HX8802-C中文资料

Connection DiagramsDual-In-Line PackageDS010802-23Top ViewOrder Number COP882C-XXX/N,COP982C-XXX/N,COP882C-XXX/WM,COP982C-XXX/WM,COP982C-XXX/N or COP982CH-XXX/WMDual-In-Line Package (N)and 28Wide SO (WM)DS010802-5Top ViewOrder Number COP881C-XXX/N,COP981C-XXX/N,COP881C-XXX/WM,COP981C-XXX/WM,COP981CH-XXX/N or COP981CH-XXX/WMDual-In-Line PackageDS010802-4Top ViewOrder Number COP680C-XXX/N,COP880C-XXX/N,COP980C-XXX/N or COP980CH-XXX/NPlastic Chip CarrierDS010802-3Top ViewOrder Number COP680C-XXX/V,COP880C-XXX/V,COP980C-XXX/V or COP980CH-XXX/VFIGURE 2.Connection DiagramsCOP880C3COP980C/COP981C/COP982C Absolute Maximum Ratings (Note 1)If Military/Aerospace specified devices are required,please contact the National Semiconductor Sales Office/Distributors for availability and specifications.Supply Voltage (V CC )7V Voltage at any Pin−0.3V to V CC+0.3VTotal Current into V CC Pin (Source)50mA Total Current out of GND Pin (Sink)60mAStorage Temperature Range −65˚C to +140˚CNote 1:Absolute maximum ratings indicate limits beyond which damage to the device may occur.DC and AC electrical specifications are not ensured when operating the device at absolute maximum ratings.DC Electrical CharacteristicsCOP98xC;0˚C ≤T A ≤+70˚C unless otherwise specifiedParameterConditionMinTypMaxUnitsOperating Voltage 98XC 2.3 4.0V 98XCH4.06.0V Power Supply Ripple (Note 2)Peak to Peak0.1V CCVSupply Current CKI =10MHz V CC =6V,tc =1µs 6.0mA CKI =4MHz V CC =6V,tc =2.5µs 4.4mA CKI =4MHz V CC =4.0V,tc =2.5µs 2.2mA CKI =1MHz V CC =4.0V,tc =10µs1.4mA (Note 3)HALT Current V CC =6V,CKI =0MHz <0.78µA (Note 4)V CC =4.0V,CKI =0MHz <0.45µAInput Levels RESET,CKI Logic High 0.9V CCV Logic Low 0.1V CCVAll Other Inputs Logic High 0.7V CCV Logic Low 0.2V CC V Hi-Z Input Leakage V CC =6.0V−1.0+1.0µA Input Pullup Current V CC =6.0V,V IN =0V−40−250µA G Port Input Hysteresis 0.35V CCVOutput Current Levels D Outputs Source V CC =4.5V,V OH =3.8V −0.4mA V CC =2.3V,V OH =1.6V −0.2mA Sink V CC =4.5V,V OL =1.0V 10mA V CC =2.3V,V OL =0.4V2mAAll OthersSource (Weak Pull-Up)V CC =4.5V,V OH =3.2V −10−110µA V CC =2.3V,V OH =1.6V −2.5−33µA Source (Push-Pull Mode)V CC =4.5V,V OH =3.8V −0.4mAV CC =2.3V,V OH =1.6V −0.2Sink (Push-Pull Mode)V CC =4.5V,V OL =0.4V 1.6mAV CC =2.3V,V OL =0.4V 0.7TRI-STATE Leakage V CC =6.0V−1.0+1.0µA Allowable Sink/Source Current Per Pin D Outputs (Sink)15mA All Others3mAC O P 880C 4COP880C DC Electrical Characteristics(Continued)COP98xC;0˚C≤T A≤+70˚C unless otherwise specifiedParameter Condition Min Typ Max Units Maximum Input Current(Note5)Without Latchup(Room Temp)Room Temp±100mARAM Retention Voltage,Vr500ns Rise and(Note6)Fall Time(Min) 2.0VInput Capacitance7pFLoad Capacitance on D21000pFCOP980C/COP981C/COP982CNote2:Rate of voltage change must be less than0.5V/ms.Note3:Supply current is measured after running2000cycles with a square wave CKI input,CKO open,inputs at rails and outputs open.Note4:The HALT mode will stop CKI from oscillating in the RC and the Crystal configurations.Test conditions:All inputs tied to V CC,L,C and G ports TRI-STATEand tied to ground,all outputs low and tied to ground.Note5:Pins G6and RESET are designed with a high voltage input network for factory testing.These pins allow input voltages greater than V CC and the pins willhave sink current to V CC when biased at voltages greater than V CC(the pins do not have source current when biased at a voltage below V CC).The effective resistance to V CC is750Ω(typ).These two pins will not latch up.The voltage at the pins must be limited to less than14V.Note6:To maintain RAM integrity,the voltage must not be dropped or raised instantaneously.AC Electrical Characteristics0˚C≤T A≤+70˚C unless otherwise specifiedParameter Condition Min Typ Max Units Instruction Cycle Time(tc)Crystal/Resonator or External V CC≥4.0V1DCµs(Div-by10) 2.3V≤V CC≤4.0V 2.5DCµsR/C Oscillator Mode V CC≥4.0V3DCµs(Div-by10) 2.3V≤V CC≤4.0V7.5DCµsCKI Clock Duty Cycle(Note7)fr=Max4060%Rise Time(Note7)fr=10MHz Ext Clock12nsFall Time(Note7)fr=10MHz Ext Clock8nsInputst SETUP V CC≥4.0V200ns2.3V≤V CC≤4.0V500nst HOLD V CC≥4.0V60ns2.3V≤V CC≤4.0V150nsOutput Propagation Delay C L=100pF,R L=2.2kΩt PD1,t PD0SO,SK V CC≥4.0V0.7µs2.3V≤V CC≤4.0V 1.75µsAll Others V CC≥4.0V1µs2.3V≤V CC≤4.0V 2.5µs MICROWIRE™Setup Time(t UWS)20ns MICROWIRE Hold Time(t UWH)56ns MICROWIRE OutputPropagation Delay(t UPD)220nsInput Pulse WidthInterrupt Input High Time t CInterrupt Input Low Time t CTimer Input High Time t CTimer Input Low Time t CReset Pulse Width 1.0µsNote7:Parameter characterized but not production tested.5COP880C/COP881C/COP882C Absolute Maximum Ratings (Note 8)If Military/Aerospace specified devices are required,please contact the National Semiconductor Sales Office/Distributors for availability and specifications.Supply Voltage (V CC )7V Voltage at any Pin−0.3V to V CC+0.3VTotal Current into V CC Pin (Source)50mA Total Current out of GND Pin (Sink)60mAStorage Temperature Range −65˚C to +140˚CNote 8:Absolute maximum ratings indicate limits beyond which damage to the device may occur.DC and AC electrical specifications are not ensured when operating the device at absolute maximum ratings.DC Electrical CharacteristicsCOP88xC;−40˚C ≤T A ≤+85˚C unless otherwise specifiedParameterConditionMin TypMax Units Operating Voltage2.56.0V Power Supply Ripple (Note 9)Peak to Peak0.1V CCVSupply Current CKI =10MHz V CC =6V,tc =1µs 6.0mA CKI =4MHz V CC =6V,tc =2.5µs 4.4mA CKI =4MHz V CC =4.0V,tc =2.5µs 2.2mA CKI =1MHz V CC =4.0V,tc =10µs1.4mA (Note 10)HALT Current V CC =6V,CKI =0MHz <110µA (Note 11)V CC =3.5V,CKI =0MHz <0.56µAInput Levels RESET,CKI Logic High 0.9V CCV Logic Low 0.1V CCVAll Other Inputs Logic High 0.7V CCV Logic Low 0.2V CCV Hi-Z Input Leakage V CC =6.0V−2+2µA Input Pullup Current V CC =6.0V,V IN =0V−40−250µA G Port Input Hysteresis 0.35V CCVOutput Current Levels D Outputs Source V CC =4.5V,V OH =3.8V −0.4mA V CC =2.5V,V OH =1.8V −0.2mA Sink V CC =4.5V,V OL =1.0V 10mA V CC =2.5V,V OL =0.4V2mAAll OthersSource (Weak Pull-Up)V CC =4.5V,V OH =3.2V −10−110µA V CC =2.5V,V OH =1.8V −2.5−33µA Source (Push-Pull Mode)V CC =4.5V,V OH =3.8V −0.4mAV CC =2.5V,V OH =1.8V −0.2Sink (Push-Pull Mode)V CC =4.5V,V OL =0.4V 1.6mAV CC =2.5V,V OL =0.4V 0.7TRI-STATE Leakage V CC =6.0V−2.0+2.0µA Allowable Sink/Source Current Per Pin D Outputs (Sink)15mA All Others3mA Maximum Input Current (Note 12)Without Latchup (Room Temp)Room Temp±100mAC O P 880C 6COP880C DC Electrical Characteristics(Continued)COP88xC;−40˚C≤T A≤+85˚C unless otherwise specifiedParameter Condition Min Typ Max UnitsRAM Retention Voltage,Vr500ns Rise and(Note13)Fall Time(Min) 2.0VInput Capacitance7pFLoad Capacitance on D21000pFCOP880C/COP881C/COP882CNote9:Rate of voltage change must be less than0.5V/ms.Note10:Supply current is measured after running2000cycles with a square wave CKI input,CKO open,inputs at rails and outputs open.Note11:The HALT mode will stop CKI from oscillating in the RC and the Crystal configurations.Test conditions:All inputs tied to V CC,L,C and G ports TRI-STATEand tied to ground,all outputs low and tied to ground.Note12:Pins G6and RESET are designed with a high voltage input network for factory testing.These pins allow input voltages greater than V CC and the pins willhave sink current to V CC when biased at voltages greater than V CC(the pins do not have source current when biased at a voltage below V CC).The effective resistance to V CC is750Ω(typ).These two pins will not latch up.The voltage at the pins must be limited to less than14V.Note13:To maintain RAM integrity,the voltage must not be dropped or raised instantaneously.AC Electrical Characteristics−40˚C≤T A≤+85˚C unless otherwise specifiedParameter Condition Min Typ Max Units Instruction Cycle Time(tc)Crystal/Resonator or External V CC≥4.5V1DCµs(Div-by10) 2.5V≤V CC<4.5V 2.5DCµsR/C Oscillator Mode V CC≥4.5V3DCµs(Div-by10) 2.5V≤V CC<4.5V7.5DCµsCKI Clock Duty Cycle(Note14)fr=Max4060%Rise Time(Note14)fr=10MHz Ext Clock12nsFall Time(Note14)fr=10MHz Ext Clock8nsInputst SETUP V CC≥4.5V200ns2.5V≤V CC<4.5V500nst HOLD V CC≥4.5V60ns2.5V≤V CC<4.5V150nsOutput Propagation Delay C L=100pF,R L=2.2kΩt PD1,t PD0SO,SK V CC≥4.5V0.7µs2.5V≤V CC<4.5V 1.75µsAll Others V CC≥4.5V1µs2.5V≤V CC<4.5V 2.5µs MICROWIRE Setup Time(t UWS)20ns MICROWIRE Hold Time(t UWH)56ns MICROWIRE OutputPropagation Delay(t UPD)220nsInput Pulse WidthInterrupt Input High Time t CInterrupt Input Low Time t CTimer Input High Time t CTimer Input Low Time t CReset Pulse Width 1.0µsNote14:Parameter characterized but not production tested.7Timing DiagramCOP680C/COP681C/COP682C Absolute Maximum Ratings (Note 16)If Military/Aerospace specified devices are required,please contact the National Semiconductor Sales Office/Distributors for availability and specifications.Supply Voltage (V CC )6V Voltage at Any Pin−0.3V to V CC+0.3VTotal Current into V CC Pin (Source)40mA Total Current Out of GND Pin (Sink)48mAStorage Temperature Range −65˚C to +140˚CNote 15:Absolute maximum ratings indicate limits beyond which damage to the device may occur.DC and AC electrical specifications are not ensured when operating the device at absolute maximum ratings.DC Electrical CharacteristicsCOP68xC:−55˚C ≤T A ≤+125˚C unless otherwise specifiedParameterConditionMin TypMax Units Operating Voltage4.55.5V Power Supply Ripple (Note 17)Peak to Peak0.1V CCVSupply Current (Note 18)CKI =10MHz V CC =5.5V,tc =1µs 8.0mA CKI =4MHz V CC =5.5V,tc =2.5µs 4.4mA HALT Current (Note 19)V CC =5.5V,CKI =0MHz<1030µAInput Levels RESET,CKI Logic High 0.9V CCV Logic Low 0.1V CCVAll Other Inputs Logic High 0.7V CCV Logic Low 0.2V CCV Hi-Z Input Leakage V CC =5.5V−5+5µA Input Pullup Current V CC =5.5V,V IN =0V−35−300µA G Port Input Hysteresis 0.35V CCVOutput Current Levels D Outputs Source V CC =4.5V,V OH =3.8V −0.35mA Sink V CC =4.5V,V OL =1.0V9mAAll OthersSource (Weak Pull-Up)V CC =4.5V,V OH =3.2V −9−120µA Source (Push-Pull Mode)V CC =4.5V,V OH =3.2V −0.35mA Sink (Push-Pull Mode)V CC =4.5V,V OL =0.4V 1.4mA TRI-STATE LeakageV CC =5.5V−5.0+5.0µAAllowable Sink/Source Current per Pin D Outputs (Sink)12mA All Others2.5mADS010802-2FIGURE 3.MICROWIRE/PLUS TimingC O P 880C 8COP880C DC Electrical Characteristics(Continued)COP68xC:−55˚C≤T A≤+125˚C unless otherwise specifiedParameter Condition Min Typ Max Units Maximum Input Current(Room Temp)without Latchup(Note20)Room Temp±100mARAM Retention Voltage,Vr(Note21)500ns Rise and Fall Time(Min) 2.5VInput Capacitance7pFLoad Capacitance on D21000pFNote16:Absolute maximum ratings indicate limits beyond which damage to the device may occur.DC and AC electrical specifications are not ensured when operating the device at absolute maximum ratings.Note17:Rate of voltage change must be less than0.5V/ms.Note18:Supply current is measured after running2000cycles with a square wave CKI input,CKO open,inputs at rails and outputs open.Note19:The HALT mode will stop CKI from oscillating in the RC and the Crystal configurations.Test conditions:All inputs tied to V CC,L and G ports TRI-STATEand tied to ground,all outputs low and tied to ground.Note20:Pins G6and RESET are designed with a high voltage input network for factory testing.These pins allow input voltages greater than V CC and the pins willhave sink current to V CC when biased at voltages greater than V CC(the pins do not have source current when biased at a voltage below V CC).The effective resistance to V CC is750Ω(typical).These two pins will not latch up.The voltage at the pins must be limited to less than14V.Note21:To maintain RAM integrity,the voltage must not be dropped or raised instantaneously.COP680C/COP681C/COP682CAC Electrical Characteristics−55˚C≤T A≤+125˚C unless otherwise specifiedParameter Condition Min Typ Max Units Instruction Cycle Time(tc)Ext.or Crystal/Resonant V CC≥4.5V1DCµs(Div-by10)CKI Clock Duty Cycle fr=Max4060%(Note22)Rise Time(Note22)fr=10MHz Ext Clock12nsFall Time(Note22)fr=10MHz Ext Clock8ns MICROWIRE Setup Time(t UWS)20ns MICROWIRE Hold Time(t UWH)56ns MICROWIRE Output Valid220nsTime(t UPD)Input Pulse WidthInterrupt Input High Time t CInterrupt Input Low Time t CTimer Input High Time t CTimer Input Low Time t CReset Pulse Width1µsNote22:Parameter characterized but not production tested.9Typical Performance Characteristics(−40˚C ≤T A ≤+85˚C)Hall —I DDDS010802-16Dynamic —I DD (Crystal Clock Option)DS010802-17Port L/C/G Weak Pull-Up DS010802-18Port L/C/G Push-Pull Source CurrentDS010802-19Port L/C/G Push-Pull Sink Current DS010802-20Port D Source CurrentDS010802-21C O P 880C 10Typical Performance Characteristics(−40˚C≤TA≤+85˚C)(Continued)Pin DescriptionsV CC and GND are the power supply pins.CKI is the clock input.This can come from an external source,a R/C generated oscillator or a crystal(in conjunc-tion with CKO).See Oscillator description.RESET is the master reset input.See Reset description. PORT I is an8-bit Hi-Z input port.The28-pin device does not have a full complement of Port I pins.The unavailable pins are not terminated i.e.,they are floating.A read operation for these unterminated pins will return unpredictable values. The user must ensure that the software takes this into ac-count by either masking or restricting the accesses to bit operations.The unterminated Port I pins will draw power only when addressed.PORT L is an8-bit I/O port.PORT C is a4-bit I/O port.Three memory locations are allocated for the L,G and C ports,one each for data register,configuration register and the input pins.Reading bits4–7of the C-Configuration reg-ister,data register,and input pins returns undefined data. There are two registers associated with the L and C ports:a data register and a configuration register.Therefore,each L and C I/O