CN205644108U - Gun -launched missile electricity performance simulation test conversion adapter device - Google Patents

Abstract

The utility model discloses a gun -launched missile electricity performance simulation test conversion adapter device, it includes converting circuit, conversion control circuit, adapter circuit and pulse -generating circuit, converting circuit includes laser receiver converting circuit, electron device converting circuit, steering wheel amplifier converting circuit, steering wheel part converting circuit, gyroscope converting circuit, electron time delay part converting circuit and guided missile body converting circuit, the beneficial effects are that: the utility model discloses can be to gun -launched missile's portion subassembly, whole, so part such as terrestrial system and whole electrical performance test provide the control of conversion adaptation, be the important component parts of test system.

Description

Gun launched missile electrical property emulation testing conversion adaptive device

Technical field

This utility model belongs to gun launched missile technical field of measurement and test, relates to a kind of gun launched missile electrical property emulation testing conversion adaptive 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.

Utility model content

Technical problem to be solved in the utility model is to provide a kind of gun launched missile electrical property emulation testing conversion adaptive device that gun launched missile electrical property can carry out intelligent test.

Be the technical scheme is that a kind of gun launched missile electrical property emulation testing conversion adaptive device by solving above-mentioned technical problem, it includes change-over circuit, conversion control circuit, adapter circuit and pulse-generating circuit；Described adapter circuit switchs with Missile Body X8, selection respectively and the corresponding port of programmable power supply is connected；The corresponding port of described pulse-generating circuit function generator respectively, programmable power supply and the first numeral I/O module is connected；Described conversion control circuit is connected with the second numeral I/O module and the corresponding port of programmable power supply respectively；

Described change-over circuit includes laser receiver change-over circuit, electronic installation change-over circuit, steering wheel amplifier change-over circuit, steering gear component change-over circuit, gyroscope change-over circuit, electronic delay parts change-over circuit and Missile Body change-over circuit；

Described laser receiver change-over circuit includes the 101st to the 104th relay and the 1028th relay；

The port DY1+ of 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 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 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；

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；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 through described 102nd relay successively holds JGND with connecing the power supply of laser receiver X1；

Described electronic installation change-over circuit includes the 105th to the 1012nd relay and the 1029th to the 1030th relay；

The port DY1+ of programmable power supply meets the power positive end DZZ of electronic installation X2 through the 1st normally opened contact KDZ107-1 of described 107th relay；The port DY1-of programmable power supply connect the power supply of electronic installation X2 through the 2nd normally opened contact KDZ107-2 of described 107th relay holds DZGD；

The port DY2-of programmable power supply meets the power supply negative terminal DZF of electronic installation X2 through the 1st normally opened contact KDZ1029-1 of described 1029th relay；The port DY2+ of programmable power supply connect the power supply of electronic installation X2 through the 2nd normally opened contact KDZ1029-2 of described 1029th relay holds DZGD；

The port DY3+ of programmable power supply meets the heavily benefit voltage input end CBDY of electronic installation X2 through the 1st normally opened contact KDZ106-1 of described 106th relay；The port DY3-of programmable power supply connect the power supply of electronic installation X2 through the 2nd normally opened contact KDZ106-2 of described 106th relay holds DZGD；

The port x WC of fine phase meter meets the detection of Z channel phases and the ripple amplitude test output terminal ZXW of electronic installation X2 through the 1st normally opened contact KDZ1012-1 of described 1012nd relay；The port x WJ of fine phase meter meets the-Z outfan Z-of electronic installation X2 through the 2nd normally opened contact KDZ1012-2 of described 1012nd relay；

The port x WC of fine phase meter meets the detection of Y channel phases and the ripple amplitude test output terminal YXW of electronic installation X2 through the 1st normally opened contact KDZ1011-1 of described 1011st relay；The port x WJ of fine phase meter meets the-Y outfan Y-of electronic installation X2 through the 2nd normally opened contact KDZ1011-2 of described 1011st relay；

The port CGD of fine phase meter connect the power supply of electronic installation X2 through the 1st normally opened contact KDZ1030-1 of described 1030th relay holds DZGD；The port JGD of fine phase meter connect the power supply of electronic installation X2 through the 2nd normally opened contact KDZ1030-2 of described 1030th relay holds DZGD；

The command signal input MZR of electronic installation X2 connects the corresponding port of described pulse-generating circuit through the 1st normally opened contact KDZ109-1 of described 109th relay；The command signal ground end ZLGD of electronic installation X2 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KDZ109-2 of described 109th relay；

The Y channel phases detection of electronic installation X2 and ripple amplitude test output terminal YXW connect the corresponding port of described pulse-generating circuit through the 1st normally opened contact KDZ1010-1 of described 1010th relay；The power supply ground end DZGD of electronic installation X2 connects the corresponding port of pulse-generating circuit through the 2nd normally opened contact KDZ1010-2 of described 1010th relay；

The Z channel phases detection of electronic installation X2 and ripple amplitude test output terminal ZXW connect the corresponding port of described pulse-generating circuit through the 1st normally opened contact KDZ105-1 of described 105th relay；The power supply ground end DZGD of electronic installation X2 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KDZ105-2 of described 105th relay；

The command signal input MZR of electronic installation X2 the 1st normally opened contact KDZ108-1, the 2nd normally opened contact KDZ108-2 through described 108th relay successively holds ZLGD with connecing the command signal of electronic installation X2；

Described steering wheel amplifier change-over circuit includes the 1013rd to the 1019th relay and the 1021st to the 1027th relay；

The port DY1+ of programmable power supply meets the power positive end DFZ of steering wheel amplifier X3 through the 1st normally opened contact KDF1013-1 of described 1013rd relay；The port DY1-of programmable power supply connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1013-2 of described 1013rd relay holds DFGD；

The power positive end DFZ of steering wheel amplifier X3 connect the power supply of steering wheel amplifier X3 through the 1st normally opened contact KDF1023-1 of described 1023rd relay holds DFGD；The power supply negative terminal DFF of steering wheel amplifier X3 connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1023-2 of described 1023rd relay holds DFGD；

The port DY2-of programmable power supply meets the power supply negative terminal DFF of steering wheel amplifier X3 through the 1st normally opened contact KDF1014-1 of described 1014th relay；The port DY2+ of programmable power supply connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1014-2 of described 1014th relay holds DFGD；

The pulse command end DF41 of steering wheel amplifier X3 connects the corresponding port of described pulse-generating circuit through the 1st normally opened contact KDF1021-1 of described 1021st relay；The power supply ground end DFGD of steering wheel amplifier X3 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KDZ1021-2 of described 1021st relay；

The pulse command end DF41 of steering wheel amplifier X3 connect the power supply of steering wheel amplifier X3 through the 1st normally opened contact KDF1015-1 of described 1015th relay holds DFGD；The pulse command end DF26 of steering wheel amplifier X3 connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1015-2 of described 1015th relay holds DFGD；

The pulse command end DF26 of steering wheel amplifier X3 connects the corresponding port of described pulse-generating circuit through the 1st normally opened contact KDF1022-1 of described 1022nd relay；The power supply ground end DFGD of steering wheel amplifier X3 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KDF1022-2 of described 1022nd relay；

The pulse command end DF40 of steering wheel amplifier X3 connects the corresponding port of described pulse-generating circuit through the 1st normally opened contact KDF1017-1 of described 1017th relay；The power supply ground end DFGD of steering wheel amplifier X3 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KDF1017-2 of described 1017th relay；

