CN105823381A - Guidance ammunition laser receiver simulation testing device - Google Patents

Abstract

The invention discloses a guidance ammunition laser receiver simulation testing device which comprises an industrial personal computer, a router, an oscilloscope, a numerical multi-meter, a function generator, a programmable power supply, an option switch, a digital I/O module, a switching circuit, a switching control circuit and a pulse generating circuit. The guidance ammunition laser receiver simulation testing device has the beneficial results that the characteristic parameters, working time sequences, data communication and the like of a guidance ammunition laser receiver are inspected and simulated, and the entire testing condition is monitored; the configuration is flexible, the system can be large or small, and application is convenient and operation is simple; the guidance ammunition laser receiver simulation testing device has a high extendibility, on the strength of the guidance ammunition laser receiver simulation testing device, the testing requirement for new type ammunition can be met, and the testing on understudied digital guidance ammunition can also be completed; and the guidance ammunition laser receiver simulation testing device also has a self-checking function, and an equipment calibration port is reserved to facilitate periodic calibration of equipment.

Description

A kind of guided munition laser receiver simulation testing device

Technical field

The invention belongs to guided munition technical field of measurement and test, relate to a kind of guided munition laser receiver simulation testing device.

Background technology

Typically, guided munition product is the electronic product constituted based on ten million components and parts, or the Complex Structural System being made up of some assemblies and parts, and the Support of its Complex Structural System more levels off to a great system engineering.In this system engineering, it is important that a part be then test system, the test of the various parameters of its main completion system level product and functional verification, including reliability test, ground simulation etc..The parameter of guided munition and functional verification are the important component parts of test guided munition properties of product, are the basic means obtaining guided munition at different lifetime stage quality informations.

Laser receiver is one of important composition parts of guided munition guidance control system, and its parameter and functional verification are one of important process of test guided munition properties of product, and to grasping, guided munition guidance control system overall performance state is significant.

Summary of the invention

The technical problem to be solved is to provide a kind of guided munition laser receiver simulation testing device that laser receiver unit for electrical property parameters can carry out intelligent test.

Be employed technical scheme comprise that a kind of guided munition laser receiver simulation testing device by solving above-mentioned technical problem, it includes industrial computer, router, oscillograph, digital multimeter, functional generator, programmable power supply, selection switch, numeral I/O module, change-over circuit, conversion control circuit and pulse-generating circuit；Described change-over circuit includes the 101st to the 104th relay and the 1028th relay；

Described oscillograph, digital multimeter, programmable power supply, functional generator, selection switch are connected with described industrial computer by router respectively with numeral I/O module；

Described digital multimeter is connected with the described corresponding port selecting switch；

Described selection switch is connected with the corresponding port of laser receiver X1；

Described functional generator is connected with the corresponding port of described pulse-generating circuit；

Described numeral I/O module corresponding port with described pulse-generating circuit and conversion control circuit respectively is connected；

Described programmable power supply corresponding port with conversion control circuit and pulse-generating circuit respectively is connected；

The port DY1+ of described programmable power supply meets the power positive end JGZ of laser receiver X1 through the 1st normally opened contact KJG101-1 of described 101st relay；The port DY1-of described programmable power supply connect the power supply of laser receiver X1 through the 2nd normally opened contact KJG101-2 of described 101st relay holds JGND；

The port DY2-of described programmable power supply meets the power supply negative terminal JGF of laser receiver X1 through the 1st normally opened contact KJG1028-1 of described 1028th relay；The port DY2+ of described programmable power supply connect the power supply of laser receiver X1 through the 2nd normally opened contact KJG1028-2 of described 1028th relay holds JGND；

The transmitter control signal input JFX of laser receiver X1 connects the corresponding port of described pulse-generating circuit through the 1st normally opened contact KJG104-1 of described 104th relay；The transmitter signal ground end JFDG of laser receiver X1 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KJG104-2 of described 104th relay；

Described oscillographic port SB1 meets the signal output port JXC of laser receiver X1 through the 1st normally opened contact KJG103-1 of described 103rd relay；Described oscillographic port SB1D connect the power supply of laser receiver X1 through the 2nd normally opened contact KJG103-2 of described 103rd relay holds JGND；

The test signal ground end JXR of laser receiver X1 the 1st normally opened contact KJG102-1, the 2nd normally opened contact KJG102-2 of the 102nd relay through described 102nd relay successively holds JGND with connecing the power supply of laser receiver X1.