bit can be individually configured under software control as shown below:Con-fig.Data Ports L and C Setup 00Hi-Z Input(TRI-STATE Output)01Input with Pull-Up(Weak One Output)10Push-Pull Zero Output11Push-Pull One OutputOn the28-pin part,it is recommended that all bits of Port C be configured as outputs.PORT G is an8-bit port with6I/O pins(G0–G5)and2input pins(G6,G7).All eight G-pins have Schmitt Triggers on the inputs.There are two registers associated with the G port:a data register and a configuration register.Therefore,each G port bit can be individually configured under software control as shown below:Con-fig.Data Port G Setup00Hi-Z Input(TRI-STATE Output)01Input with Pull-Up(Weak One Output)10Push-Pull Zero Output11Push-Pull One OutputSince G6and G7are input only pins,any attempt by the user to configure them as outputs by writing a one to the configu-ration register will be disregarded.Reading the G6and G7 configuration bits will return zeros.The device will be placed in the HALT mode by writing to the G7bit in the G-port data register.Six pins of Port G have alternate features:G0INTR(an external interrupt)G3TIO(timer/counter input/output)G4SO(MICROWIRE serial data output)G5SK(MICROWIRE clock I/O)G6SI(MICROWIRE serial data input)G7CKO crystal oscillator output(selected by mask option) or HALT restart input(general purpose input)Pins G1and G2currently do not have any alternate func-tions.PORT D is an8-bit output port that is preset high when RESET goes low.Care must be exercised with the D2pin operation.At RESET,the external loads on this pin must ensure that the output voltages stay above0.9V CC to pre-vent the chip from entering special modes.Also,keep the external loading on D2to less than1000pF. Functional DescriptionFigure1shows the block diagram of the internal architec-ture.Data paths are illustrated in simplified form to depict how the various logic elements communicate with each other in implementing the instruction set of the device. ALU AND CPU REGISTERSThe ALU can do an8-bit addition,subtraction,logical or shift operation in one cycle time.There are five CPU registers:A is the8-bit Accumulator registerPU is the upper7bits of the program counter(PC)PL is the lower8bits of the program counter(PC)Port D Sink CurrentDS010802-22COP880CFunctional Description(Continued)B is the 8-bit address register,can be auto incremented or decremented.X is the 8-bit alternate address register,can be incremented or decremented.SP is the 8-bit stack pointer,points to subroutine stack (in RAM).B,X and SP registers are mapped into the on chip RAM.The B and X registers are used to address the on chip RAM.The SP register is used to address the stack in RAM during subroutine calls and returns.PROGRAM MEMORYProgram memory consists of 4096bytes of ROM.These bytes may hold program instructions or constant data.The program memory is addressed by the 15-bit program counter (PC).ROM can be indirectly read by the LAID in-struction for table lookup.DATA MEMORYThe data memory address space includes on chip RAM,I/O and registers.Data memory is addressed directly by the instruction or indirectly by the B,X and SP registers.The device has 128bytes of RAM.Sixteen bytes of RAM are mapped as “registers”that can be loaded immediately,dec-remented or tested.Three specific registers:B,X and SP are mapped into this space,the other bytes are available for general usage.The instruction set permits any bit in memory to be set,reset or tested.All I/O and registers (except the A &PC)are memory mapped;therefore,I/O bits and register bits can be directly and individually set,reset and tested.A is not memory mapped,but bit operations can be still performed on it.Note:RAM contents are undefined upon power-up.RESETThe RESET input when pulled low initializes the microcon-troller.Initialization will occur whenever the RESET input is pulled low.Upon initialization,the ports L,G and C are placed in the TRI-STATE mode and the Port D is set high.The PC,PSW and CNTRL registers are cleared.The data and configuration registers for Ports L,G and C are cleared.The external RC network shown in Figure 4should be used to ensure that the RESET pin is held low until the power supply to the chip stabilizes.OSCILLATOR CIRCUITSFigure 5shows the three clock oscillator configurations.A.CRYSTAL OSCILLATORThe device can be driven by a crystal clock.The crystal network is connected between the pins CKI and CKO.Table 1shows the component values required for various standard crystal values.B.EXTERNAL OSCILLATORCKI can be driven by an external clock signal.CKO is available as a general purpose input and/or HALT restart control.C.R/C OSCILLATORCKI is configured as a single pin RC controlled Schmitt trigger oscillator.CKO is available as a general purpose input and/or HALT restart control.Table 2shows the variation in the oscillator frequencies as functions of the component (R and C)values.OSCILLATOR MASK OPTIONSThe device can be driven by clock inputs between DC and 10MHz.TABLE 1.Crystal Oscillator Configuration,T A =25˚CR1R2C1C2CKI Freq Conditions(k Ω)(M Ω)(pF)(pF)(MHz)013030–3610V CC =5V 013030–364V CC =2.5V 5.61200100–1500.455V CC =5V DS010802-6RC ≥5X Power Supply Rise TimeFIGURE 4.Recommended Reset CircuitDS010802-7FIGURE 5.Crystal and R-C Connection Diagrams C O P 880CFunctional Description(Continued)TABLE2.RC Oscillator Configuration,T A=25˚CR C CKI Freq.Instr.Cycle Conditions (kΩ)(pF)(MHz)(µs)3.382 2.2to2.7 3.7to4.6V CC=5V5.6100 1.1to1.37.4to9.0V CC=5V6.81000.9to1.18.8to10.8V CC=5V Note23:(R/C Oscillator Configuration):3k≤R≤200k,50pF≤C≤200pF.The device has three mask options for configuring the clock input.The CKI and CKO pins are automatically configured upon selecting a particular option.•Crystal(CKI/10);CKO for crystal configuration •External(CKI/10);CKO available as G7input•R/C(CKI/10);CKO available as G7inputG7can be used either as a general purpose input or as a control input to continue from the HALT mode.HALT MODEThe device supports a power saving mode of operation: HALT.The controller is placed in the HALT mode by setting the G7data bit,alternatively the user can stop the clock input.In the HALT mode all internal processor activities including the clock oscillator are stopped.The fully static architecture freezes the state of the controller and retains all information until continuing.In the HALT mode,power re-quirements are minimal as it draws only leakage currents and output current.The applied voltage(V CC)may be de-creased down to Vr(minimum RAM retention voltage)with-out altering the state of the machine.There are two ways to exit the HALT mode:via the RESET or by the CKO pin.A low on the RESET line reinitializes the microcontroller and starts executing from the address 0000H.A low to high transition on the CKO pin(only if the external or R/C clock option selected)causes the microcon-troller to continue with no reinitialization from the address following the HALT instruction.This also resets the G7data bit.INTERRUPTSThere are three interrupt sources,as shown below.A maskable interrupt on external G0input(positive or nega-tive edge sensitive under software control)A maskable interrupt on timer underflow or timer captureA non-maskable software/error interrupt on opcode zeroINTERRUPT CONTROLThe GIE(global interrupt enable)bit enables the interrupt function.This is used in conjunction with ENI and ENTI to select one or both of the interrupt sources.This bit is reset when interrupt is acknowledged.ENI and ENTI bits select external and timer interrupt respec-tively.Thus the user can select either or both sources to interrupt the microcontroller when GIE is enabled.IEDG selects the external interrupt edge(0=rising edge,1=falling edge).The user can get an interrupt on both risingand falling edges by toggling the state of IEDG bit after each interrupt.IPND and TPND bits signal which interrupt is pending.After interrupt is acknowledged,the user can check these two bitsto determine which interrupt is pending.This permits the interrupts to be prioritized under software.The pending flagshave to be cleared by the user.Setting the GIE bit highinside the interrupt subroutine allows nested interrupts.The software interrupt does not reset the GIE bit.Thismeans that the controller can be interrupted by other inter-rupt sources while servicing the software interrupt.INTERRUPT PROCESSINGThe interrupt,once acknowledged,pushes the program counter(PC)onto the stack and the stack pointer(SP)is decremented twice.The Global Interrupt Enable(GIE)bit isreset to disable further interrupts.The microcontroller then vectors to the address00FFH and resumes execution fromthat address.This process takes7cycles to complete.At theend of the interrupt subroutine,any of the following three instructions return the processor back to the main program:RET,RETSK or RETI.Either one of the three instructions willpop the stack into the program counter(PC).The stackpointer is then incremented twice.The RETI instruction ad-ditionally sets the GIE bit to re-enable further interrupts.Any of the three instructions can be used to return from a hardware interrupt subroutine.The RETSK instructionshould be used when returning from a software interrupt subroutine to avoid entering an infinite loop.Note:There is always the possibility of an interrupt occurring during an instruction which is attempting to reset the GIE bit or any other inter-rupt enable bit.If this occurs when a single cycle instruction is beingused to reset the interrupt enable bit,the interrupt enable bit will bereset but an interrupt may still occur.This is because interrupt process-ing is started at the same time as the interrupt bit is being reset.Toavoid this scenario,the user should always use a two,three or fourcycle instruction to reset interrupt enable bits.COP880CFunctional Description(Continued)DETECTION OF ILLEGAL CONDITIONSThe device contains a hardware mechanism that allows it to detect illegal conditions which may occur from coding errors,noise and “brown out”voltage drop situations.Specifically it detects cases of executing out of undefined ROM area and unbalanced stack situations.Reading an undefined ROM location returns 00(hexadeci-mal)as its contents.The opcode for a software interrupt is also “00”.Thus a program accessing undefined ROM will cause a software interrupt.Reading an undefined RAM location returns an FF (hexa-decimal).The subroutine stack grows down for each subrou-tine call.By initializing the stack pointer to the top of RAM,the first unbalanced return instruction will cause the stack pointer to address undefined RAM.As a result the program will attempt to execute from FFFF (hexadecimal),which is an undefined ROM location and will trigger a software interrupt.MICROWIRE/PLUSMICROWIRE/PLUS is a serial synchronous bidirectional communications interface.The MICROWIRE/PLUS capabil-ity enables the device to interface with any of National Semiconductor’s MICROWIRE peripherals (i.e.A/D convert-ers,display drivers,EEPROMS,etc.)and with other micro-controllers which support the MICROWIRE/PLUS interface.It consists of an 8-bit serial shift register (SIO)with serial data input (SI),serial data output (SO)and serial shift clock (SK).Figure 7shows the block diagram of the MICROWIRE/PLUS interface.The shift clock can be selected from either an internal source or an external source.Operating the MICROWIRE/PLUS interface with the internal clock source is called the Master mode of operation.Similarly,operating the MICROWIRE/PLUS interface with an external shift clock is called the Slave mode of operation.The CNTRL register is used to configure and control the MICROWIRE/PLUS mode.To use the MICROWIRE/PLUS,the MSEL bit in the CNTRL register is set to one.The SK clock rate is selected by the two bits,SL0and SL1,in the CNTRL register.Table 3details the different clock rates that may be selected.TABLE 3.SL1SL0SK Cycle Time002t C 014t C 1x8t Cwhere,t C is the instruction cycle clock.MICROWIRE/PLUS OPERATIONSetting the BUSY bit in the PSW register causes the MICROWIRE/PLUS arrangement to start shifting the data.It gets reset when eight data bits have been shifted.The user may reset the BUSY bit by software to allow less than 8bits to shift.The devoce may enter the MICROWIRE/PLUS mode either as a Master or as a Slave.Figure 8shows how two COP880C microcontrollers and several peripherals may be interconnected using the MICROWIRE/PLUS arrange-ment.Master MICROWIRE/PLUS OperationIn the MICROWIRE/PLUS Master mode of operation the shift clock (SK)is generated internally.The MICROWIRE/PLUS Master always initiates all data exchanges.(See Fig-ure 8).The MSEL bit in the CNTRL register must be set to enable the SO and SK functions onto the G Port.The SO and SK pins must also be selected as outputs by setting appropriate bits in the Port G configuration register.Table 4summarizes the bit settings required for Master mode of operation.SLAVE MICROWIRE/PLUS OPERATIONIn the MICROWIRE/PLUS Slave mode of operation the SK clock is generated by an external source.Setting the MSEL bit in the CNTRL register enables the SO and SK functions onto the G Port.The SK pin must be selected as an input and the SO pin is selected as an output pin by appropriately setting up the Port G configuration register.Table 4summa-rizes the settings required to enter the Slave mode of opera-tion.The user must set the BUSY flag immediately upon entering the Slave mode.This will ensure that all data bits sent by the Master will be shifted properly.After eight clock pulses the BUSY flag will be cleared and the sequence may be re-peated.(See Figure 8.)DS010802-8FIGURE 6.Interrupt Block DiagramC O P 880C。