The port DY3+ of programmable power supply meets the pulse command end DF40 of steering wheel amplifier X3 through the 1st normally opened contact KDF1024-1 of described 1024th relay；The port DY3-of programmable power supply connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1024-2 of described 1024th relay holds DFGD；

The pulse command end DF40 of steering wheel amplifier X3 connect the power supply of steering wheel amplifier X3 through the 1st normally opened contact KDF1019-1 of described 1019th relay holds DFGD；The pulse command end DF25 of steering wheel amplifier X3 connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1019-2 of described 1019th relay holds DFGD；

The port DY3+ of programmable power supply meets the pulse command end DF25 of steering wheel amplifier X3 through the 1st normally opened contact KDF1027-1 of described 1027th relay；The port DY3-of programmable power supply connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1027-2 of described 1027th relay holds DFGD；

The pulse command end DF25 of steering wheel amplifier X3 connects the corresponding port of pulse-generating circuit through the 1st normally opened contact KDF1018-1 of described 1018th relay；The power supply ground end DFGD of steering wheel amplifier X3 connects the corresponding port of pulse-generating circuit through the 2nd normally opened contact KDF1018-2 of described 1018th relay；

The port DY3+ of programmable power supply meets the port DCD of described adapter circuit through the 1st normally opened contact KDF1016-1 of described 1016th relay；The port DY3-of programmable power supply connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1016-2 of described 1016th relay holds DFGD；

The multimeter port DF31 of steering wheel amplifier X3 connects the corresponding port of described adapter circuit through the 1st normally opened contact KDF1025-1 of described 1025th relay；The multimeter port DF37 of steering wheel amplifier X3 connects the corresponding port of described adapter circuit through the 2nd normally opened contact KDF1025-2 of described 1025th relay；

The multimeter port DF28 of steering wheel amplifier X3 connects the corresponding port of described adapter circuit through the 1st normally opened contact KDF1026-1 of described 1026th relay；The multimeter port DF35 of steering wheel amplifier X3 connects the corresponding port of described adapter circuit through the 2nd normally opened contact KDF1026-2 of described 1026th relay；

Described steering gear component change-over circuit includes the 1st to the 3rd relay, the 5th to the 7th relay and the 9th to the 14th relay；

The port DY1+ of programmable power supply meets the power positive end DBZ of steering gear component X5 through the 1st normally opened contact KDB1-1 of described 1st relay；The port DY1-of programmable power supply connect the power supply of steering gear component X5 through the 2nd normally opened contact KDB1-2 of described 1st relay holds DBGD；

The port DY2-of programmable power supply meets the power supply negative terminal DBF of steering gear component X5 through the 1st normally opened contact KDB9-1 of described 9th relay；The port DY2+ of programmable power supply connect the power supply of steering gear component X5 through the 2nd normally opened contact KDB9-2 of described 9th relay holds DBGD；

The power supply negative terminal DBF of steering gear component X5 connects the corresponding port of described adapter circuit through the 1st normally opened contact KDB6-1 of described 6th relay；The port DY2-of programmable power supply connects the corresponding port of described adapter circuit through the 2nd normally opened contact KDB6-2 of described 6th relay；

The z access port DB4 of steering gear component X5 connects the corresponding port of described pulse-generating circuit through the 1st normally opened contact KDB2-1 of described 2nd relay；The power supply ground end DBGD of steering gear component X5 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KDB2-2 of described 2nd relay；

The y access port DB5 of steering gear component X5 connects the corresponding port of described pulse-generating circuit through the 1st normally opened contact KDB3-1 of described 3rd relay；The power supply ground end DBGD of steering gear component X5 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KDB3-2 of described 3rd relay；

Oscillographic port SB1 connects the corresponding port of described adapter circuit through the 1st normally opened contact KDB7-1 of described 7th relay；Oscillographic port SB1D connect the power supply of steering gear component X5 through the 2nd normally opened contact KDB7-2 of described 7th relay holds DBGD；

The signal output port DB9 of steering gear component X5 connects the corresponding port of described adapter circuit through the 1st normally opened contact KDB5-1 of described 5th relay；The signal output port DB10 of steering gear component X5 connects the corresponding port of described adapter circuit through the 2nd normally opened contact KDB5-2 of described 5th relay；

The signal output port DB9 of steering gear component X5 connects the corresponding port of described adapter circuit through the 1st normally opened contact KDB10-1 of described 10th relay；The signal output port DB10 of steering gear component X5 connects the corresponding port of described adapter circuit through the 2nd normally opened contact KDB10-2 of described 10th relay；

The signal output port DB9 of steering gear component X5 connects the corresponding port of described adapter circuit through the 1st normally opened contact KDB13-1 of described 13rd relay；The signal output port DB10 of steering gear component X5 connects the corresponding port of described adapter circuit through the 2nd normally opened contact KDB13-2 of described 13rd relay；

Oscillographic port SB1 connects the corresponding port of described adapter circuit through the 1st normally opened contact KDB11-1 of described 11st relay；Oscillographic port SB1D connect the power supply of steering gear component X5 through the 2nd normally opened contact KDB11-2 of described 11st relay holds DBGD；

Oscillographic port SB1 connects the corresponding port of described adapter circuit through the 1st normally opened contact KDB12-1 of described 12nd relay；Oscillographic port SB1D connect the power supply of steering gear component X5 through the 2nd normally opened contact KDB12-2 of described 12nd relay holds DBGD；

The port DY2+ of described programmable power supply connect the power supply of steering gear component X5 through the 1st normally opened contact KDB14-1 of described 14th relay holds DBGD；

Described gyroscope change-over circuit includes the 15th to the 16th relay and the 19th to the 20th relay；

The port DY1+ of programmable power supply meets the+Uz port TL2 of gyroscope X6 through the 1st normally opened contact KTL19-1 of described 19th relay；The port DY1-of programmable power supply connect the power supply of gyroscope X6 through the 2nd normally opened contact KTL19-2 of described 19th relay holds TLGD；

The port DY2-of programmable power supply meets the-Uz port TL3 of gyroscope X6 through the 1st normally opened contact KTL15-1 of described 15th relay；The port DY2+ of programmable power supply connect the power supply of gyroscope X6 through the 2nd normally opened contact KTL15-2 of described 15th relay holds TLGD；

The port DY1+ of programmable power supply meets the+Uy port TL4 of gyroscope X6 through the 1st normally opened contact KTL20-1 of described 20th relay；The port DY1-of described programmable power supply connect the power supply of gyroscope X6 through the 2nd normally opened contact KTL20-2 of described 20th relay holds TLGD；

The port DY2-of programmable power supply meets the-Uy port TL5 of gyroscope X6 through the 1st normally opened contact KTL16-1 of described 16th relay；The port DY2+ of described programmable power supply connect the power supply of gyroscope X6 through the 2nd normally opened contact KTL16-2 of described 16th relay holds TLGD；

Described electronic delay parts change-over circuit includes the 17th relay, the 21st to the 24th relay and the 29th to the 30th relay；

The port DY2-of programmable power supply meets the power supply negative terminal mouth DYF of electronic delay parts X7 through the 1st normally opened contact KDY17-1 of described 17th relay；The port DY2+ of programmable power supply meets the GND port DYGD of electronic delay parts X7 through the 2nd normally opened contact KDY17-2 of described 17th relay；