Described pulse-generating circuit includes phase inverter U11A, phase inverter U11B, enumerator U12, selector U13, switch module U14, resistance R90, the first Pulse Width Control relay, port MZ1 and port MGD1；

The outfan XF1 of functional generator connects 4 feet of described switch module U14 through the 1st normally opened contact KMZ1-1 of described first Pulse Width Control relay；

The outfan XF2 of functional generator connects 3 feet of described switch module U14 through the 2nd normally opened contact KMZ1-2 of described first Pulse Width Control relay；

The outfan XF1D of functional generator connects 11 feet of described switch module U14；

The outfan XF2D of functional generator connects 12 feet of described switch module U14；

6 feet of described switch module U14 and 9 feet connect outfan 4 foot of described phase inverter U11B respectively；

2 feet of described switch module U14 and 5 feet meet described port MZ1 respectively；

Described port MZ1 meets the transmitter control signal input JFX of laser receiver X1 through the 1st normally opened contact KJG104-1 of described 104th relay；

10 feet of described switch module U14 and 13 feet meet described port MGD1 respectively；

Described port MGD1 connect the transmitter signal of laser receiver X1 through the 2nd normally opened contact KJG104-2 of described 104th relay holds JFDG；

Input 1 foot of described phase inverter U11A meets the port CLK of numeral I/O module；

1 foot of described selector U13 to 4 feet meet port D3 ~ D0 that numeral I/O module is corresponding respectively；12 feet of described selector U13 to 15 feet meet port D7 ~ D4 that numeral I/O module is corresponding respectively；

Outfan 2 foot of described phase inverter U11A connects 5 feet of described enumerator U12；

3 feet of described enumerator U12 connect 11 feet of described selector U13；2 feet of described enumerator U12 connect 10 feet of described selector U13；6 feet of described enumerator U12 connect 9 feet of described selector U13；

7 feet of described enumerator U12 connect its 14 foot；

6 feet of described selector U13 connect input 3 foot of described phase inverter U11B；Outfan 4 foot of described phase inverter U11B meets the port+5V+ of programmable power supply through described resistance R90；

4 feet of described enumerator U12,11 feet and 16 feet meet the port+5V+ of programmable power supply respectively；15 feet of described enumerator U12,1 foot, 10 feet, 9 feet and 8 feet ground connection respectively；16 feet of described selector U13 meet the port+5V+ of programmable power supply；7 feet of described selector U13 and 8 feet ground connection respectively；

14 feet of described switch module U14 meet the port+15V+ of programmable power supply；8 feet of described switch module U14 meet the port-15V-of programmable power supply；7 feet of described switch module U14 meet port+15V-, port-15V+ and the port+5V-of programmable power supply respectively.

Described conversion control circuit includes buffer U2-5, rp-drive U2-11 and 9 foot exclusion RP1；

Input 1A ~ the 6A of described buffer U2-5 connects the corresponding port of described numeral I/O module respectively；Outfan 1Y ~ the 6Y of described buffer U2-5 connects corresponding input 6 foot ~ 1 foot of described rp-drive U2-11 respectively；The power end VCC of described buffer U2-5 meets the port+5V+ of described programmable power supply；The earth terminal GND ground connection of described buffer U2-5；9 feet of described rp-drive U2-11 meet the port+24V+ of described programmable power supply；The 8 foot ground connection of described rp-drive U2-11；

Wherein 6 not common end pins of the port+5V+ of the described programmable power supply of public termination of described 9 foot exclusion RP1, described 9 foot exclusion RP1 connect input 1 foot ~ 6 foot of the described rp-drive U1-11 of correspondence respectively；

The coil KJG101 of described 101st relay is connected between outfan 11 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KJG102 of described 102nd relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KJG103 of described 103rd relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KJG104 of described 104th relay is connected between outfan 14 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KJG1028 of described 1028th relay is connected between outfan 15 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KMZ1 of described first Pulse Width Control relay is connected between outfan 16 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11.

The model of described digital multimeter is 34405A；Described oscillographic model is DPO4034；The model of described functional generator is 33210A；The model of described programmable power supply is N6700B；The described model selecting switch is L4421A；The model of described numeral I/O module is L4450A.