Electrical data Primary nominal Primary currentPrimary Conductor Typer.m.s. current measuring range Diameter x Turns I PN (A) I P (A) (mm)3± 90.6d x 20T HX 03-P5± 15 0.8d x 12T HX 05-P 10± 30 1.1d x 6T HX 10-P 15± 45 1.4d x 4T HX 15-P 20± 60 1.6d x 3T HX 20-P 25± 75 1.6d x 2THX 25-P 50± 1501.2 x 6.3 x 1THX 50-PV OUT Output voltage @ ± I PN , R L = 10 k Ω, T A = 25°C ± 4 V R OUT Output impedance < 50ΩR L Load resistance≥ 10k ΩVC Supply voltage (± 5 %)1)± 15 V I C Current consumption< ± 15 mA V d R.m.s. voltage for AC isolation test, 50/60Hz, 1 mn > 3kV V eR.m.s. voltage for partial discharge extinction at 10pC≥ 1kV Impulse withstand voltage, 1.2/50µs≥ 6kVAccuracy-Dynamic performance dataXAccuracy @ I PN , T A = 25°C (without offset) < ± 1% of I PNεL Linearity (0 .. ± I PN ) < ± 1% of I PN V OE Electrical offset voltage, T A = 25°C < ± 40mV V OH Hysteresis offset voltage @ I P = 0;after an excursion of 3 x I PN < ± 15mVV OT Thermal drift of V OE max. ± 1.5mV/K TC εG Thermal drift of the gain (% of reading) ± 0.1%/K t r Response time @ 90% of I P ≤ 3µsf Frequency bandwidth (-3 dB) 2) 50 kHz General dataT A Ambient operating temperature - 25 .. + 85°C T S Ambient storage temperature - 25 .. + 85°C mMass8g Min. internal creepage distance/clearance ≥ 5.5 mm Isolation material group IStandardsEN50178Current Transducer HX 03 .. 50-PFor the electronic measurement of currents: DC, AC, pulsed, mixed,with a galvanic isolation between the primary circuit (high power) and the secondary circuit (electronic circuit).I PN =3 .. 50 ANotes :1) Also operate at ±12V power supplies, measuring range reduced to ±2.5x I PN2)Small signal only to avoid excessive heating of the magnetic cores030806/5Features•Galvanic isolation between primary and secondary circuit•Hall effect measuring principle •Isolation voltage 3000V •Low power consumption•Extended measuring range (3x I PN )•Power supply from ±12V to ±15V •Material according to UL94-V0Advantages•Low insertion losses•Easy to mount with automatichandling system•Small size and space saving •Only one design for wide current ratings range•High immunity to external interference.Applications•Switched Mode Power Supplies (SMPS)•AC variable speed drives•Uninterruptible Power Supplies (UPS)•Electrical appliances•Battery supplied applications •DC motor drivesLEM Components。