Oscillographic port SB1 meets the outfan DYC of electronic delay parts X7 through the 1st normally opened contact KDY24-1 of described 24th relay；Oscillographic port SB1D meets the GND port DYGD of electronic delay parts X7 through the 2nd normally opened contact KDY24-2 of described 24th relay；

The port DY1+ of programmable power supply meets the power positive end mouth DYZ of electronic delay parts X7 through the 1st normally opened contact KDY22-1 of described 22nd relay；The port DY1-of programmable power supply meets the GND port DYGD of electronic delay parts X7 through the 2nd normally opened contact KDY22-2 of described 22nd relay；

The input DYR of electronic delay parts X7 connects the corresponding port of described pulse-generating circuit through the 1st normally opened contact KDY23-1 of described 23rd relay；The GND port DYGD of electronic delay parts X7 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KDY23-2 of described 23rd relay；

The port K21-1 of electronic delay parts X7 meets the port K21-2 of electronic delay parts X7 through the 1st normally opened contact KDY21-1 of described 21st relay；The port K21-3 of electronic delay parts X7 meets the port K21-4 of electronic delay parts X7 through the 2nd normally opened contact KDY21-2 of described 21st relay；

The port K29-1 of electronic delay parts X7 meets the port K29-2 of electronic delay parts X7 through the 1st normally opened contact KDY29-1 of described 29th relay；The port K29-3 of electronic delay parts X7 meets the port K29-4 of electronic delay parts X7 through the 2nd normally opened contact KDY29-2 of described 29th relay；

The port K30-1 of electronic delay parts X7 meets the port K30-2 of electronic delay parts X7 through the 1st normally opened contact KDY30-1 of described 30th relay；The port K30-3 of electronic delay parts X7 meets the port K30-4 of electronic delay parts X7 through the 2nd normally opened contact KDY30-2 of described 30th relay；

Described Missile Body change-over circuit includes the 25th to the 28th relay and the 18th relay；

The port DY1+ of programmable power supply meets the power positive end mouth DTZ of Missile Body X8 through the 1st normally opened contact KDT25-1 of described 25th relay；The port DY1-of programmable power supply meets the GND port DTGD of Missile Body X8 through the 2nd normally opened contact KDT25-2 of described 25th relay；

The port DY2-of programmable power supply meets the power supply negative terminal mouth DTF of Missile Body X8 through the 1st normally opened contact KDT18-1 of described 18th relay；The port DY2+ of programmable power supply meets the GND port DTGD of Missile Body X8 through the 2nd normally opened contact KDT18-2 of described 18th relay；

The fin test point port DT6 of Missile Body X8 connects the corresponding port of described pulse-generating circuit through the 1st normally opened contact KDT28-1 of described 28th relay；The GND port DTGD of Missile Body X8 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KDT28-2 of described 28th relay；

The z port DT4 of Missile Body X8 through the 1st normally opened contact KDT26-1 of described 26th relay connect Missile Body X8-Y-port DT7；The y port DT5 of Missile Body X8 meets the-Z port DT8 of Missile Body X8 through the 2nd normally opened contact KDT26-2 of described 26th relay；

The fin test point port DT6 of Missile Body X8 meets the VA port DT18 of Missile Body X8 through the 1st normally opened contact KDT27-1 of described 27th relay.

The beneficial effects of the utility model are: this utility model can carry out integration test to the unit for electrical property parameters of the parts of gun launched missile, entirety or even ground system etc., and the characterisitic parameter of parts, work schedule, data communication etc. are checked, simulate and be monitored whole Test condition.This system flexible configuration, system is changeable, easy to use simple to operate.

Accompanying drawing explanation

Fig. 1 is theory diagram of the present utility model.

Fig. 2 is laser receiver change-over circuit schematic diagram.

Fig. 3 is electronic installation change-over circuit schematic diagram.

Fig. 4 is steering wheel amplifier change-over circuit schematic diagram.

Fig. 5 is steering gear component change-over circuit schematic diagram.

Fig. 6 is gyroscope change-over circuit schematic diagram.

Fig. 7 is electronic delay parts change-over circuit schematic diagram.

Fig. 8 is Missile Body change-over circuit schematic diagram.

Fig. 9 is pulse-generating circuit schematic diagram.

Figure 10 is Missile Body adapter circuit schematic diagram.

Figure 11 is steering gear component adapter circuit schematic diagram.

Figure 12 is steering wheel amplifier adapter circuit schematic diagram.

Figure 13 is first control circuit schematic diagram.

Figure 14 is second control circuit schematic diagram.

Detailed description of the invention

From the embodiment shown in Fig. 1-14, it includes industrial computer, router, fine phase meter, digital multimeter, oscillograph, functional generator, programmable power supply, selection switch, the first numeral I/O module, the second numeral I/O module, change-over circuit, conversion control circuit, adapter circuit and pulse-generating circuit；

Described fine phase meter is connected with described industrial computer by USB interface；Described digital multimeter, oscillograph, functional generator, programmable power supply, selection switch, the first numeral I/O module are connected with described industrial computer by router respectively with the second numeral I/O module；

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

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

Described first numeral I/O module is connected with the corresponding port of described pulse-generating circuit；Described second numeral I/O module is connected with the corresponding port of described conversion control circuit；

Described programmable power supply corresponding port with described change-over circuit, conversion control circuit, adapter circuit and pulse-generating circuit respectively is connected；

Described switch corresponding port with laser receiver X1, electronic installation X2, steering wheel amplifier X3, steering gear component X5, gyroscope X6, electronic delay parts X7, Missile Body X8 and described adapter circuit respectively is selected to be connected；

Described adapter circuit is connected with the corresponding port of Missile Body X8；

Described change-over circuit corresponding port with laser receiver X1, electronic installation X2, steering wheel amplifier X3, steering gear component X5, gyroscope X6, electronic delay parts X7, Missile Body X8, pulse-generating circuit, adapter circuit, oscillograph and fine phase meter respectively is connected.

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 described 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 described functional generator connects 11 feet of described switch module U14；

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

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

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

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

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

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；

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

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 described programmable power supply through described resistance R90；

4 feet of described enumerator U12,11 feet and 16 feet meet the port+5V+ of described 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 described 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 described programmable power supply；8 feet of described switch module U14 meet the port-15V-of described programmable power supply；7 feet of described switch module U14 meet port+15V-, port-15V+ and the port+5V-of described programmable power supply respectively.