The model of described phase inverter U11A and phase inverter U11B is 74LS04；The model of described enumerator U12 is 74LS193；The model of described selector U13 is 74LS151；The model of described switch module U14 is DG303AAK；The model of described buffer U2-5 is 74LS07；The model of described rp-drive U2-11 is MC1413.

The invention has the beneficial effects as follows: the present invention is that the characterisitic parameter to guided munition laser receiver, work schedule, data communication etc. check, simulate, and is monitored whole Test condition；Flexible configuration of the present invention, system is changeable, easy to use simple to operate；The present invention has stronger extensibility, based on the present invention, can complete the testing requirement of new model ammunition, it is also possible to meet in the test grinding digital guided munition；The present invention also has self-checking function, leaves equipment Alignment interface, facilitates equipment periodic calibration, and equipment can work more than 8 hours continuously.

Accompanying drawing explanation

Fig. 1 is the theory diagram of the present invention.

Fig. 2 is change-over circuit circuit theory diagrams.

Fig. 3 is pulse-generating circuit circuit theory diagrams.

Fig. 4 is conversion control circuit circuit theory diagrams.

Detailed description of the invention

From the embodiment shown in Fig. 1-4, it includes industrial computer, router, oscillograph, digital multimeter, functional generator, programmable power supply, selection switch, numeral I/O module, change-over circuit, conversion control circuit and pulse-generating circuit；Described change-over circuit includes the 101st to the 104th relay and the 1028th relay；

Described oscillograph, digital multimeter, programmable power supply, functional generator, selection switch are connected with described industrial computer by router respectively with numeral I/O module；

Described digital multimeter is connected with the described corresponding port selecting switch；

Described selection switch is connected with the corresponding port of laser receiver X1；

Described functional generator is connected with the corresponding port of described pulse-generating circuit；

Described numeral I/O module corresponding port with described pulse-generating circuit and conversion control circuit respectively is connected；

Described programmable power supply corresponding port with conversion control circuit and pulse-generating circuit respectively is connected；

The port DY1+ of described programmable power supply meets the power positive end JGZ of laser receiver X1 through the 1st normally opened contact KJG101-1 of described 101st relay；The port DY1-of described programmable power supply connect the power supply of laser receiver X1 through the 2nd normally opened contact KJG101-2 of described 101st relay holds JGND；

The port DY2-of described programmable power supply meets the power supply negative terminal JGF of laser receiver X1 through the 1st normally opened contact KJG1028-1 of described 1028th relay；The port DY2+ of described programmable power supply connect the power supply of laser receiver X1 through the 2nd normally opened contact KJG1028-2 of described 1028th relay holds JGND；

The transmitter control signal input JFX of laser receiver X1 connects the corresponding port of described pulse-generating circuit through the 1st normally opened contact KJG104-1 of described 104th relay；The transmitter signal ground end JFDG of laser receiver X1 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KJG104-2 of described 104th relay；

Described oscillographic port SB1 meets the signal output port JXC of laser receiver X1 through the 1st normally opened contact KJG103-1 of described 103rd relay；Described oscillographic port SB1D connect the power supply of laser receiver X1 through the 2nd normally opened contact KJG103-2 of described 103rd relay holds JGND；

The test signal ground end JXR of laser receiver X1 the 1st normally opened contact KJG102-1, the 2nd normally opened contact KJG102-2 of the 102nd relay through described 102nd relay successively holds JGND with connecing the power supply of laser receiver X1.

Described pulse-generating circuit includes phase inverter U11A, phase inverter U11B, enumerator U12, selector U13, switch module U14, resistance R90, the first Pulse Width Control relay, port MZ1 and port MGD1；

The outfan XF1 of functional generator connects 4 feet of described switch module U14 through the 1st normally opened contact KMZ1-1 of described first Pulse Width Control relay；

The outfan XF2 of functional generator connects 3 feet of described switch module U14 through the 2nd normally opened contact KMZ1-2 of described first Pulse Width Control relay；

The outfan XF1D of functional generator connects 11 feet of described switch module U14；

The outfan XF2D of functional generator connects 12 feet of described switch module U14；

6 feet of described switch module U14 and 9 feet connect outfan 4 foot of described phase inverter U11B respectively；