RF Monolithics, Inc.Phone: (972) 233-2903Fax: (972) 387-9148E-mail: info@ Page 1 of 2RFM Europe Phone: 44 1963 251383Fax: 44 1963 251510 ©1999 by RF Monolithics, Inc. The stylized RFM logo are registered trademarks of RF Monolithics, Inc.HX1002-101899Electrical CharacteristicsCharacteristicSym Notes Minimum TypicalMaximum Units Operating FrequencyAbsolute Frequencyf O 1, 2, 3, 4,10303.725303.925MHz Tolerance from 303.825 MHz∆f O ±100kHz RF Output Power into 50 Ω at 25°CP O2, 4, 5, 10-30dBm Within Specified Temperature Range2, 3, 4, 5-50Harmonic Spurious Emissions 2, 3, 4, 5-45-35dBc Modulation InputInput HIGH Voltage V IH 3, 4, 52.5V CC V Input LOW Voltage V IL 0.00.3Input HIGH Current I IH 100µA Input LOW CurrentI IL 0.0Data Timing Parameters Modulation Rise Time t R 3, 4, 5, 6100µs Modulation Fall Time t F 100Power SupplyVoltage V CC 5, 7 2.73 3.3VDC Peak Current I CC3, 4, 5, 8710mA Standby Current5, 9 1.0µA Operating Case Temperature RangeT C 5-40+85°CLid Symbolization (in addition to Lot and/or Date Codes)RFM HX1002SM-4 Case•Ideal for 303.825 MHz Unlicensed Transmitters•Quartz SAW Frequency Stabilization and Harmonic Filtering •Compact, Surface-Mount Case with < 90mm 2 FootprintThe HX1002 is a miniature transmitter module that generates on-off keyed (OOK) modulation from an exter-nal digital encoder (not included). The carrier frequency is quartz, surface-acoustic-wave (SAW) stabilized,and output harmonics are suppressed by a SAW filter. The result is excellent performance in a simple-to-use, surface-mount device with a low external component count. The HX1002 is designed specifically for unlicensed remote-control and wireless security transmitters operating in the USA under FCC Part 15 and in Australia under DTC regulations.Absolute Maximum RatingsRatingValue Units Power Supply and/or Modulation Input Voltage 10V Nonoperating Case Temperature -40 to +85°C Ten-Second Soldering Temperature230°C303.825 MHz Hybrid TransmitterHX1002CAUTION: Electrostatic Sensitive Device. Observe precautions for handling.NOTES:1.One or more of the following United States patents apply: 4,454,488; 4,616,197; 4,670,681; and 4,760,352.2.Typically, equipment utilizing this device requires emissions testing and government approval, which is the responsibility of the equipment manufacturer.3.Applies over the specified range of operating temperature.4.Applies over the specified range of operating power supply voltage.5.The design, manufacturing process, and specifications of this device are subject to change without notice.6.The maximum modulation bandwidth (and data rate) is dependent on the characteristics of the external encoding circuitry (not included).7.Unless noted otherwise, case temperature T C = +25°C ± 2°C, test load impedance = 50 Ω, and modulation input is at logic HIGH.8.The maximum operating current occurs at the maximum specified power supply voltage and maximum specified operating temperature.9.Standby current is defined as the supply current consumed with the modulation input at logic LOW.10.Improper antenna loading affects performance of HX device.303.825 MHz Hybrid TransmitterRF Monolithics, Inc.Phone: (972) 233-2903Fax: (972) 387-9148E-mail: info@ Page 2 of 2RFM Europe Phone: 44 1963 251383Fax: 44 1963 251510 ©1999 by RF Monolithics, Inc. The stylized RFM logo are registered trademarks of RF Monolithics, Inc.HX1002-101899Electrical ConnectionsBlock DiagramCase DesignFootprintTypical Test Circuit*Note: Bypass required only for “HX2...” series transmitters in the 902 to 928 MHz band.Typical Transmitter ApplicationNotes:1.This matching component is required only for antennas that are not 50 ohms. It is typically a chip inductor to match to stub antennas shorter than ¼ wavelength. For very low radiated field-strength appli-cations, a resistor can also be used.2.For ESD protection.Terminal NumberConnections 1Data Input 2+DC Supply 3Ground 4RF Output to 50 ΩDimensionsMillimeters InchesMinMax MinMax A 10.670.420B 1.27 Nominal 0.050 NominalC 2.67 Nominal 0.105 NominalD 5.08 Nominal 0.200 NominalE 1.70 Nominal 0.067 NominalF 5.36 Nominal0.211 NominalG 2.800.110H9.020.355C。

丹东边境经济合作区华信电子技术有限公司HX-8802电子秤仪表说明书一、功能及参数1. 可用于调速皮带秤和恒速皮带秤的流量核算和控制。

2. 智能化的设计使仪表参数大大简化，是同类仪表中参数最少的仪表。

3. 汉字显示，12个数字键、组合功能键，操作方便。

4. 运行中可以修改流量和控制参数。

5. 16位ADC模块，用于荷重传感器输入和外部流量设定输入。

传感器可选择1－3mV灵敏度电阻应变传感器，外部流量设定输入为4-20mA，内阻为10欧。

6. 6路继电器无源开关量输出，用于启动、报警和累计脉冲输出。

接点容量5A/250V。

7. 两路4-20mA输出，可驱动500欧负载。

8. 标准RS485通讯接口，执行modbus-RTU通讯协议。

二、认识仪表面板图2.1 面板及主显示1画面图2.2 主显示画面2三、端子定义L、N、FG为电源输入，220V/50Hz/5W。

FG要可靠接地。

RG、B、A为485通讯口SH、S2+/-、S1+/-、E＋/-分别为屏蔽层、流量设定输入+/-、传感器信号+/-和传感器电源+/-DI1、DG接启动按钮（自锁）DI2、DV、DG为测速传感器的信号端、电源端(12V)和地AO1、DG为流量控制输出4-20mAAO2、DG为瞬时流量输出指示4-20mADO1-3分别为皮带启动、累计脉冲和报警输出。

COM为输出公共端四、工作过程1. 操作过程：开机－设定流量(通过端口、键盘或通讯)－启动(通过端口或通讯)。

2. 首次使用：上电-设定参数(检查并所有参数并根据设定情况设定必要参数)-接口测试(检查硬件是否正常)-标定零点-实物标定-试运行。

3. 标定步骤：检查与标定有关的参数，先进行零点标定，然后执行实物标定功能。

如果使用链码标定则应核算成等效的物料量。

(详见后面有关章节)4. 调整方法：仪表采用智能控制算法，只要根据皮带秤的滞后时间输入合适的控制周期，根据皮带秤正常流量波动范围输入合适的报警误差，仪表将自动完成控制参数的整定。