Described adapter circuit includes Missile Body adapter circuit, steering gear component adapter circuit and steering wheel amplifier adapter circuit；

Described Missile Body adapter circuit includes R10-R13 and port DT11A-DT14A；

Described resistance R13 is connected between the DT11 port of port DT11A and Missile Body X8；

Described resistance R12 is connected between the DT12 port of port DT12A and Missile Body X8；

Described resistance R11 is connected between the DT13 port of port DT13A and Missile Body X8；

Described resistance R10 is connected between the DT14 port of port DT14A and Missile Body X8；

Described port DT11A-DT14A connects the described corresponding port selecting switch respectively；

Described steering gear component adapter circuit includes resistance R1-R9, resistance R15-R22, electric capacity C1-C4, rheostat VR1-VR4, operational amplifier U16-U18, port DB9A-DB9E, port DB10A-DB10E, port ZYZ, port ZJY, port TQD, port DBFA and port DBFB;

Described rheostat VR1 connects with described resistance R1 and is followed by between described port ZYZ and described port DB9A；The sliding end of described rheostat VR1 is connected on the node of described rheostat VR1 and described resistance R1；

Described rheostat VR2 connects with described resistance R2 and is followed by between described port ZJY and described port DB10A；The sliding end of described rheostat VR2 is connected on the node of described rheostat VR2 and described resistance R2；

Described electric capacity C1 and electric capacity C2 connects and is followed by between the node of described rheostat VR1 and the node of described resistance R1 and described rheostat VR2 and described resistance R2；

Described resistance R4 and resistance R6 connects and is followed by between described port DB9B and port DB9C；

Described resistance R5 and resistance R7 connects and is followed by between described port DB10B and port DB10C；

Described electric capacity C3 and electric capacity C4 connects and is followed by between described resistance R4 and the node of resistance R6 and described resistance R5 and the node of resistance R7；

Described resistance R8 is connected between described port DB9D and port DB9E；

Described resistance R9 is connected between described port DB10D and port DB10E；

Described rheostat VR3 and rheostat VR4 connects and is followed by between described port DB9E and port DB10E；

The sliding end of described rheostat VR3 and rheostat VR4 connects the node of described rheostat VR3 and rheostat VR4 respectively；

The in-phase input end of described operational amplifier U16 meets described port DBFB through described resistance R15；

The in-phase input end of described operational amplifier U17 meets described port DBFA through described resistance R16；

The inverting input of described operational amplifier U16 connects the inverting input of described operational amplifier U17 through described resistance R17；

The outfan of described operational amplifier U16 connects the inverting input of described operational amplifier U18 through described resistance R20；

The outfan of described operational amplifier U17 connects the in-phase input end of described operational amplifier U18 through described resistance R22；

The output of described operational amplifier U18 terminates described port TQD；

Described resistance R3 is connected between described port DBFA and port DBFB；

Described resistance R18 is connected between inverting input and its outfan of described operational amplifier U16；

Described resistance R19 is connected between inverting input and its outfan of described operational amplifier U17；

Described resistance R21 is connected between inverting input and its outfan of described operational amplifier U18；

The positive power source terminal of described operational amplifier U16-U18 meets the port+15V+ of described programmable power supply respectively；The negative power end of described operational amplifier U16-U18 meets the port-15V-of described programmable power supply respectively；

Described port DB9E, port DB10E, port ZYZ and port ZJY connect the described corresponding port selecting switch respectively；Described port DB9A-DB9D, port DB10A-DB10D, port DBFA, port DBFB, port TQD connect the corresponding port of described change-over circuit respectively；

Described steering wheel amplifier adapter circuit includes resistance R31-R38, port DCD, port DK28, port DK35, port DK31, port DK37, port DC37, port DC31, port DC35 and port DC28；

Described resistance R31 and resistance R35 connects and is followed by between described port DC37 and port DCD；Described port DK37 is the node of described resistance R31 and resistance R35；

Described resistance R32 and resistance R36 connects and is followed by between described port DC31 and port DCD；Described port DK31 is the node of described resistance R32 and resistance R36；

Described resistance R33 and resistance R37 connects and is followed by between described port DC35 and port DCD；Described port DK35 is the node of described resistance R33 and resistance R37；

Described resistance R34 and resistance R38 connects and is followed by between described port DC28 and port DCD；Described port DK28 is the node of described resistance R34 and resistance R38；

Described port DC37, port DC31, port DC35 and port DC28 connect the described corresponding port selecting switch respectively；Described port DK28, port DK35, port DK31, port DK37 and port DCD connect the corresponding port of described change-over circuit respectively.

Described change-over circuit includes laser receiver change-over circuit, electronic installation change-over circuit, steering wheel amplifier change-over circuit, steering gear component change-over circuit, gyroscope change-over circuit, electronic delay parts change-over circuit and Missile Body change-over circuit；

Described laser receiver change-over circuit includes the 101st to the 104th relay and the 1028th relay；

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 meets the port MZ1 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 meets the port MGD1 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 through described 102nd relay successively holds JGND with connecing the power supply of laser receiver X1；

Described electronic installation change-over circuit includes the 105th to the 1012nd relay and the 1029th to the 1030th relay；

The port DY1+ of described programmable power supply meets the power positive end DZZ of electronic installation X2 through the 1st normally opened contact KDZ107-1 of described 107th relay；The port DY1-of described programmable power supply connect the power supply of electronic installation X2 through the 2nd normally opened contact KDZ107-2 of described 107th relay holds DZGD；

The port DY2-of described programmable power supply meets the power supply negative terminal DZF of electronic installation X2 through the 1st normally opened contact KDZ1029-1 of described 1029th relay；The port DY2+ of described programmable power supply connect the power supply of electronic installation X2 through the 2nd normally opened contact KDZ1029-2 of described 1029th relay holds DZGD；

The port DY3+ of described programmable power supply meets the heavily benefit voltage input end CBDY of electronic installation X2 through the 1st normally opened contact KDZ106-1 of described 106th relay；The port DY3-of described programmable power supply connect the power supply of electronic installation X2 through the 2nd normally opened contact KDZ106-2 of described 106th relay holds DZGD；

The port x WC of described fine phase meter meets the detection of Z channel phases and the ripple amplitude test output terminal ZXW of electronic installation X2 through the 1st normally opened contact KDZ1012-1 of described 1012nd relay；The port x WJ of described fine phase meter meets the-Z outfan Z-of electronic installation X2 through the 2nd normally opened contact KDZ1012-2 of described 1012nd relay；

The port x WC of described fine phase meter meets the detection of Y channel phases and the ripple amplitude test output terminal YXW of electronic installation X2 through the 1st normally opened contact KDZ1011-1 of described 1011st relay；The port x WJ of described fine phase meter meets the-Y outfan Y-of electronic installation X2 through the 2nd normally opened contact KDZ1011-2 of described 1011st relay；

The port CGD of described fine phase meter connect the power supply of electronic installation X2 through the 1st normally opened contact KDZ1030-1 of described 1030th relay holds DZGD；The port JGD of described fine phase meter connect the power supply of electronic installation X2 through the 2nd normally opened contact KDZ1030-2 of described 1030th relay holds DZGD；

The command signal input MZR of electronic installation X2 meets the port MZ1 of described pulse-generating circuit through the 1st normally opened contact KDZ109-1 of described 109th relay；The command signal ground end ZLGD of electronic installation X2 meets the port MGD1 of described pulse-generating circuit through the 2nd normally opened contact KDZ109-2 of described 109th relay；

The Y channel phases detection of electronic installation X2 and ripple amplitude test output terminal YXW meet the port MZ1 of described pulse-generating circuit through the 1st normally opened contact KDZ1010-1 of described 1010th relay；The power supply ground end DZGD of electronic installation X2 meets the port MGD1 of pulse-generating circuit through the 2nd normally opened contact KDZ1010-2 of described 1010th relay；

The Z channel phases detection of electronic installation X2 and ripple amplitude test output terminal ZXW meet the port MZ1 of described pulse-generating circuit through the 1st normally opened contact KDZ105-1 of described 105th relay；The power supply ground end DZGD of electronic installation X2 meets the port MGD1 of described pulse-generating circuit through the 2nd normally opened contact KDZ105-2 of described 105th relay；

