated in Fig. 11.CAUTIONS• Keep the A/D converter reference voltage on the VR pin equal to or below V DD.• Do not apply the voltage to the VR pin before V DD is applied.• Connect AGND to GND.Fig. 11 A/D Converter Block DiagramMODE REGISTERSThe registers which control functions of the SM5K3/5K4/5K5 and which serve as counter/timer are commonly referred to as “mode registers”. In the SM5K3/5K4/5K5, R8 to RB are 8-bit mode registers;and R3, RC, RE and RF are 4-bit mode registers.To set data into the mode registers, the OUT command is used; and to check the contents of the mode registers IN command is used.R3 (A/D pin selection register)Any pin on 4-pin port P3 can be set accommodate analog voltage (hereafter called A/D pin).Bit i (i = 3 to 0)Sets P3i pin to either general purpose input or A/D pin0 | (General purpose) input 1 | A/D inputR8 (A/D conversion control & A/D data register)An 8-bit register used to control A/D conversion and storing part of A/D conversion result. It also stores the results of comparison.Bits 7 to 6Storage of A/D conversion result (A/D conversion mode) and setting of internal voltage (comparison mode)• Use as part of a 10-bit data ragister in combination with mode register R9.• Bit R86 is the LSB.• Store lower 2-bit of converted data in A/D conversion mode.• Use as lower 2-bit of internal voltage setting data in comparison mode.Bit 5∗A/D operation enable/disable flag 0 | Disable (A/D power source off)1 | Enable (A/D power source on)Bit 4Storages of comparison result (read only)0 | P3i pin voltage < internal setting voltage 1 | P3i pin voltage > internal setting voltage(i = 3 to 0)Bit 3∗S/R flag (start/clear)0 | End of operation (or stop)1 | Start of operation (or in operation)Bit 2Operation mode selection 0 | A/D conversion 1 | Comparison Bits 1 to 0Select one of A/D pins as A/D conversion 00 | P3001 | P3110 | P3211 | P33R9 (A/D data register)The register to store the upper 8-bit of 10-bit data resulting from A/D conversion.Bit 7Bit i (i = 7 to 0)Storages of A/D conversion result (A/D conversion mode) and setting of internal voltage (comparison mode)• Uses as part of a 10-bit data register in combination with mode register R8.• Bit R97 is the MSB.• Stores upper 8-bit of A/D conversion result.• Uses as upper 8-bit of internal voltage setting data in comparison mode.∗When operation is end, these bits are cleared.∗Select one pin which is to be selected by mode register R8.RA (Count register)Bit i (i = 7 to 0)Count clock input register• Uses as counter part of timer/counter (count clock input).• Loads the content of RB to RA when the RAoverflows or when OUT command (B L = 0A H )is executed.RA ←RB• Loads the content of RA to X and A registers upon execution of IN command (B L = 0A H ).(X, A)←RA• Bit 7 = MSB, bit 0 = LSBRB (Modulo register)Bit i (i = 7 to 0)Count initial value storage register• Uses as modulo register of timer/counter • Loads the content of RB to X and A registers upon execution ofIN command (B L = 0B H ) : X = upper bits,A = lower bits.(X, A)←RB• Loads the contents of X and A registers to RB upon execution ofOUT command (B L = 0B H ) :X = upper bits,A = lower bits.RB ←(X, A)• Bit 7 : MSB, Bit 0 : LSBRC (Timer control)Bit 3Starts up count of the timer.0 | Stop 1 | StartBit 2 (Unused)Bits 1 to 0Select the source clock to the timer.00 | f SYS (system clock)01 | f SYS /2710 | f SYS /21511 | Falling edge input on P11pinRE (Interrupt mask flag)Bit 3Bit 3 (Unused)Bit 2Removes overflow interrupt from timer or standby condition.0 | Disable 1 | Enable Bit 1Interrupts on the falling edge of input from P11 pin,or releases of standby mode by the Low input from P11pin.0 | Disable 1 | Enable Bit 0Interrupts on the falling edge of input on P10pin, or releases of standby mode by the Low input from P10pin.0 | Disable 1 | EnableRF (P2 port direction register)Bit 3Bit i (i = 3 to 0)Selection of input pin/output pin 0 | Set P2i pin to input.1 | Set P2i pin to output.I/O PortsThe SM5K3/5K4/5K5 have 24 ports : 8-input, 4-output and 12-I/O port. To verify the input, use suitable instruction to transfer the input on the pin directly to the A register. To select the output latch register to which the content of the A register is to be transferred, and to select the input port from which the signal or data is to be transferred to the A register, use the B L register. For details of B L settings and associated ports, refer to Table 1.