HX8088芯片规格书和使用手册目录1.概述 (6)1.1简介 (6)HX8088是一个提供串口的语音芯片，完美的集成了MP3、WAV的硬解码。

同时软件支持工业级别的串口通信协议，以SPIFLASH作为存储介质，用户可以灵活的选用其中的任何一种设备作为语音的存储介质。

通过简单的串口指令即可完成播放指定的语音，以及如何播放语音等功能，无需繁琐的底层操作，使用方便，稳定可靠是此款产品的最大特点。

(6)1.2功能 (6)1.3应用 (6)1.方案说明 (7)2.1参数说明 (7)2.2管脚说明 (8)2.3测试简述 (9)3.串口通讯协议 (10)3.1通讯格式 (10)3.2通讯指令 (11)3.2.1控制指令 (11)3.2.2查询指令 (12)3.3芯片返回的数据 (13)3.3.1芯片上电返回的数据 (13)3.3.2曲目播放完毕返回的数据[0X3C][0X3D][0X3E] (14)3.3.3模块应答返回的数据[0X41] (14)3.3.4模块错误返回的数据[0X40][0X50] (15)3.3.5设备插入拔出消息[0X3A][0X3B] (15)3.3.6设备文件系统初始化成功返回[0X90] (15)3.4串口控制指令详解 (16)3.4.1指定歌曲播放指令[0X03] (16)3.4.2指定音量播放指令[0X06] (16)3.4.3单曲循环播放指令[0X08] (17)3.4.4指定播放设备[0X09] (17)3.4.5进入睡眠[0X0A] (17)3.4.6指定文件夹文件名播放[0X0F] (18)3.4.7插播ADVERT文件夹下的广告[0X13] (19)3.4.8全部循环播放指令[0X11] (19)3.4.9播放停止指令[0X15][0X16] (20)3.4.10指定文件夹开始循环顺序播放[0X17] (20)3.4.11随机播放设备文件[0X18] (20)3.4.12对当前的曲目设置为循环播放[0X19] (20)3.4.14组合播放功能指令[0X21] (21)3.4.16多文件夹插播功能[0X25] (22)3.4.17复位和睡眠的说明[0X0A][0X0B][0X0C] (22)3.4.18指定文件夹循环随机播放[0X28] (23)3.5串口查询指令详解 (24)3.5.1查询当前在线的设备 (24)3.5.2播放状态查询指令 (24)3.5.3指定文件夹曲目总数查询[0X4E] (25)3.5.4当前设备的总文件夹数目查询[0X4F] (25)3.5.6查询当前播放的音乐的总时间和已经播放的时间[0X80][0X81] (26)4.参考电路 (27)4.1串行接口 (27)4.2按键接口 (28)4.2.1通过CFG文件来配置 (28)4.2外接单声道功放 (29)4.5USB更新语音说明[业内首创功能] (30)4.7.1USB更新SPIFLASH的语音详细说明 (31)4.8用户使用空白的FLASH说明 (32)5.注意事项 (34)5.1GPIO的特性 (34)5.2应用中的注意点 (35)5.3注意事项点 (36)5.3.1芯片上电的工作流程图 (36)5.3.2串口编程参考的说明 (37)5.3.3串口编程需要适当延时的注意点 (37)5.3.4校验的重要说明 (37)5.3.5校验的计算说明 (38)5.3.6MCU的晶振选择 (38)5.3.7指定播放的说明 (39)5.3.8串口调试说明 (40)5.3.9校验代码的移植 (41)5.3.10芯片或者芯片的供电说明 (43)6.免责声明 (44)7.订货信息 (45)7.1参考原理图 (45)7.2封装尺寸 (46)8.参考例程 (47)9.PC端串口调试指令举例 (49)9.1控制指令 (49)9.2查询参数指令 (50)1.概述1.1简介HX8088是一个提供串口的语音芯片，完美的集成了MP3、WAV的硬解码。

GM8802C使用说明书G M8802C-0D11010148010224131000©2011，深圳市杰曼科技有限公司，版权所有。

未经深圳市杰曼科技有限公司的许可，任何单位和个人不得以任何形式或手段复制、传播、转录或翻译为其他语言版本。

因我公司的产品一直在持续的改良及更新，故我公司对本手册保留随时修改不另行通知的权利。

为此，请经常访问公司网站，以便获得及时的信息。

公司网址 本产品执行标准：GB/T 7724—2008目录第一章概述 (1)1.1功能及特点 (1)1.2前面板说明 (1)1.3 技术规格 (3)1.3.1一般规格 (3)1.3.2模拟部分 (3)1.3.3数字部分 (4)1.4尺寸图 (5)第二章安装及配线 (6)2.1电源接线 (6)2.2传感器连接 (6)2.2.1 六线制接法 (7)2.2.2 四线制接法 (8)2.3串行口的连接 (9)第三章标定 (10)3.1标定说明 (10)3.2 标定流程图 (11)3.3 毫伏数显示 (16)3.4 有砝码标定 (17)3.5无砝码标定 (18)3.6串口标定开关 (19)3.7 标定参数说明表 (20)3.8 标定参数记录表 (20)第四章参数设置 (21)4.1 工作参数设置流程表 (21)4.2 参数设置方法 (26)4.2.1 数据输入类参数设置方法 (26)4.2.2选项类参数设置 (27)第五章串口通讯 (28)5.1 快速协议方式 (28)5.1.1连续方式 (28)5.1.2 命令方式 (29)5.2 RE协议方式 (30)5.2.1 连续方式 (30)5.2.2命令方式 (31)5.3 RS协议方式 (32)5.3.1 连续方式 (32)5.3.2 命令方式 (33)5.3.2.1上位机读称重显示器当前状态 (33)5.3.2.2读小数点 (34)5.3.2.3读传感器灵敏度 (35)5.3.2.4读最大量程和分度值 (36)5.3.2.5读参数协议 (37)5.3.2.6串口清零功能 (37)5.3.2.7标定称重显示器 (38)5.3.2.8写工作参数 (44)5.3.2.9读寄存器1-9 (45)5.3.2.10写寄存器1-9 (45)5.3.3 RS协议CRC（校验和）计算 (46)5.4 SP1协议方式 (47)5.4.1参数代码说明表 (47)5.4.2 错误代码说明表 (49)5.4.3 连续方式 (49)5.4.4 命令方式 (50)5.4.4.1上位机读称重显示器当前状态 (51)5.4.4.2读其他参数 (52)5.4.4.3写最大量程与最小分度 (53)5.4.4.4写其他参数 (54)5.4.4.5标定零位 (54)5.4.4.6增益标定 (56)5.4.4.7清零操作 (57)5.4.4.8读寄存器1-9 (58)5.4.4.9写寄存器1-9 (59)5.4.4.10 CRC计算 (59)5.5 Modbus协议方式 (60)5.5.1 Modbus传输模式 (60)5.5.2 Modbus通讯地址 (61)5.5.3 功能码说明 (64)5.5.4 Modbus通讯错误信息 (71)5.6托利多协议 (72)5.7飞利浦协议 (73)第六章操作 (76)6.1清零操作 (76)6.2密码输入 (76)6.3 密码设置 (77)6.4恢复出厂设置操作 (78)第七章显示测试 (80)第八章错误及报警信息 (81)第一章概述GM8802C称重显示器是针对工业现场需要进行重量变送的场合而开发生产的一种小型称重显示器。

550C中文资料关键信息项：1、资料名称：550C 中文资料2、资料用途：＿___________________________3、资料提供方：＿___________________________4、资料接收方：＿___________________________5、资料使用期限：＿___________________________6、资料保密要求：＿___________________________7、违约责任：＿___________________________8、争议解决方式：＿___________________________11 协议背景本协议旨在规范550C 中文资料的相关事宜，确保资料的合理使用、保护和传播。

111 资料的定义和范围本协议中所提及的550C 中文资料包括但不限于文字、图表、图像、音频、视频等与 550C 相关的各类中文形式的信息。

112 资料的用途资料接收方应仅将 550C 中文资料用于具体合法且明确的用途，不得用于其他任何未经授权的目的。

12 资料提供方的权利和义务121 提供方应确保所提供的 550C 中文资料的真实性、准确性和完整性。

122 提供方有权对资料接收方的使用情况进行监督和检查。

13 资料接收方的权利和义务131 接收方应按照协议约定的用途使用 550C 中文资料。

132 接收方有义务对资料进行妥善保管，采取合理的安全措施防止资料泄露、丢失或损坏。

133 未经提供方书面同意，接收方不得将资料转让、出售、出租或提供给任何第三方。

14 资料使用期限141 双方约定 550C 中文资料的使用期限为具体时间段。

142 在使用期限届满后，接收方应立即停止使用并按照提供方的要求归还或销毁资料。

15 资料保密要求151 接收方应对 550C 中文资料予以保密，不得向任何无关人员透露资料的内容。

152 接收方应采取必要的保密措施，如限制访问、加密存储等，以确保资料的保密性。

公司简介深圳市信华翰科技有限公司成立于2006年，注册资金500万，办公室位于深圳市商业中心，华强北商圈的国际科技大厦11楼，办公面积320平方。

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我司共代理有十几个品牌的条码设备，为客户提供优质丰富的条码相关产品和系统集成专业服务。

扫描网是深圳市信华翰科技有限公司斥资100万打造的扫描枪的网上商城。

信华翰为了让中国的条码事业走得更好更快，让大众都能享受条码带来的便利，特此为全国商户带“”来质优价廉的各类扫描枪，扫描网所售的所有扫描枪均是厂家授权，均经过三测（出厂检测，到货检测，出货检测）的优良产品。

PIRY ins zebexOPTICONT S C合作伙伴Honeywell深圳市信华翰科技有限公司SHENZHEN XIN HUA HAN SCIENCE AND TECHNOLOGY CO.,LTD.地址:深圳市福田区深南中路3007号国际科技大厦11楼电话****************************;传真**************展销部:深圳市华强北赛格大厦7106室网址：服务热线：新大陆HR1030手持式扫描枪北京意锐RC532二维码扫描平台 摩托罗拉C11一维扫描枪霍尼韦尔1900GHD二维码扫描枪PIRYinsHoneywell如何正确使用条码阅读器：1、在条码阅读器和条码保持一定的倾角，以达到最佳效果。