2 feet of described switch module U14 and 5 feet meet described port MZ1 respectively；

Described port MZ1 meets the transmitter control signal input JFX of laser receiver X1 through the 1st normally opened contact KJG104-1 of described 104th relay；

10 feet of described switch module U14 and 13 feet meet described port MGD1 respectively；

Described port MGD1 connect the transmitter signal of laser receiver X1 through the 2nd normally opened contact KJG104-2 of described 104th relay holds JFDG；

Input 1 foot of described phase inverter U11A meets the port CLK of numeral I/O module；

1 foot of described selector U13 to 4 feet meet port D3 ~ D0 that numeral I/O module is corresponding respectively；12 feet of described selector U13 to 15 feet meet port D7 ~ D4 that numeral I/O module is corresponding respectively；

Outfan 2 foot of described phase inverter U11A connects 5 feet of described enumerator U12；

3 feet of described enumerator U12 connect 11 feet of described selector U13；2 feet of described enumerator U12 connect 10 feet of described selector U13；6 feet of described enumerator U12 connect 9 feet of described selector U13；

7 feet of described enumerator U12 connect its 14 foot；

6 feet of described selector U13 connect input 3 foot of described phase inverter U11B；Outfan 4 foot of described phase inverter U11B meets the port+5V+ of programmable power supply through described resistance R90；

4 feet of described enumerator U12,11 feet and 16 feet meet the port+5V+ of programmable power supply respectively；15 feet of described enumerator U12,1 foot, 10 feet, 9 feet and 8 feet ground connection respectively；16 feet of described selector U13 meet the port+5V+ of programmable power supply；7 feet of described selector U13 and 8 feet ground connection respectively；

14 feet of described switch module U14 meet the port+15V+ of programmable power supply；8 feet of described switch module U14 meet the port-15V-of programmable power supply；7 feet of described switch module U14 meet port+15V-, port-15V+ and the port+5V-of programmable power supply respectively.

Described conversion control circuit includes buffer U2-5, rp-drive U2-11 and 9 foot exclusion RP1；

Input 1A ~ the 6A of described buffer U2-5 connects the corresponding port of described numeral I/O module respectively；Outfan 1Y ~ the 6Y of described buffer U2-5 connects corresponding input 6 foot ~ 1 foot of described rp-drive U2-11 respectively；The power end VCC of described buffer U2-5 meets the port+5V+ of described programmable power supply；The earth terminal GND ground connection of described buffer U2-5；9 feet of described rp-drive U2-11 meet the port+24V+ of described programmable power supply；The 8 foot ground connection of described rp-drive U2-11；

Wherein 6 not common end pins of the port+5V+ of the described programmable power supply of public termination of described 9 foot exclusion RP1, described 9 foot exclusion RP1 connect input 1 foot ~ 6 foot of the described rp-drive U1-11 of correspondence respectively；

The coil KJG101 of described 101st relay is connected between outfan 11 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KJG102 of described 102nd relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KJG103 of described 103rd relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KJG104 of described 104th relay is connected between outfan 14 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KJG1028 of described 1028th relay is connected between outfan 15 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KMZ1 of described first Pulse Width Control relay is connected between outfan 16 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11.

The model of described digital multimeter is 34405A；Described oscillographic model is DPO4034；The model of described functional generator is 33210A；The model of described programmable power supply is N6700B；The described model selecting switch is L4421A；The model of described numeral I/O module is L4450A.

The model of described phase inverter U11A and phase inverter U11B is 74LS04；The model of described enumerator U12 is 74LS193；The model of described selector U13 is 74LS151；The model of described switch module U14 is DG303AAK；The model of described buffer U2-5 is 74LS07；The model of described rp-drive U2-11 is MC1413.

Method of testing of the present invention is as follows:

A. testing current is consumed: industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 101st relay and the 1028th relay close, connects programmable power supply, and consuming electric current can read from power supply.Or transmit data to industrial computer process.

B. output signal frequency test: industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 103rd relay close, connects oscillograph, and signal frequency is obtained by oscillograph.

C. sensitivity test: industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 104th relay close, functional generator produces pulse command, digital multimeter read data.