• Port P00to P03(CMOS inverting output port) The data transfers in 4-bit string (use OUT or OUTL instruction) or in unit of 1-bit (use ANP or ORP instruction).• Port P10to P13(input port with pull-up resistor) The data transfers in unit of 4-bit. This port can be used as standby/external interrupt input or count pulse input. The P1 port can also be used as a standby release port without requiring specific setting on P12and P13pins. Pins P10and P11 require settings through the mode resister RE. When using the P1 port as an external interrupt input, use pins P10and P11with suitable settings in the mode register RE. When using the P1 port as the count pulse input, use P11pin.• Port P20to P23(I/O port with pull-up resistor) Each bit can be independently be set its direction and can be transferred independently or in combination of other 3-bit. The direction of the bits is determined by the RF register. After reset, the P2 port is set input.• Port P30to P33(input port with pull-up resistor) The data transfers in unit of 4-bit. The port can also be used as A/D analog voltage input. To use the P3 port as the A/D port, set the mode register R3.• Port P40to P43(I/O port with pull-up resistor) The data transfers in unit of 4-bit.When set output, content of each bit can be set. Executing the input instruction (IN) sets the P4 ports (P40to P43) to input; and executing output instruction (OUT, ANP or ORP) sets the port to output. After reset, the P4 port is set input.• Port P50to P53(I/O port with pull-up resistor) The data transfers in unit of 4-bit.When set output, content of each bit can be set. Executing the input instruction (IN) sets the P5 ports (P50to P53) to input; and executing output instruction (OUT, ANP or ORP) sets the port to output. After reset, the P5 port is set input.FlagsThe SM5K3/5K4/5K5 have 4 flags (C flag and interrupt request flags [IFA, IFB, IFT] ), which are used to perform setting and judgments.• DividerThe divider consists of 15 divided-by-two dividers,providing 2 (f SYS /27, f SYS /215) of 4 count clocks that are fed to the counter RA from the system clock.Its configuration is shown below. The divider can be cleared by using the DR instruction.• Oscillator mask optionSelection of type of oscillator, ceramic or crystal, is made by mask option.Fig. 12 Main Clock and System ClockFig. 13 System Clock Generator and DividerSystem Clock Generator and Dividers• System clock generatorThe system clock is the divided-by-two main clock applied through OSC IN and OSC OUT (See Fig. 12).The system clock generator is shown in Fig. 13.One system clock cycle period is equal to one instruction execution time when the instruction consists of 1 word. When the ceramic oscillatorruns at 400 kHz, the system clock fsys is 200 kHz.This means that the instruction execution time is 5µs/word. Using a 32.768 kHz crystal oscillator generates 16.384 kHz fsys and the instruction execution time is 61 µs/word. The system clock can be used as count input pulse to the timer.INSTRUCTION SET Array Definition of SymbolsM: Content of RAM at the address defined by the B register.←: Transfer direction∪: Logical OR∩: Logical AND⊕: Exclusive ORAi: An i bit of A register (i = 3 to 0)Push: Saves the contents of PC to stack register SR.Pop: Returns the contents saved in the stack register back to PC.Pj: Indicates output latch register or input register. Pj ( j = 0, 1, 2, 3, 4, 5)Rj: Mode register. Rj register ( j = 3, A, B, C, E, F)ROM ( ) : Content stored in ROM location defined by the value in ( ).CY: Carry in ALU (independent of C flag) The CY(carry) is a signal which isgenerated when the ALU has beencarried by the execution of a command.It is different from the C flag.X: Used to represent a group of bits in the content of a register or memory. Forexample, the X in the LDAX instructiondenotes the lower 2 digits (I1and I0) of Aregister.• A bit in a register is affixed to the register symbol, e.g. a bit (i = 0, 1, 2, 3....) of X register is expressed as Xi and P (R) register as P (R) i.• Increment means binary addition of 1H and decrement addition of F H.• Skipping an instruction means to ignore that instruction and to do nothing until starting the next instruction. In this sense, an instruction to be skipped is treated as an NOP instruction. Skipping 1-byte instruction requires 1-cycle, and 2-byte instruction 2-cycle. Skipping 1-byte 2-cycleinstruction requires 1-cycle.SYSTEM CONFIGURATION EXAMPLE • Charger controller。