The command signal input MZR of electronic installation X2 the 1st normally opened contact KDZ108-1, the 2nd normally opened contact KDZ108-2 through described 108th relay successively holds ZLGD with connecing the command signal of electronic installation X2；

Described steering wheel amplifier change-over circuit includes the 1013rd to the 1019th relay and the 1021st to the 1027th relay；

The port DY1+ of described programmable power supply meets the power positive end DFZ of steering wheel amplifier X3 through the 1st normally opened contact KDF1013-1 of described 1013rd relay；The port DY1-of described programmable power supply connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1013-2 of described 1013rd relay holds DFGD；

The power positive end DFZ of steering wheel amplifier X3 connect the power supply of steering wheel amplifier X3 through the 1st normally opened contact KDF1023-1 of described 1023rd relay holds DFGD；The power supply negative terminal DFF of steering wheel amplifier X3 connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1023-2 of described 1023rd relay holds DFGD；

The port DY2-of described programmable power supply meets the power supply negative terminal DFF of steering wheel amplifier X3 through the 1st normally opened contact KDF1014-1 of described 1014th relay；The port DY2+ of described programmable power supply connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1014-2 of described 1014th relay holds DFGD；

The pulse command end DF41 of steering wheel amplifier X3 meets the port MZ1 of described pulse-generating circuit through the 1st normally opened contact KDF1021-1 of described 1021st relay；The power supply ground end DFGD of steering wheel amplifier X3 meets the port MGD1 of described pulse-generating circuit through the 2nd normally opened contact KDZ1021-2 of described 1021st relay；

The pulse command end DF41 of steering wheel amplifier X3 connect the power supply of steering wheel amplifier X3 through the 1st normally opened contact KDF1015-1 of described 1015th relay holds DFGD；The pulse command end DF26 of steering wheel amplifier X3 connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1015-2 of described 1015th relay holds DFGD；

The pulse command end DF26 of steering wheel amplifier X3 meets the port MZ1 of described pulse-generating circuit through the 1st normally opened contact KDF1022-1 of described 1022nd relay；The power supply ground end DFGD of steering wheel amplifier X3 meets the port MGD1 of described pulse-generating circuit through the 2nd normally opened contact KDF1022-2 of described 1022nd relay；

The pulse command end DF40 of steering wheel amplifier X3 meets the port MZ1 of described pulse-generating circuit through the 1st normally opened contact KDF1017-1 of described 1017th relay；The power supply ground end DFGD of steering wheel amplifier X3 meets the port MGD1 of described pulse-generating circuit through the 2nd normally opened contact KDF1017-2 of described 1017th relay；

The port DY3+ of described programmable power supply meets the pulse command end DF40 of steering wheel amplifier X3 through the 1st normally opened contact KDF1024-1 of described 1024th relay；The port DY3-of described programmable power supply connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1024-2 of described 1024th relay holds DFGD；

The pulse command end DF40 of steering wheel amplifier X3 connect the power supply of steering wheel amplifier X3 through the 1st normally opened contact KDF1019-1 of described 1019th relay holds DFGD；The pulse command end DF25 of steering wheel amplifier X3 connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1019-2 of described 1019th relay holds DFGD；

The port DY3+ of described programmable power supply meets the pulse command end DF25 of steering wheel amplifier X3 through the 1st normally opened contact KDF1027-1 of described 1027th relay；The port DY3-of described programmable power supply connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1027-2 of described 1027th relay holds DFGD；

The pulse command end DF25 of steering wheel amplifier X3 meets the port MZ1 of pulse-generating circuit through the 1st normally opened contact KDF1018-1 of described 1018th relay；The power supply ground end DFGD of steering wheel amplifier X3 meets the port MGD1 of pulse-generating circuit through the 2nd normally opened contact KDF1018-2 of described 1018th relay；

The port DY3+ of described programmable power supply meets the port DCD of described steering wheel amplifier adapter circuit through the 1st normally opened contact KDF1016-1 of described 1016th relay；The port DY3-of described programmable power supply connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1016-2 of described 1016th relay holds DFGD；

The multimeter port DF31 of steering wheel amplifier X3 meets the port DK31 of described steering wheel amplifier adapter circuit through the 1st normally opened contact KDF1025-1 of described 1025th relay；The multimeter port DF37 of steering wheel amplifier X3 meets the port DK37 of described steering wheel amplifier adapter circuit through the 2nd normally opened contact KDF1025-2 of described 1025th relay；

The multimeter port DF28 of steering wheel amplifier X3 meets the port DK28 of described steering wheel amplifier adapter circuit through the 1st normally opened contact KDF1026-1 of described 1026th relay；The multimeter port DF35 of steering wheel amplifier X3 meets the port DK35 of described steering wheel amplifier adapter circuit through the 2nd normally opened contact KDF1026-2 of described 1026th relay；

Described steering gear component change-over circuit includes the 1st to the 3rd relay, the 5th to the 7th relay and the 9th to the 14th relay；

The port DY1+ of described programmable power supply meets the power positive end DBZ of steering gear component X5 through the 1st normally opened contact KDB1-1 of described 1st relay；The port DY1-of described programmable power supply connect the power supply of steering gear component X5 through the 2nd normally opened contact KDB1-2 of described 1st relay holds DBGD；

The port DY2-of described programmable power supply meets the power supply negative terminal DBF of steering gear component X5 through the 1st normally opened contact KDB9-1 of described 9th relay；The port DY2+ of described programmable power supply connect the power supply of steering gear component X5 through the 2nd normally opened contact KDB9-2 of described 9th relay holds DBGD；

The power supply negative terminal DBF of steering gear component X5 meets the port DBFB of described steering gear component adapter circuit through the 1st normally opened contact KDB6-1 of described 6th relay；The port DY2-of described programmable power supply meets the port DBFA of described steering gear component adapter circuit through the 2nd normally opened contact KDB6-2 of described 6th relay；

The z access port DB4 of steering gear component X5 meets the port MZ1 of described pulse-generating circuit through the 1st normally opened contact KDB2-1 of described 2nd relay；The power supply ground end DBGD of steering gear component X5 meets the port MGD1 of described pulse-generating circuit through the 2nd normally opened contact KDB2-2 of described 2nd relay；

The y access port DB5 of steering gear component X5 meets the port MZ1 of described pulse-generating circuit through the 1st normally opened contact KDB3-1 of described 3rd relay；The power supply ground end DBGD of steering gear component X5 meets the port MGD1 of described pulse-generating circuit through the 2nd normally opened contact KDB3-2 of described 3rd relay；

Described oscillographic port SB1 meets the port TQD of steering gear component adapter circuit through the 1st normally opened contact KDB7-1 of described 7th relay；Described oscillographic port SB1D connect the power supply of steering gear component X5 through the 2nd normally opened contact KDB7-2 of described 7th relay holds DBGD；

The signal output port DB9 of steering gear component X5 meets the port DB9A of described steering gear component adapter circuit through the 1st normally opened contact KDB5-1 of described 5th relay；The signal output port DB10 of steering gear component X5 meets the port DB10A of described steering gear component adapter circuit through the 2nd normally opened contact KDB5-2 of described 5th relay；

The signal output port DB9 of steering gear component X5 meets the port DB9B of described steering gear component adapter circuit through the 1st normally opened contact KDB10-1 of described 10th relay；The signal output port DB10 of steering gear component X5 meets the port DB10B of described steering gear component adapter circuit through the 2nd normally opened contact KDB10-2 of described 10th relay；