2、在条码阅读器和条码间的角度不能为90度，否则不能正常读码。

3、务必让条码被完整扫描，确定阅读器能正确扫读。

介绍说明：该条码扫读设备为计算机信息系统提供精确，易用和快速的数据录入和存入的完备的解决方案。

本产品提供完整的接口方式以适应各类主机的计算机系统包括：KeyboardWandRS-232Dual RS-232USBOTHERS所有译码器的参数设定都可通条码的扫描来完成，并保存在存储记忆体中，在关闭电源后仍保留设置。

xmt-8802说明书
主要技术参数
1.输入电压：220V±10%,50HZ
2.输出电压：0～220V连续可调
3.最大允许负载：5KW
4.精度等级：0.5级
5.配用电偶：镍铬-镍硅，K值，0～1000℃
6.工作环境：0～40℃，相对湿度≯85％
使用方法
1.使用前应首先检查控制器的内部接线是否脱落，如有松动应按原理图接好，可控硅管壳与散热器应接触良好，保证元件工作是散热正常。

2.控制器不应放置在具有剧烈震动的场合，控制器内部应保持清洁。

3.按电控器上所标输入（220V），输出位置，将电源与负载接好。

4.打开电源开关键，工作指示灯亮，表示电源已接通。

5.顺时针转动电压调节选钮，使电压表指示到合适强度(220v),
拨动”数显调节仪”右下方开关到设定（OFF）后,顺时针转动开关上面的调节选钮，使温度显示到需要设定值；设定后，开关拨到测量（ON），绿灯亮开始工作，温度达到设定值后红灯亮，停止工作。

GM8802C使用说明书G M8802C-0D11010148010224131000©2011，深圳市杰曼科技有限公司，版权所有。

未经深圳市杰曼科技有限公司的许可，任何单位和个人不得以任何形式或手段复制、传播、转录或翻译为其他语言版本。

因我公司的产品一直在持续的改良及更新，故我公司对本手册保留随时修改不另行通知的权利。

为此，请经常访问公司网站，以便获得及时的信息。

公司网址 本产品执行标准：GB/T 7724—2008目录第一章概述 (1)1.1功能及特点 (1)1.2前面板说明 (1)1.3 技术规格 (3)1.3.1一般规格 (3)1.3.2模拟部分 (3)1.3.3数字部分 (4)1.4尺寸图 (5)第二章安装及配线 (6)2.1电源接线 (6)2.2传感器连接 (6)2.2.1 六线制接法 (7)2.2.2 四线制接法 (8)2.3串行口的连接 (9)第三章标定 (10)3.1标定说明 (10)3.2 标定流程图 (11)3.3 毫伏数显示 (16)3.4 有砝码标定 (17)3.5无砝码标定 (18)3.6串口标定开关 (19)3.7 标定参数说明表 (20)3.8 标定参数记录表 (20)第四章参数设置 (21)4.1 工作参数设置流程表 (21)4.2 参数设置方法 (26)4.2.1 数据输入类参数设置方法 (26)4.2.2选项类参数设置 (27)第五章串口通讯 (28)5.1 快速协议方式 (28)5.1.1连续方式 (28)5.1.2 命令方式 (29)5.2 RE协议方式 (30)5.2.1 连续方式 (30)5.2.2命令方式 (31)5.3 RS协议方式 (32)5.3.1 连续方式 (32)5.3.2 命令方式 (33)5.3.2.1上位机读称重显示器当前状态 (33)5.3.2.2读小数点 (34)5.3.2.3读传感器灵敏度 (35)5.3.2.4读最大量程和分度值 (36)5.3.2.5读参数协议 (37)5.3.2.6串口清零功能 (37)5.3.2.7标定称重显示器 (38)5.3.2.8写工作参数 (44)5.3.2.9读寄存器1-9 (45)5.3.2.10写寄存器1-9 (45)5.3.3 RS协议CRC（校验和）计算 (46)5.4 SP1协议方式 (47)5.4.1参数代码说明表 (47)5.4.2 错误代码说明表 (49)5.4.3 连续方式 (49)5.4.4 命令方式 (50)5.4.4.1上位机读称重显示器当前状态 (51)5.4.4.2读其他参数 (52)5.4.4.3写最大量程与最小分度 (53)5.4.4.4写其他参数 (54)5.4.4.5标定零位 (54)5.4.4.6增益标定 (56)5.4.4.7清零操作 (57)5.4.4.8读寄存器1-9 (58)5.4.4.9写寄存器1-9 (59)5.4.4.10 CRC计算 (59)5.5 Modbus协议方式 (60)5.5.1 Modbus传输模式 (60)5.5.2 Modbus通讯地址 (61)5.5.3 功能码说明 (64)5.5.4 Modbus通讯错误信息 (71)5.6托利多协议 (72)5.7飞利浦协议 (73)第六章操作 (76)6.1清零操作 (76)6.2密码输入 (76)6.3 密码设置 (77)6.4恢复出厂设置操作 (78)第七章显示测试 (80)第八章错误及报警信息 (81)第一章概述GM8802C称重显示器是针对工业现场需要进行重量变送的场合而开发生产的一种小型称重显示器。

HX-DU8602T Wireless Data TransceiverUser ManualVersion：V1.4CONTENTS1、SUMMARY (4)2、INTERFACE (4)2.1S ERIAL DA TA LINE INTERFACE (4)2.2RF INTERFACE (4)3、FUNCTION AND OPERATING INSTRUCTION (5)3.1B OOTING (5)3.2H IGH/L OW RF POWER SWITCHING (5)3.3T RANSMITTING CHANNEL SWITCHING (5)3.4C HANNEL D ISPLAY (5)3.5L OW VOLTAGE INDICATOR (5)3.6O VERVOLTAGE INDICATOR (6)3.7D ATA TRANSMITTING INDICATOR (6)4、RADIO SETTING (6)4.1C HOOSE PORTS (6)4.2E NTRY THE CONFIGURATION MODE (7)4.3R EAD THE RADIO MODEM PARAMETER (7)4.4C ONFIGURING THE RADIO MODEM PARAMETER (8)4.4F INISH TO EXIT THE CONFIGURA TION MODE (10)5.5I MPORT AND EXPORT CONFIGURA TION (10)5、SOFTWARE UPGRADING (10)6、TECHNICAL SPECIFICATIONS (12)Copyright InformationThis products operation manual and all the related software are protected by Harxon Corporation, and all rights reserved. All rights of this manual include copyright only belongs to Harxon Corporation (short for Harxon as below), unless the copyright holders allowed, strictly forbid to copy this manual by printing、xeroxing、recording and other means.DisclaimerWe strive to guarantee the accuracy and completeness of this manual content when compiling, but for possible errors or omissions, Harxon will not assume any responsibility. Due to the continuous development of technology, Harxon reserves the rights to change the technical specifications or functions of their products without any notification to users.Antenna Installation Warning1. Any antenna only can be installed and maintained by professional technician. Please make sure that the radio station is closed when you maintain or work nearby the antenna.2. In general, radio will be connected to a directional (high-gain) antenna, and fixed to the edge or top of building or top of tower. According to the application and antenna gain, total hybrid power may exceed 90W (ERP). Under normal circumstance, only the professional technicians can close to the antenna area, anyone can’t touch the antenna or close to 2.3m in diameter range of the antenna.Antenna Gain vs Safe distance recommended1、SummaryHX-DU8602T is an external transmit-only high-power UHF radio modem, waterproof of IP67、Durable structure，which can apply to all outdoor weather conditions.HX-DU8602T has 4 pieces of LED、1 piece of nixie tube and 3 pieces of push-button, for user’s convenience of booting、channel switching、power rating、low voltage alarming and indicating the current operation channel.2、Interface2.1 Serial data line interfaceInterface type: asynchronous serial communication standard of RS232Pin definitions：Pin 1------Power，9-16V DC；Pin 2------power grounding，Power GND；Pin 3------serial data receiver，RXD；Pin 4------serial signal grounding；Pin 5------serial data transmission，TXD.2.2 RF interfaceHX-DU8602T RF interface is TNC female connector of 50Ω.3、Function and operating instruction3.1 BootingPress the button of ON/OFF to boot. LED indicator of ON is green, which means the voltage is normal, and the machine can work normally; if LED indicator of ON is red flash, which means the voltage is too low, low voltage protection has been worked; if LED indicator of ON is red, which means the voltage is too high, overvoltage protection has been worked.3.2 High/Low RF power switchingPressing the button of PWR for switching RF power level between high and low. If you choose high power, LED indicator of PWR will turn red; if you choose low power, LED indicator of PWR will turn green.3.3 Transmitting channel switchingPressing the button of CHANNEL, 8 channels of “1-8”will be switched within each other, keep pressing for fast forward, digital tube display the current channel number.3.4 Channel DisplayOperation Mode: Display the channel number of “1-8”.Software upgraded to boot mode: display “b”.3.5 Low voltage indicatorWhen the voltage lower than 10V, radio modem will turn on protection, LED indicator of ON will be red flash; voltage back up to 10.2V, LED indicator show green, radio modem will return to normal work.3.6 Overvoltage indicatorWhen voltage higher than 16V, the radio modem will turn on protection, LED indicator of ON turn red; voltage back down to 15.8V, LED indicator will show green, radio modem will return to work normal.3.7 Data transmitting indicatorWhen data transmitting, LED indicator of TX will turn red flash.4、Radio setting4.1 Choose portsOpen the configured software, choose the corresponding port, and the serial baud rate change to 19200.4.2 Entry the configuration modeConnecting the power line and serial port line, which confirmed to be connected correctly, repower, press the button of “ON/OFF”for booting, LED indicator of ON show green. Within 3seconds, click the button to make the radio modem enter configuration mode, if digital tube of radio modem show “C”, or the progress bar show “Connect Success”,it means that the radio modem has entered to the configuration mode.4.3 Read the radio modem parameterWhen the radio is in the configuration mode, you can click the button to read the radio modem parameter. the progress bar show “Read Success”,it means that all the radio modem parameter has been read out.4.4 Configuring the radio modem parameter4.3.1 Configuring the customed frequency, default frequency setting are as follows:Click the button,the tx frequency of channel1-channel8 will revert to the default frequency.4.3.2 Configuring the protocol typeConfiguring the protocol type optional TRIMTALK、TRIMMARK3、TRANSEOT.4.3.3 Configuring the current channel ch1-ch84.3.4 Configuring the serial baud rate optional 9600,19200,38400,57600,115200 bps. (Note: if you want to reconnect radio modem after modifying the baud rate of serial port, you have to modify the serial baudrate here.4.3.5 Configuring the Link baudrate.The default link baudrate is 9600bps,you can select a different rate from the list.4.3.6 write the radio modem parameterClick the button to overwrite the radio’s current configuration. The progress bar show “Write Success”,it means that all the radio modem parameter has been written..4.4 Finish to exit the configuration modeClick the button to exit configuration mode, the digital tube of radio modem will show the current channel number.5.5 Import and export configurationClick the button to write a configuration file to a selected location on yourcomputer.Click the button to import a configuration file to a selected location on your computer.5、Software upgrading1）connecting the power data line, serial line of DB9 connected to computer. Pressing two buttons of “Channel”and “PWR”simultaneously before power on, and then pressing the button of “ON/OFF” to turn on the machine, LED indicator of “ON” show green. Checking and confirming digital tube show “b”, entering the upgrading mode.2）Open the Harxon Configration tool, choose the corresponding port, choose serial baud rate 115200.3)Select the menu file->upgrade firmware4）Choose the upgrading file “******.dwn” in the file, click the button “open” to start the firmware upgrading. Please don’t break off operation in the process of upgrading!5）After finishing the upgrading, The progress bar show “Upgrade Firmware Success”,it means that upgrade operation has been completed., radio modem resetting, digital tube show bright, whichmeans you upgrade successfully.6、Technical SpecificationsOperation Voltage: DC 9.0V~16VFCC Radiation Exposure StatementThis equipment complies with FCC radiation exposure limits set forth for a controlled environment. This equipment should be installed and operated with minimum distance 2.30m between the radiator & your body.Only service personnel have access to the programming capabilities.The end users in all these cases must not be able to program the radios.。