1产品规格书Production Specification客户名称（Customer name）：产品名称（Production name）：3535IR 型号（Model）：M3535E1IRS9G12-850编号（Part number）：日期（Date）：客户确认CUSTOMER CONFIRMATION确认Confirmed by审核Checked by核准Approved by备注：请检测后签回贵司的宝贵意见，谢谢支持！Note:please sign back your valuable comments after testing,thank you for your support!2目录Catalog1.特性（Features ）2.应用范围（Applications ）3.成品外观尺寸（Package Dimensions ）4.最大额定值（Maximum rating）5.光电特性参数（Electro-optical characteristics ）6.典型光电参数曲线（Typical optical characteristics curves ）7.BIN 级参数（Bin sorting parameters）8.编带规格（Tape Specification ）9.包装方式（Packaging ）10.标签描述（Label description ）11.可靠度实验项目及条件（Reliability Test Items And Conditions ）12.使用注意事项（Use of caveats ）31.特性（Features ）◆封装尺寸3.5*3.5*2.5/1.67mm ◆采用陶瓷基板封装Encapsulation Size Ceramic substrate encapsulation ◆焊接方式：回流焊◆符合RoHS 标准Welding Method:Reflow soldering Compliance with RoHS standards ◆采用高可靠性封装能量稳定◆体积小、功耗低、指向性好High reliability packaging energy stabilizationSmall size,low powerconsumption,good directivity2.应用范围（Applications ）◆摄像头（视频拍摄）数位摄影，监控，美容，治疗皮肤病等Camera (video shooting),digital photography,surveillance,beauty,treatment of skin diseases,etc◆楼寓对讲，防盗报警，红外防水，非视觉光源等Building intercom,burglar alarm,infrared waterproof,non visual light source,etc3．成品外观尺寸（Package Dimensions）备注：1.所有尺寸单位均以mm 单位.Remarks:All units of size in mm units.2.在没有明确标注的情况下正负公差为0.1mmA positive and negative tolerance of 0.1mm without a clear indication.44.最大额定值（Maximum rating）(Ta=25℃)项目Project 缩写Symbol 额定值Rating 单位Unit 峰值正向电流Peak forward currentIFP 1000mA 光功率Optical power IV 450mW 反向电压Reverse voltageVR 5V 漏电流Leakage currentIR 10µA 工作温度working temperatureTopr –40～85℃存储温度Storage temperatureTstg 5～30℃焊接温度welding temperatureTsld回流焊240℃不超过30sReflow soldering 240℃not more than 30s手动焊接300℃不超过3sManual welding at 300℃for no more than 3S℃ESD 等级（HBM)ESD 4000V（脉冲宽度≤10ms,占空比≤0.1）（Pulse width ≤10ms,duty cycle ≤0.1）5.主要光电参数（Electro-optical characteristics ）(Ta=25℃)项目Project 符号Symbol 测试条件（mA）Test conditions最小值Min 典型值Typ 最大值Max 单位Unit 正向电压Forward voltageVF IF=350mA1.4-2.0V 正向电流Forward currentIF --7001000mA 光功率Optical power IV --450-mW 发光角度Viewing Angle2θ½IF=350mA -120°波长Peak wavelengthλp IF=350mA 845850855nm 热阻Thermal resistanceRIF=350mA- 4.5-℃/W56.曲型光电参数曲线（Typical optical characteristics curves ）Relationship between voltage and currentRelationship between current and opticalpowerThe relationship between current and power Relationship between current and peakwavelengthLuminous angle Spectralwavelength67.BIN 级参数（Bin sorting parameters）(1)正向电压Forward voltage VF(公差tolerance ：±0.05V@IF=350mA)8.编带规格（Tape Specification ）：800PCS/卷(800pcs /Reel)最小值min(V)最大值max(V)1.62.02.0 2.22.22.479.包装方式（Packaging）10.标签描述（Label description ）Please use 70-75degree dehumidification for more than 15hours.Please sub contract the light splitting products,thank you!深圳市银月光科技有限公司P/N:WL:Φe ：IF:VF:Lot ：Qty ：请使用70-75度除湿，时间15小时以上。