The signal output port DB9 of steering gear component X5 meets the port DB9D of described steering gear component adapter circuit through the 1st normally opened contact KDB13-1 of described 13rd relay；The signal output port DB10 of steering gear component X5 meets the port DB10D of described steering gear component adapter circuit through the 2nd normally opened contact KDB13-2 of described 13rd relay；

Described oscillographic port SB1 meets the port DB9C of described steering gear component adapter circuit through the 1st normally opened contact KDB11-1 of described 11st relay；Described oscillographic port SB1D connect the power supply of steering gear component X5 through the 2nd normally opened contact KDB11-2 of described 11st relay holds DBGD；

Described oscillographic port SB1 meets the port DB10C of described steering gear component adapter circuit through the 1st normally opened contact KDB12-1 of described 12nd relay；Described oscillographic port SB1D connect the power supply of steering gear component X5 through the 2nd normally opened contact KDB12-2 of described 12nd relay holds DBGD；

The port DY2+ of described programmable power supply connect the power supply of steering gear component X5 through the 1st normally opened contact KDB14-1 of described 14th relay holds DBGD；

Described gyroscope change-over circuit includes the 15th to the 16th relay and the 19th to the 20th relay；

The port DY1+ of described programmable power supply meets the+Uz port TL2 of gyroscope X6 through the 1st normally opened contact KTL19-1 of described 19th relay；The port DY1-of described programmable power supply connect the power supply of gyroscope X6 through the 2nd normally opened contact KTL19-2 of described 19th relay holds TLGD；

The port DY2-of described programmable power supply meets the-Uz port TL3 of gyroscope X6 through the 1st normally opened contact KTL15-1 of described 15th relay；The port DY2+ of described programmable power supply connect the power supply of gyroscope X6 through the 2nd normally opened contact KTL15-2 of described 15th relay holds TLGD；

The port DY1+ of described programmable power supply meets the+Uy port TL4 of gyroscope X6 through the 1st normally opened contact KTL20-1 of described 20th relay；The port DY1-of described programmable power supply connect the power supply of gyroscope X6 through the 2nd normally opened contact KTL20-2 of described 20th relay holds TLGD；

The port DY2-of described programmable power supply meets the-Uy port TL5 of gyroscope X6 through the 1st normally opened contact KTL16-1 of described 16th relay；The port DY2+ of described programmable power supply connect the power supply of gyroscope X6 through the 2nd normally opened contact KTL16-2 of described 16th relay holds TLGD；

Described electronic delay parts change-over circuit includes the 17th relay, the 21st to the 24th relay and the 29th to the 30th relay；

The port DY2-of described programmable power supply meets the power supply negative terminal mouth DYF of electronic delay parts X7 through the 1st normally opened contact KDY17-1 of described 17th relay；The port DY2+ of described programmable power supply meets the GND port DYGD of electronic delay parts X7 through the 2nd normally opened contact KDY17-2 of described 17th relay；

Described oscillographic port SB1 meets the outfan DYC of electronic delay parts X7 through the 1st normally opened contact KDY24-1 of described 24th relay；Described oscillographic port SB1D meets the GND port DYGD of electronic delay parts X7 through the 2nd normally opened contact KDY24-2 of described 24th relay；

The port DY1+ of described programmable power supply meets the power positive end mouth DYZ of electronic delay parts X7 through the 1st normally opened contact KDY22-1 of described 22nd relay；The port DY1-of described programmable power supply meets the GND port DYGD of electronic delay parts X7 through the 2nd normally opened contact KDY22-2 of described 22nd relay；

The input DYR of electronic delay parts X7 meets the port MZ1 of described pulse-generating circuit through the 1st normally opened contact KDY23-1 of described 23rd relay；The GND port DYGD of electronic delay parts X7 meets the port MGD1 of described pulse-generating circuit through the 2nd normally opened contact KDY23-2 of described 23rd relay；

The port K21-1 of electronic delay parts X7 meets the port K21-2 of electronic delay parts X7 through the 1st normally opened contact KDY21-1 of described 21st relay；The port K21-3 of electronic delay parts X7 meets the port K21-4 of electronic delay parts X7 through the 2nd normally opened contact KDY21-2 of described 21st relay；

The port K29-1 of electronic delay parts X7 meets the port K29-2 of electronic delay parts X7 through the 1st normally opened contact KDY29-1 of described 29th relay；The port K29-3 of electronic delay parts X7 meets the port K29-4 of electronic delay parts X7 through the 2nd normally opened contact KDY29-2 of described 29th relay；

The port K30-1 of electronic delay parts X7 meets the port K30-2 of electronic delay parts X7 through the 1st normally opened contact KDY30-1 of described 30th relay；The port K30-3 of electronic delay parts X7 meets the port K30-4 of electronic delay parts X7 through the 2nd normally opened contact KDY30-2 of described 30th relay；

Described Missile Body change-over circuit includes the 25th to the 28th relay and the 18th relay；

The port DY1+ of described programmable power supply meets the power positive end mouth DTZ of Missile Body X8 through the 1st normally opened contact KDT25-1 of described 25th relay；The port DY1-of described programmable power supply meets the GND port DTGD of Missile Body X8 through the 2nd normally opened contact KDT25-2 of described 25th relay；

The port DY2-of described programmable power supply meets the power supply negative terminal mouth DTF of Missile Body X8 through the 1st normally opened contact KDT18-1 of described 18th relay；The port DY2+ of described programmable power supply meets the GND port DTGD of Missile Body X8 through the 2nd normally opened contact KDT18-2 of described 18th relay；

The fin test point port DT6 of Missile Body X8 meets the port MZ1 of described pulse-generating circuit through the 1st normally opened contact KDT28-1 of described 28th relay；The GND port DTGD of Missile Body X8 meets the port MGD1 of described pulse-generating circuit through the 2nd normally opened contact KDT28-2 of described 28th relay；

The z port DT4 of Missile Body X8 through the 1st normally opened contact KDT26-1 of described 26th relay connect Missile Body X8-Y-port DT7；The y port DT5 of Missile Body X8 meets the-Z port DT8 of Missile Body X8 through the 2nd normally opened contact KDT26-2 of described 26th relay；

The fin test point port DT6 of Missile Body X8 meets the VA port DT18 of Missile Body X8 through the 1st normally opened contact KDT27-1 of described 27th relay.