Hu-23HX80 Series HX80 Series is a family of humidity probes that offers a variety of measurement parameters with precision accuracy: RH,temperature, dew point, pressure (psia), ppmv, ppmw, gr/lbs, etc.The probe is easily adaptable for most applications including high temperature and high pressure conditions.The HX85A is a humidity/ temperature stainless steel probe with a stainless steel sinter filter, RS232 and 0 to 10 Vdc outputs, RH measurement range is 5 to 95% with an accuracy of ±1%,operating temperature -20 to 120°C (-4 to 248°F), dew point range -40 to 60°C (-40 to 140°F), default outputs: RH, temperature and dew point.The HX85BA is a humidity/temperature/barometric pressure stainless steel probe with a stainless steel sinter filter, RS232and 0 to 10 Vdc outputs, RH measurement range is 5 to 95%with an accuracy of ±1%, dew point range -40 to 60°C (-40 to 140°F),pressure range is (barometric pressure, 20 to 1100 mb, operating temperature -20 to 120°C (-4 to 248°F), default outputs:DP, temperature and pressure.The HXP85 is a humidity/temperature/high pressure stainless steel probe with a stainless steel sinter filter, RS232 and 0 to 10 Vdcoutputs, RH measurement range is 5 to 95% with an accuracy of ±1%, dew point range -40 to 60°C (-40 to 140°F), pressure range is 0 to 200 psia, operating temperature -20 to 120°C (-4 to 248°F), defaultoutputs: DP, temperature and pressure.The HX86 is a remote [1.8 m (6')cable] humidity/high temperaturestainless steel probe with astainless steel sinter filter, RS232and 4 to 20 mA outputs, RHmeasurement range is 5 to 95%with an accuracy of ±1%, dew pointrange -40 to 60°C (-40 to 140°F),operating temperature -20 to 120°C(-4 to 248°F), default outputs:RH, temperature and dew point,display included.HXB86 is a remote [1.8 m (6')cable] humidity/high temperature/barometric pressure stainless steelprobe with a stainless steel sinterfilter, RS232 and 4 to 20 mAoutputs, RH measurement range is5 to 95% with an accuracy of ±1%,dew point range -40 to 60°C(-40 to 140°F), pressure range is (barometric pressure, 20 to 1100 mb,operating temperature-20 to 120°C (-4 to 248°F), defaultoutputs: DP, temperature andpressure, display included.HXP86 is a remote [1.8 m (6')cable] humidity/high temperature/pressure stainless steel probe with a stainless steel sinterfilter, RS232 and 4 to 20 mA outputs, RH measurement range is 5 to 95% with an accuracy of ±1%, dew point range -40 to 60°C (-40 to 140°F), pressure range is 0 to 200 psia, operating temperature -20 to 120°C (-4 to 248°F), default outputs: DP, temperature and pressure, display included.The HX86N is a remote [1.8 m (6')cable] humidity/high temperature stainless steel probe with a stainless steel sinter filter, RS232and 0 to 10 Vdc outputs, RH measurement range is 5 to 95%with an accuracy of ±1%, dew point range -40 to 60°C (-40 to 140°F), operating temperature -20 to 120°C (-4 to 248°F), default outputs:RH, temperature and DP.HX85A, shown much smaller than actual size.Environmental/Process Air Transmitters RH/Temperature and Dew Point or Pressure OutputsCommon Specifications RH Accuracy: ±1% RH Temp Accuracy: ±0.5°C Electrical Outputs 0 to 10 Vdc (x3) @ 10 mA max Temp Measurement Range: -20 to 120°C (-4 to 248°F) RH Measurement Range: 5 to 95% Dew Point: -40 to 60°C (-40 to 140°F)Serial Output (All Units): RS232C to DTE device, 19.2 kilobaud, 8 bits data, 1 stop bit, no parity; RS232C (bi-directional) Power Requirements: 18 to 30 Vdc unregulated, 50 mA max Dimensions: Sensor: 19 x 203 mm (3⁄4 x 8") Cable Length: 1.8 m (6'); consult factory for longer lengths Electronics Module Outside Dimensions: 13 H x 9.4 W x 5.6 cm D (5.1 x 3.7 x 2.2") Mounting Centers: 11.5 x 7.9 cm (4.53 x 3.11") Sensor Pressure Rating: 200 psia max Sensor Sintered Filter: 40 microns Material: Stainless steel HX85A (Sensor Only) Measured Parameters: RH/temp Output Information: RH, temp, DP Electrical Outputs:0 to 10 Vdc (x3)Hu-24HX85BA (Sensor Only) Measured Parameters: RH/temp/barometric pressure Pressure Measurement Range: 10 to 1100 mb Pressure Accuracy: ±5 mb Output Information: RH, temp, pressure Electrical Outputs: 0 to 10 Vdc (x3)HX85PA (Sensor Only) Measured Parameters: RH/temp/ high pressure Pressure Measurement Range:0 to 200 psia Pressure Accuracy: ±0.75 psiOutput Information: RH, temp, pressureElectrical Outputs:0 to 10 Vdc (x3) HX86A (Sensor with Electronics Module)Measured Parameters: RH/high tempOutput Information: RH, temp, DPElectrical Outputs: 4 to 20 mA (x3)Alarm Relays: (x2)Digital Display: LCD, 2-lineHX86PA (Sensor with Electronics Module)Measured Parameters: RH/high temp/absolute pressure Pressure Measurement Range: 0 to 200 psiaPressure Accuracy: ±0.75 psiOutput Information: RH, temp, pressureElectrical Outputs: 4 to 20 mA (x3)Alarm Relays: (x2)Ordering Examples: HXP85PA, RH/temp and pressure transmitter with 0 to 10 Vdc outputs, and PSU-93, unregulated power supply, 16 to 23 Vdc, 300 mA max, screw terminal.HX86PA, RH/high temp and pressure transmitter with 4 to 20 mA outputs, and PSU-93, unregulated power supply, 16 to 23 Vdc, 300 mA max,screw terminal.HXB86BA (Sensor with Electronics Module)Measured Parameters: RH/high temp/barometric pressure Pressure Measurement Range: 10 to 1100 mb Pressure Accuracy: ±5 mbOutput Information: RH, temp, pressureElectrical Outputs: 4 to 20 mA (x3)Alarm Relays: (x2)Digital Display: LCD, 2-lineHX86N (Sensor Only) Measured Parameters: RH/high temp Output Information: RH, temp, DP Electrical Outputs: 0 to 10 Vdc (x3)HX86A。