LGA1700 / 1200 / 115X / 1366IntelACCESSORY KITCaution:Applying too much thermal paste will lower heat conductivity and cooling performance!E LGA1700SPECIFICATIONSFORZA 135Product Name CPU SocketIntel Socket LGA 115X / 1366 / 1200 / 1700 / 2011 / 2066(Core i3 / i5 / i7 / i9 CPU)AMD AM5 / AM4 / FM2 / FM1 / AM3+ / AM3 / AM2+ / AM2 CPU产品规格 , 產品規格零件包 , 零件包产品名称 , 產品名稱支援 CPU 插座类型 , 支援 CPU 插座類型注意：散热膏涂抹过多会降低热传导性能与散热效能。

注意：散熱膏塗抹過多會降低熱傳導性能與散熱效能。

Forza 135零件包多附一组风扇扣具可支援所有品牌的120mm风扇，建议您可安装第三个风扇以提升Forza 135的散热效能。

我们推荐您另外购买COUGAR MHP 120风扇以达到最佳散热表现。

Forza 135零件包多附一組風扇扣具可支援所有品牌的120mm風扇，建議您可安裝第三個風扇以提升Forza 135的散熱效能。

我們推薦您另外購買COUGAR MHP 120風扇以達到最佳散熱表現。

Made in ChinaLEGAL NOTICESThis manual was created by Compucase Enterprise and may not be completely or partially copied, passed on, distributed or stored without written consent by Compucase Enterprise.COUGAR® is a registered brand of Compucase Enterprise Other product and company names mentioned in this documentation may be brands or trademarks of their respective owners.Compucase Enterprise reserves the right to make changes concerning the contents of the manual and the technical data of the product without previous announcement.GLOBAL WARRANTY POLICYWARRANTY PERIODS OF COUGAR GAMING DEVICES Product : COUGAR Forza 135 single tower air cooler Warranty : 2 YearsThis warranty gives you specific legal rights. You may also have other rights granted under local law. These rights may vary.MANUFACTURER CONTACTCompucase Enterprise Co.,Ltd.All rights reserved.COUGAR USA Technical Service Tel: (833) 256-3778Mail:********************Official websiteOOAOOAForza 135 comes with an additional set of fan clips that allows for a third 120 mm fan of any brand to increase the heat dissipation efficiency of the Forza 135.To maximize the performance,we recommend a third COUGAR MHP 120 fan (sold separately).WARRANTY AGREEMENTIf the product has defects in material or manufacture, COUGAR will provide product repair and replacement service within the warranty period.Our warranty service is based on the date of the invoice or warranty card (must be affixed with the store stamp).Any fault or damage caused by natural disasters (including storm, fire, flood, thunder, earthquake, etc).Any fault or damage caused by accidental factors and man-made reasons (including hit, scrape, crash,moving, compression, stain, corrosion, use of incurred on unsuitable voltage, computer virus, riot, misuse,malicious damage, etc).Use in an improper operating environment (including high temperature, high humidity, water inflow, etc).Inability to provide the product warranty card, purchase receipt or invoice to prove the product is still within the warranty period and the shipping date of the product is out of warranty.The warranty card or product serial number has been altered or its number is hard to identify.The warranty period has expired.Any fault or damage caused by non-compliance with regulations stated on the user manual or improper, rough and careless treatment.Any fault or damage caused by use of parts not certified by COUGAR original manufacturer.The problem is caused by improper repair or adjustment by the buyer or any manufacturer without authorization from COUGAR.The product is not acquired from an authorized distributor of the company or is acquired from illicit sources.Paper carton, instruction and other accessories are not warranted.DISCLAIMERSCOUGAR product is not authorized for use as critical components in life support device or for incorrect application software or malfunction of the product.COUGAR is not liable for the death or damage of person or loss of property when product is using as,including but not limited to, medical equipment, military equipment, traffic equipment and disaster prevention system.COUGAR is not liable for any damages, expenses, lost data, lost revenues, lost savings, lost profits, or any incidental or consequential damages due to using defect product of COUGAR.COUGAR电竞产品保固期 , COUGAR電競產品保固期产品名称 , 產品名稱 : COUGAR Forza 135单塔散热器 , COUGAR Forza 135單塔散熱器保固期 , 保固期 : 2年 , 2年本保固条款赋予您特定的合法权利，而您所在的地区可能也会赋予您其他权利。