Described conversion control circuit includes the first conversion control circuit and the second conversion control circuit；

Described first conversion control circuit includes buffer U1-5 ~ U1-10, rp-drive U1-11 ~ U1-15 and 9 foot exclusion RP1 ~ RP4；

Input 1A ~ the 6A of described buffer U1-5 connects the corresponding port of described second numeral I/O module respectively；Outfan 1Y ~ the 6Y of described buffer U1-5 connects corresponding input 6 foot ~ 1 foot of described rp-drive U1-11 respectively；The power end VCC of described buffer U1-5 meets the port+5V+ of described programmable power supply；The earth terminal GND ground connection of described buffer U1-5；9 feet of described rp-drive U1-11 meet the port+24V+ of described programmable power supply；The 8 foot ground connection of described rp-drive U1-11；

Input 1A ~ the 6A of described buffer U1-6 connects the corresponding port of described second numeral I/O module respectively；Outfan 1Y ~ the 5Y of described buffer U1-6 connects corresponding input 5 foot ~ 1 foot of described rp-drive U1-12 respectively；The outfan 6Y of described buffer U1-6 connects input 7 foot of described rp-drive U1-11；The power end VCC of described buffer U1-6 meets the port+5V+ of described programmable power supply；The earth terminal GND ground connection of described buffer U1-6；9 feet of described rp-drive U1-12 meet the port+24V+ of described programmable power supply；The 8 foot ground connection of described rp-drive U1-12；

Input 1A ~ the 6A of described buffer U1-7 connects the corresponding port of described second numeral I/O module respectively；Outfan 1Y ~ the 4Y of described buffer U1-7 connects corresponding input 4 foot ~ 1 foot of described rp-drive U1-13 respectively；Outfan 5Y ~ the 6Y of described buffer U1-7 connects input 7 foot ~ 6 foot of described rp-drive U1-12 respectively；The power end VCC of described buffer U1-7 meets the port+5V+ of described programmable power supply；The earth terminal GND ground connection of described buffer U1-7；9 feet of described rp-drive U1-13 meet the port+24V+ of described programmable power supply；The 8 foot ground connection of described rp-drive U1-13；

Input 5A ~ the 6A of described buffer U1-8 connects the corresponding port of described second numeral I/O module respectively；Outfan 5Y ~ the 6Y of described buffer U1-8 connects corresponding input 6 foot ~ 5 foot of described rp-drive U1-13 respectively；The power end VCC of described buffer U1-8 meets the port+5V+ of described programmable power supply；The earth terminal GND ground connection of described buffer U1-8；

Input 1A ~ the 6A of described buffer U1-9 connects the corresponding port of described second numeral I/O module respectively；Outfan 2Y ~ the 6Y of described buffer U1-9 connects corresponding input 7 foot ~ 3 foot of described rp-drive U1-14 respectively；The outfan 1Y of described buffer U1-9 connects input 1 foot of described rp-drive U1-15；The power end VCC of described buffer U1-9 meets the port+5V+ of described programmable power supply；The earth terminal GND ground connection of described buffer U1-9；9 feet of described rp-drive U1-14 meet the port+24V+ of programmable power supply；The 8 foot ground connection of described rp-drive U1-14；

Input 1A ~ the 4A of described buffer U1-10 connects the corresponding port of described second numeral I/O module respectively；Outfan 1Y ~ the 4Y of described buffer U1-10 connects corresponding input 7 foot ~ 4 foot of described rp-drive U1-15 respectively；The power end VCC of described buffer U1-10 meets the port+5V+ of described programmable power supply；The earth terminal GND ground connection of described buffer U1-10；9 feet of described rp-drive U1-15 meet the port+24V+ of programmable power supply；The 8 foot ground connection of described rp-drive U1-15；

The common port of described 9 foot exclusion RP1 ~ RP4 meets the port+5V+ connecing programmable power supply respectively respectively；Remaining 8 not common end pin of described 9 foot exclusion RP1 are corresponding respectively connects input 1 foot ~ 7 foot of described rp-drive U1-11 and input 1 foot of described rp-drive U1-12；Remaining 8 not common end pin of described 9 foot exclusion RP2 are corresponding respectively connects input 2 foot ~ 7 foot of described rp-drive U1-12 and input 1 foot of described rp-drive U1-13；Input 7 foot ~ 5 foot of remaining 8 not common end pin of described 9 foot exclusion RP3 corresponding input 4 foot ~ 7 foot, 1 foot and described rp-drive U1-14 meeting described rp-drive U1-15 respectively；

Wherein 6 not common end pin correspondences respectively of described 9 foot exclusion RP4 connect input 4 foot ~ 3 foot of described rp-drive U1-14 and input 5 foot ~ 2 foot of described rp-drive U1-13；

The coil KDB1 of described 1st relay is connected between outfan 11 foot and the port+24V+ of described programmable power supply of described rp-drive U1-11；

The coil KDB2 of described 2nd relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U1-11；

The coil KDB3 of described 3rd relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U1-11；

The coil KDB5 of described 5th relay is connected between outfan 14 foot and the port+24V+ of described programmable power supply of described rp-drive U1-11；

The coil KDB6 of described 6th relay is connected between outfan 15 foot and the port+24V+ of described programmable power supply of described rp-drive U1-11；

The coil KDB7 of described 7th relay is connected between outfan 16 foot and the port+24V+ of described programmable power supply of described rp-drive U1-11；

The coil KDB9 of described 9th relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U1-12；

The coil KMZ1 of described first Pulse Width Control relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U1-12；

The coil KDB10 of described 10th relay is connected between outfan 14 foot and the port+24V+ of described programmable power supply of described rp-drive U1-12；

The coil KDB11 of described 11st relay is connected between outfan 15 foot and the port+24V+ of described programmable power supply of described rp-drive U1-12；

The coil KDB12 of described 12nd relay is connected between outfan 16 foot and the port+24V+ of described programmable power supply of described rp-drive U1-12；

The coil KDB13 of described 13rd relay is connected between outfan 10 foot and the port+24V+ of described programmable power supply of described rp-drive U1-11；

The coil KDB14 of described 14th relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U1-13；

The coil KDB15 of described 15th relay is connected between outfan 14 foot and the port+24V+ of described programmable power supply of described rp-drive U1-13；

The coil KTL16 of described 16th relay is connected between outfan 15 foot and the port+24V+ of described programmable power supply of described rp-drive U1-13；

The coil KTL17 of described 17th relay is connected between outfan 16 foot and the port+24V+ of described programmable power supply of described rp-drive U1-13；

The coil KDY18 of described 18th relay is connected between outfan 10 foot and the port+24V+ of described programmable power supply of described rp-drive U1-12；

The coil KDT19 of described 19th relay is connected between outfan 11 foot and the port+24V+ of described programmable power supply of described rp-drive U1-12；

The coil KTL20 of described 20th relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U1-13；

The coil KDY21 of described 21st relay is connected between outfan 14 foot and the port+24V+ of described programmable power supply of described rp-drive U1-14；

The coil KDY22 of described 22nd relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U1-14；

The coil KDY23 of described 23rd relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U1-14；

The coil KDY24 of described 24th relay is connected between outfan 11 foot and the port+24V+ of described programmable power supply of described rp-drive U1-14；

The coil KDT25 of described 25th relay is connected between outfan 10 foot and the port+24V+ of described programmable power supply of described rp-drive U1-14；

The coil KDT26 of described 26th relay is connected between outfan 16 foot and the port+24V+ of described programmable power supply of described rp-drive U1-15；

The coil KDT27 of described 27th relay is connected between outfan 10 foot and the port+24V+ of described programmable power supply of described rp-drive U1-15；

The coil KDT28 of described 28th relay is connected between outfan 11 foot and the port+24V+ of described programmable power supply of described rp-drive U1-15；

The coil KDY29 of described 29th relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U1-15；

The coil KDY30 of described 30th relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U1-15；

Described second conversion control circuit includes buffer U2-5 ~ U2-10, rp-drive U2-11 ~ U2-15 and 9 foot exclusion RP5 ~ RP8；

Described second conversion control circuit is identical with the structure of described first conversion control circuit；

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 KDZ105 of described 105th relay is connected between outfan 15 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KDZ106 of described 106th relay is connected between outfan 16 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KDZ107 of described 107th relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U2-12；