D. threshold testing is led to: read by digital multimeter and upload industrial computer.

The input of pulse command circuit comes from functional generator, and for producing pulse, sine involves 21K signal, and signal is modulated by the switch module U14 that model is DG303AAK, produces the command signal required by measurand, has characteristics that

A) programmable DC regulated power supply, using the teaching of the invention it is possible to provide supply voltage, electric current is not less than 3A, can directly test electric current and voltage；

B) functional generator, reference frequency output: 0～10MHz, sinusoidal wave or square wave, output amplitude (peak-to-peak value) is up to 15V；

C) numeral I/O module: digital quantity input and the output on up to 128 tunnels；

D) digital multimeter, DC voltage measurement scope: 0～± 1000V, ac voltage measurement scope: 0～700V；Test accuracy is not less than 0.1%；

E) oscillograph, 4 passage inputs, 0～350MHz bandwidth, vertical factor is not less than 2%, and horizontal factor is not less than 3%, can store over the data of 1 minute；

F) fine phase meter, 1Hz～10MHz, test accuracy is more than 0.05 °；

G) switch is selected, no less than 20 tunnels.

Digital multimeter

Main test function is as follows:

Alternating voltage:

A) five kinds of ranges: 100.000mV, 1.00000V, 10.0000V, 100.000V, 750.00V；

B) measuring method: the real rms-of AC coupled is measured by the 400VDC bias on any range；

C) AC portion；

D) crest factor: be 5:1 during full scale to the maximum；

E) input impedance: < 100pF is in parallel with on all ranges for 1M Ω ± 2%；

F) input protection: be 750Vrms(HI terminal on all ranges).

DC voltage:

A) five kinds of ranges: 100.000mV, 1.00000V, 10.0000V, 100.000V, 1000.00V

B) measuring method: SigmaDelta hands over and turns straight transducer

C) input impedance: all ranges of 0 ~ 10M Ω (typical)

D) input protection: the 1000V(HI end on all ranges)

DC precision and AC precision the key technical indexes are shown in Tables 1 and 2.

Table 1DC precision

Table 2AC precision

Programmable power supply N6700B is a configurable platform, be can be combined by it and mates output module to create the power-supply system being best suitable for testing system requirements.Its available power level has 400W, 600W and 1,200W.Power is that the output module of 50W, 100W and 300W has different voltage and current combinations, and provides following Performance Characteristics:

A) there is programmable voltage and electric current, measurement and defencive function, make these economic modules be suitably for the system resource such as equipment under test or control equipment and power；

B) there is high-performance, automatically adjust range DC power supplier offer low noise, high accuracy, fast programming, advanced programming and measurement function, to accelerate testing progress；

C) it is precision DC stabilizer module, can provide in the range of milliampere and microampere and accurately control and measure have simultaneously by voltage and current digitized and these measured values to be captured the ability in similar oscillographic data buffer.

Output function:

A) programmable voltage and electric current: output voltage and electric current for gamut provide programing function completely.Output can be as constant voltage: (CV) or constant current (CC) source;

B) express command processes: the process time of each order is less than 1 millisecond;

C) quickly up/down programming: for automatically adjusting range and precision voltage source module, changing to the response time of 90% from the 10% of specified output is 1.5 milliseconds;

D) fast transient response: for automatically adjusting range and precision voltage source module, the transient response time is less than 100 microseconds;

E) low output noise: the output noise automatically adjusting range and precision voltage source module is usually 4mV peak-to-peak value, can match in excellence or beauty with linear power supply;

F) range function is automatically adjusted: automatically adjust range function and in the range of wider and continuous print voltage and current are arranged, maximum rated power can be produced for automatically adjusting range and precision voltage source module;

G) sequence is opened/is closed in output: the unlatching of each output/closedown delay feature makes you can be the unlatching/closedown sequence exported.

Defencive function:

A) remote voltage sensing: each output provides two remote sense terminals.When dispatching from the factory, remote sense wire jumper is contained in single bag offer；

B) voltage and current is measured: all output modules can measure output voltage and the electric current of themselves；

C) voltage, electric current and temperature protection: each output has overvoltage, overcurrent and overtemperature protection.Overvoltage and overcurrent protection can pass through programme-control.After activation, protection circuit can make voltage vanishing, exports disabled and reports guard mode.