Hydra II C测汞仪操作手册编号: 150-00282版本: G1声明本手册适用于已接受Hydra II C测汞仪培训的专业人员。

虽然Teledyne Leeman Labs 对Hydra II C 测汞仪的设计能保证使用安全, 但未经培训或不熟悉仪器的人员不得擅自进行操作。

不要在Hydra II C操作过程中拆卸外壳，加热炉高温可能会烫伤操作人员。

氧气用于加速化学物质分解，促进燃烧。

如未按本手册对Hydra II C进行操作，可能会造成仪器损坏或操作人员受到伤害。

不要让手指或其他物体接触运行过程中的样品舟升降台和进样针，否则会导致人员伤害或仪器损坏。

在操作设备时，请佩戴安全眼镜并穿着实验服。

不同的样品类型可能需要采取不同的安全措施。

操作人员须采取适当的安全措施以保证自身安全。

警告–当使用Hydra II C对可燃物如汽油或爆炸物进行分析时，需采取比手册中更高要求的操作程序和安全措施。

对爆炸物的分析过程必须满足Hydra II C 操作手册和当地政府的安全条例。

必须强调的是，当采用Hydra II C分析挥发性或不稳定的物质时，必须在防爆通风橱内进行操作。

根据分析样品的不同，需要采取一些其他的预防措施，操作人员需保证Hydra II C在安全环境下运行。

记住，样品在石英材料构成的封闭空间内在高温条件下与纯氧接触！Teledyne Leeman Labs 不保证Hydra II C 在分析易爆物质时的安全性。

Teledyne Leeman Labs 对Hydra II C的设计满足EN 61010-1:2001标准和CE 安全需求。

2目录1声明2目录3如何使用手册4安全说明4.1 Hydra II C安全标示4.2Hydra II C安全项目综述.5协定5.1商标6安装综述7快速安装综述8接收& 开箱接收单9系统描述10安装10.1设置(电路部分)10.2设置(气路部分)10.3天平联机设置10.3.1综述10.4第三方计算机软件与驱动安装10.5氧气隔板安装10.5.1氧气隔板安装综述10.6催化管安装10.7催化管活化10.8开机10.9关机11操作(硬件)11.1手动操作(单个样品)11.2自动进样器操作(多个样品) 12操作(软件)12.1Envoy 软件显示界面12.2菜单栏12.3工具栏12.4导航面板12.5详细信息区域12.5.1方法列表12.5.2检测序列列表12.5.3分析列表12.6状态栏12.7方法开发指导12.7.1综述使用仪器控制12.7.1.1自动进样器12.7.1.2加热炉温度和时间设置12.7.1.3光源& 检测器控制12.7.1.4气体控制12.7.1.5基于方法的分析程序12.7.2校准12.7.3添加标准物质到标物库12.7.4添加核查标样(QC) 到标物库12.7.5为自动分析创建检测序列12.8分析12.8.1运行标准物质检测12.8.2运行样品检测(Unknown)12.8.3运行性能核查标样12.8.4运行检测序列12.8.5中止检测序列12.8.6在自动检测过程中添加有限样品进行检测12.8.7查看分析结果12.8.8隐藏结果12.8.9查看隐藏结果12.9控制表(SPCC)12.10报告12.11重新计算13系统确认13.1快速确认方法13.2详细确认方法13.2.1HYDRA II C确认报告13.3用于确认测试的残留计算14方法开发14.1设计初步方法14.2高硫或高卤素类样品方法优化14.3优化气体消耗14.4方法开发流程图15维护15.1自动定期维护15.2样品舟使用和更换15.2.1样品舟净化15.2.2什么时候样品舟不能使用?15.3催化剂更换15.4催化剂活化15.5催化剂活化(新装机)15.6汞齐更换15.7汞灯更换15.8光学组件维护15.8.1光学池和UV窗清洁15.8.2反射镜清洁15.9自动进样器维护15.10进样叉维护15.11清洁加热炉15.12更换Teflon 内衬管15.13检查外部气路和接头.15.14更换保险丝16故障诊断16.1故障诊断工具16.1.1LED 指示灯模块16.1.1.1 AA LED模块16.1.1.2加热炉LED模块16.1.2仪器诊断16.1.2.1系统内置测试16.1.3实时记录表16.2标准物质检测没有或检测信号地低16.3样品检测没有或检测信号低16.4重复检测精度低16.5汞灯不亮16.6更换PN 122-00189-1汞灯组件详见16.7输出压力低16.8空白值过高16.9分析峰形异常16.10高汞样品检测后恢复16.11管路或光学池除湿16.12 CRM 报告不准确17服务17.1识别故障模块17.1.1 CVAAS 模块更换17.1.2加热炉模块更换17.1.3自动进样器模块更换18安装辅助18.1安装天平18.2自动进样器准直18.3自动进样器校准18.3.1进样叉调节18.3.2滑轨调节18.4驱动模块安装19 Envoy 计算方法20备件& 消耗品20.1备件20.2消耗品20.3标准物质20.4备件和组件3如何使用手册1新仪器?您要安装仪器吗? 请参阅下页安装综述部分。

H uEnvironmental/Process Air Transmitters RH and Temperature with Dew Point or Pressure Outputs U 316 SS HousingU ±1% RH AccuracyU ±0.5°C (1.0°F) Temperature AccuracyU H igh Temperature[120°C (248°F)]U R emovable StainlessSteel Sensor Cap U RS232 StandardU A djustable ¾ NPTFitting The HX80A Series is a family of humidity probes that offer a variety of measurement parameters with precision accuracy: relative humidity and temperature, with dew point or pressure. The probe is easily adaptable for most applications via a 3⁄4 NPT fitting that can beadjusted to any desired position, including high temperature and high pressure conditions. This remote type transmitter comes standard with a 1.8 m (6') cable and is ideally suited for many different applications such as environmental chambers, compressed air, and industrial applications. Models offer a stainless steel probe with a removable sinter stainless steel filter and RS232 (which allows for reading of data, scaling output, and for HX86A type units, changing the digital display and setting the alarms). All models have 3 outputs, with output 1 scaled for 0 to 100% RH, output 2 scaled for -20 to 120°C (-4 to 248°F), and output 3 determined by the model number. Output 3 for HX85A and HX86A is -60 to 40°C (-76 to 104°F) dew point, forHX85BA and HX86BA is 750 to 1100 mb, and for HX85PAand HX86PA is 0 to 200 psia. RH measurement range is 5 to 95% with an accuracy of ±1%. temperature accuracy is ±0.5°C (33°F).HX85A (probe only) models (HX85A, HX85BA, HX85PA) offer 0 to 10V signals on the outputs via a 1.8 m (6') cable. The HX86A models (HX86A, HX86BA,HX86PA) include a display box attached to the end of the cable from the probe, and offers a 2 line digital display, 2 alarms, three 4 to 20 mA output signals, and an RS232 serial output.SPECIFICATIONS RH Accuracy: ±1% RH RH Measurement Range: 5 to 95%Time Constant: <15 sec, air flow dependent (for 66.6% response)Temp Accuracy: ±0.5ºC (1.0°F)Temp Measurement Range: -20 to 120ºC (-4 to 248ºF) Pressure Rating: 317 kg (700 lb) (47.6 bar) max Serial Output: RS232C (bi-directional) to DTE device, 19.2 kilo baud, 8 bits data, 1 stop bit, no parity Power Requirements: 18 to 30 Vdcunregulated, 50 mA max HX85A shown smaller than actual size.HX86ASensor Dimensions: robe: 19 Dia. x 203 mm (3⁄4 x 8") Cable Length: 1.8 m (6')Filter: Sinter stainless steel (removable and cleanable)Probe Material: Stainless steelFitting: Adjustable ¾ NPTWeight: 0.9 kg (2 lb)Display Box (HX86A, HX86BA, HX86PA Only): Dimensions: 130 x 94 x 56 mm (5.1 x 3.7 x 2.2") Mounting Centers: 115 x 79 mm (4.52 x 3.11") Digital Display: LCD, 2-line Electrical Analog Outputs (HX85A, HX85BA, HX85PA Only):0 to 10 Vdc (x3) @ 10 mA max Electrical Outputs (HX86A, HX86BA, HX86PA Only): Analog Outputs: 4 to 20 mA (x3) into 500 Ω max Ordering Example: HX85A, RH/air temperature/dew point transmitter with 0 to 10 Vdc outputs, and PSR-24S, regulated power supply90 to 264 Vac input with 24 Vdc output.Alarm Relay (x2): Form A (SPST , NO) rated at 3 A/250 Vac Barometric Pressure (HX85BA, HX86BA Only): Range*: 750 to 1100 mb Accuracy: ±5 mb * Although the unit is scaled 750 to 1100 mb, the unit actual measurement range is 10 to 1100 mb and can be reprogrammed in the field if the range needs to be expanded. High Pressure (HX85PA, HX86PA Only): Range: 0 to 200 psia Accuracy: ±0.75 psi。

1模块简介FEL8802-NCSx系列嵌入式无线通信模块，集成了符合ZigBee/ZLL（ZigBee Lighting Link）标准的射频收发器和应用软件，具有超小尺寸、低成本、低功耗、组网灵活、性能可靠稳定等优点和特性，能够快速帮助用户实现无线传感器网络的组建。

2主要特性符合ZigBee Light Link（ZLL）标准高性能低功耗处理器o工作电流4mAo工作主频 16MHz集成2.4G低功耗ISM Band收发器o 3.5dBm发射功率o-100dBm接收灵敏度@250kb/so遵从IEEE802.15.4标准o RX电流6mAo TX电流14.5mA4路PWM输出，可实现RGBW色彩控制1.8V～3.6V工作电压4层PCB板设计超小尺寸：15*22*2mm3机械特性：3.1外观尺寸3.2俯视图3.3侧视图：灯类应用仅需要使用红色背景的8个引脚。

4电气特性4.1模块工作参数4.2模块射频特性5环境特性5.1环境特性6其他注意事项6.1安装说明为了确保最好的天线特性，避免LED灯的金属外壳对天线的收发特性产生影响，建议将该模块的天线部分远离灯具壳体或其他任何金属组件（包含PCB覆铜）5mm以上（如图6.1），并不可将天线放置于灯具金属密闭体之内。

对于需要将整个模块内置于金属密闭体内的应用，需考虑在金属体上设计预留部分无金属覆盖区域，用于天线信号发射或者选用带I-PEX接口的对应模块，配合外置天线使用。

图6.1：留空部分需超过5mm.7 命名规则FE L 88 03 – N P S B工作温度A -40°C ~ 125°CB -40°C ~ 85°CU= 超小S= 小M = 中等尺寸天线类型P = PCB 天线I= I-PEX 天线C= 陶瓷天线 功放N = 无功放P = 有功放模块尺寸产品子系列产品系列88 = 国际标准68 = 自主标准产品家族L = 照明前缀01 = Wi-Fi 02 = ZigBee 03 = BLE8版权声明本文档包含的所有信息均为上海福睿电子科技有限公司版权所有。