Systemic-function

A) SCPI language: instrument is compatible with standard commands for programmable instruments (SCPI)；

B) optional three kinds of interfaces: the most built-in GPIB (IEEE-488), LAN and USB remote programming interface；

C) front panel I/O is arranged: can arrange GPIB and LAN parameter by menu from front panel；

D) built-in Web server: can directly control instrument by the explorer from computer by built-in Web server；

E) real time status information: front panel indicates the state of each output.Even if occurring to also indicate that during protectiveness shutdown；

F) module identification: preserve identification data in the nonvolatile memory of each module.Information includes module No., serial number and option.This information may be displayed on front panel.

The effect of 64 bit digital I/O modules: (1) provides clock for pulse command circuit；(2) it is that switch control circuit inputs control signal；(3) programming Control of pulse duty factor.Select switch to coordinate with digital multimeter and realize automatic multi-point sampler.Oscillographic effect: the output signal frequency of (1) Laser Measurement receiver；(2) electric magnet measuring steering wheel starts the time；(3) the self-oscillatory frequency of steering wheel and amplitude are measured.Digital multimeter is used for multimetering.Functional generator produces signal required during measuring.Programmable power supply is powered for the present invention.

The above embodiment is only the preferred embodiments of the present invention, and and non-invention possible embodiments exhaustive.For persons skilled in the art, any obvious change done to it on the premise of without departing substantially from the principle of the invention and spirit, within all should being contemplated as falling with the claims of the present invention.

Claims (5)

1. a guided munition laser receiver simulation testing device, it is characterised in that: include industrial computer, router, oscillograph, digital multimeter, functional generator, programmable power supply, selection switch, numeral I/O module, change-over circuit, conversion control circuit and pulse-generating circuit；Described change-over circuit includes the 101st to the 104th relay and the 1028th relay；

Described oscillograph, digital multimeter, programmable power supply, functional generator, selection switch are connected with described industrial computer by router respectively with numeral I/O module；

Described digital multimeter is connected with the described corresponding port selecting switch；

Described selection switch is connected with the corresponding port of laser receiver X1；

Described functional generator is connected with the corresponding port of described pulse-generating circuit；

Described numeral I/O module corresponding port with described pulse-generating circuit and conversion control circuit respectively is connected；

Described programmable power supply corresponding port with conversion control circuit and pulse-generating circuit respectively is connected；

The port DY1+ of described programmable power supply meets the power positive end JGZ of laser receiver X1 through the 1st normally opened contact KJG101-1 of described 101st relay；The port DY1-of described programmable power supply connect the power supply of laser receiver X1 through the 2nd normally opened contact KJG101-2 of described 101st relay holds JGND；

The port DY2-of described programmable power supply meets the power supply negative terminal JGF of laser receiver X1 through the 1st normally opened contact KJG1028-1 of described 1028th relay；The port DY2+ of described programmable power supply connect the power supply of laser receiver X1 through the 2nd normally opened contact KJG1028-2 of described 1028th relay holds JGND；

The transmitter control signal input JFX of laser receiver X1 connects the corresponding port of described pulse-generating circuit through the 1st normally opened contact KJG104-1 of described 104th relay；The transmitter signal ground end JFDG of laser receiver X1 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KJG104-2 of described 104th relay；

Described oscillographic port SB1 meets the signal output port JXC of laser receiver X1 through the 1st normally opened contact KJG103-1 of described 103rd relay；Described oscillographic port SB1D connect the power supply of laser receiver X1 through the 2nd normally opened contact KJG103-2 of described 103rd relay holds JGND；

The test signal ground end JXR of laser receiver X1 the 1st normally opened contact KJG102-1, the 2nd normally opened contact KJG102-2 of the 102nd relay through described 102nd relay successively holds JGND with connecing the power supply of laser receiver X1.

A kind of guided munition laser receiver simulation testing device the most according to claim 1, it is characterised in that: described pulse-generating circuit includes phase inverter U11A, phase inverter U11B, enumerator U12, selector U13, switch module U14, resistance R90, the first Pulse Width Control relay, port MZ1 and port MGD1；

The outfan XF1 of functional generator connects 4 feet of described switch module U14 through the 1st normally opened contact KMZ1-1 of described first Pulse Width Control relay；

The outfan XF2 of functional generator connects 3 feet of described switch module U14 through the 2nd normally opened contact KMZ1-2 of described first Pulse Width Control relay；

The outfan XF1D of functional generator connects 11 feet of described switch module U14；

The outfan XF2D of functional generator connects 12 feet of described switch module U14；

6 feet of described switch module U14 and 9 feet connect outfan 4 foot of described phase inverter U11B respectively；

2 feet of described switch module U14 and 5 feet meet described port MZ1 respectively；

Described port MZ1 meets the transmitter control signal input JFX of laser receiver X1 through the 1st normally opened contact KJG104-1 of described 104th relay；

10 feet of described switch module U14 and 13 feet meet described port MGD1 respectively；

Described port MGD1 connect the transmitter signal of laser receiver X1 through the 2nd normally opened contact KJG104-2 of described 104th relay holds JFDG；

Input 1 foot of described phase inverter U11A meets the port CLK of numeral I/O module；

1 foot of described selector U13 to 4 feet meet port D3 ~ D0 that numeral I/O module is corresponding respectively；12 feet of described selector U13 to 15 feet meet port D7 ~ D4 that numeral I/O module is corresponding respectively；

Outfan 2 foot of described phase inverter U11A connects 5 feet of described enumerator U12；

3 feet of described enumerator U12 connect 11 feet of described selector U13；2 feet of described enumerator U12 connect 10 feet of described selector U13；6 feet of described enumerator U12 connect 9 feet of described selector U13；

7 feet of described enumerator U12 connect its 14 foot；

6 feet of described selector U13 connect input 3 foot of described phase inverter U11B；Outfan 4 foot of described phase inverter U11B meets the port+5V+ of programmable power supply through described resistance R90；

4 feet of described enumerator U12,11 feet and 16 feet meet the port+5V+ of programmable power supply respectively；15 feet of described enumerator U12,1 foot, 10 feet, 9 feet and 8 feet ground connection respectively；16 feet of described selector U13 meet the port+5V+ of programmable power supply；7 feet of described selector U13 and 8 feet ground connection respectively；

14 feet of described switch module U14 meet the port+15V+ of programmable power supply；8 feet of described switch module U14 meet the port-15V-of programmable power supply；7 feet of described switch module U14 meet port+15V-, port-15V+ and the port+5V-of programmable power supply respectively.

A kind of guided munition laser receiver simulation testing device the most according to claim 2, it is characterised in that: described conversion control circuit includes buffer U2-5, rp-drive U2-11 and 9 foot exclusion RP1；

Input 1A ~ the 6A of described buffer U2-5 connects the corresponding port of described numeral I/O module respectively；Outfan 1Y ~ the 6Y of described buffer U2-5 connects corresponding input 6 foot ~ 1 foot of described rp-drive U2-11 respectively；The power end VCC of described buffer U2-5 meets the port+5V+ of described programmable power supply；The earth terminal GND ground connection of described buffer U2-5；9 feet of described rp-drive U2-11 meet the port+24V+ of described programmable power supply；The 8 foot ground connection of described rp-drive U2-11；

Wherein 6 not common end pins of the port+5V+ of the described programmable power supply of public termination of described 9 foot exclusion RP1, described 9 foot exclusion RP1 connect input 1 foot ~ 6 foot of the described rp-drive U1-11 of correspondence respectively；

The coil KJG101 of described 101st relay is connected between outfan 11 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KJG102 of described 102nd relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KJG103 of described 103rd relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KJG104 of described 104th relay is connected between outfan 14 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KJG1028 of described 1028th relay is connected between outfan 15 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KMZ1 of described first Pulse Width Control relay is connected between outfan 16 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11.

A kind of guided munition laser receiver simulation testing device the most according to claim 3, it is characterised in that: the model of described digital multimeter is 34405A；Described oscillographic model is DPO4034；The model of described functional generator is 33210A；The model of described programmable power supply is N6700B；The described model selecting switch is L4421A；The model of described numeral I/O module is L4450A.

A kind of guided munition laser receiver simulation testing device the most according to claim 4, it is characterised in that: the model of described phase inverter U11A and phase inverter U11B is 74LS04；The model of described enumerator U12 is 74LS193；The model of described selector U13 is 74LS151；The model of described switch module U14 is DG303AAK；The model of described buffer U2-5 is 74LS07；The model of described rp-drive U2-11 is MC1413.