The coil KDZ108 of described 108th relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U2-12；

The coil KDZ109 of described 109th relay is connected between outfan 14 foot and the port+24V+ of described programmable power supply of described rp-drive U2-12；

The coil KDZ1010 of described 1010th relay is connected between outfan 15 foot and the port+24V+ of described programmable power supply of described rp-drive U2-12；

The coil KDZ1011 of described 1011st relay is connected between outfan 16 foot and the port+24V+ of described programmable power supply of described rp-drive U2-12；

The coil KDZ1012 of described 1012nd relay is connected between outfan 10 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KDF1013 of described 1013rd relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U2-13；

The coil KDF1013 of described 1014th relay is connected between outfan 14 foot and the port+24V+ of described programmable power supply of described rp-drive U2-13；

The coil KDF1015 of described 1015th relay is connected between outfan 15 foot and the port+24V+ of described programmable power supply of described rp-drive U2-13；

The coil KDF1016 of described 1016th relay is connected between outfan 16 foot and the port+24V+ of described programmable power supply of described rp-drive U2-13；

The coil KDF1017 of described 1017th relay is connected between outfan 10 foot and the port+24V+ of described programmable power supply of described rp-drive U2-12；

The coil KDF1018 of described 1018th relay is connected between outfan 11 foot and the port+24V+ of described programmable power supply of described rp-drive U2-12；

The coil KDF1019 of described 1019th relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U2-13；

The coil KDF1021 of described 1021st relay is connected between outfan 14 foot and the port+24V+ of described programmable power supply of described rp-drive U2-14；

The coil KDF1022 of described 1022nd relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U2-14；

The coil KDF1023 of described 1023rd relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U2-14；

The coil KDF1024 of described 1024th relay is connected between outfan 11 foot and the port+24V+ of described programmable power supply of described rp-drive U2-14；

The coil KDF1025 of described 1025th relay is connected between outfan 10 foot and the port+24V+ of described programmable power supply of described rp-drive U2-14；

The coil KDF1026 of described 1026th relay is connected between outfan 16 foot and the port+24V+ of described programmable power supply of described rp-drive U2-15；

The coil KDF1027 of described 1027th relay is connected between outfan 10 foot and the port+24V+ of described programmable power supply of described rp-drive U2-15；

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

The coil KDZ1029 of described 1029th relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U2-15；

The coil KDZ1030 of described 1030th relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U2-15.

Described functional generator is to be made up of the function generation module that two models are 33210A and peripheral circuit thereof.

Described second numeral I/O module is to be made up of the 64 bit digital I/O chips that two models are L4450A and peripheral circuit thereof；Described first numeral I/O module is to be made up of the 64 bit digital I/O chips that model is L4450A and peripheral circuit thereof；It is described that to select switch be to be made up of the multidiameter option switch that two models are L4421A and peripheral circuit thereof.

Described programmable power supply is to be made up of the power module that two models are N6700B and peripheral circuit thereof.

The model of described fine phase meter is HK6620A；The model of described digital multimeter is 34405A；Described oscillographic model is DPO4034；

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；Described buffer U1-5 ~ U1-10, the model of buffer U2-5 ~ U2-10 are 74LS07；Described rp-drive U1-11 ~ U1-15, the model of rp-drive U2-11 ~ U2-15 are MC1413.

Laser receiver method of testing is as follows: 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.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.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.Logical threshold testing: read by digital multimeter and upload industrial computer.

Electronic device test method is as follows:

Industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 107th relay and the 1029th relay close, connects programmable power supply, and consuming electric current can read from power supply.Or transmit data to industrial computer process.Industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 1028th relay close, digital multimeter reads data.Industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 109th relay close, functional generator produces pulse command, digital multimeter read data.Industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 109th relay close, functional generator produces pulse command, digital multimeter read data.Industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 109th relay close, functional generator produces pulse command, digital multimeter read data.Industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, the normally opened contact making the 1011st relay, the 1012nd relay, the 105th relay and the 1010th relay closes, produced pulse command by functional generator, digital multimeter read data.Industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 106th relay close, digital multimeter reads data.

Steering wheel amplifier this utility model method of testing is as follows:

Industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 1013rd relay and the 1014th relay close, connects programmable power supply, and consuming electric current can read from programmable power supply；Or transmit data to industrial computer process.Industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 1016th relay and the 1025th relay close, connects power supply and adapter circuit；Industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 1017th relay close, accesses functional generator, produces test instruction, multimeter reads data U1.Industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 1026th relay and the 1018th relay close, and reads U2, calculate turn threshold=U1-U2 from digital multimeter.Industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 1021st relay and the 1022nd relay close, functional generator produces pulse command, industrial computer control digital multimeter and select to read corresponding port data.Industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 1021st relay and the 1022nd relay close, functional generator produces pulse command, industrial computer control digital multimeter and select to read corresponding port data.Industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 1021st relay and the 1022nd relay close, functional generator produces pulse command, industrial computer control digital multimeter and select to read corresponding port data.Industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 1017th relay and the 1018th relay close, functional generator produces pulse command；Industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 1024th relay and the 1027th relay close, switches on power, industrial computer control digital multimeter and select to read corresponding port data.Transmission coefficient: selected to read corresponding port resistance by digital multimeter.

Steering gear component method of testing is as follows:

Industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 1st relay and the 9th relay close, switches on power, and consuming electric current can read from power supply；Or transmit data to industrial computer process.Industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 5th relay close, connects adapter circuit；The normally opened contact making the 2nd relay and the 3rd relay closes, and connectivity function generator produces pulse command, digital multimeter read corresponding data.Industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 6th relay close, switches on power, connect adapter circuit and oscillograph, the normally opened contact making the 2nd relay and the 3rd relay closes, and produces pulse command, oscillograph read the startup time.Self-excited oscillatory frequency, amplitude and product value: industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, the normally opened contact making the 10th relay closes, logical adapter circuit and multimeter, connect oscillograph, multimeter and oscillograph read surveyed data.Null offset: industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 13rd relay close, reads multiplex numeral table data.

Gyroscope method of testing is as follows: industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 15th relay and the 19th relay close, reads digital multimeter magnitude of voltage；The normally opened contact making the 16th relay closes, then reads digital multimeter magnitude of voltage；Relatively twice magnitude of voltage, judges sensor states.

The method of testing that electronic delay parts input and output check is as follows: industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 17th relay and the 22nd relay close, switches on power；Being the normally opened contact Guan Bi of the 23rd relay, connectivity function generator produces pulse command；The normally opened contact making the 24th relay closes, and connects oscillograph, observes output situation.

Missile Body method of testing is as follows: the method for testing that Missile Body input and output check is as follows: industrial computer sends instruction by numeral I/O module transfer to conversion control circuit, makes the normally opened contact of the 18th relay and the 25th relay close, switches on power；The normally opened contact making the 26th relay and the 27th relay closes, short circuit respective terminal, reads and consume electric current from programmable power supply.

Claims (5)

1. a gun launched missile electrical property emulation testing conversion adaptive device, it is characterised in that: include change-over circuit, conversion control circuit, adapter circuit and pulse-generating circuit；Described adapter circuit switchs with Missile Body X8, selection respectively and the corresponding port of programmable power supply is connected；The corresponding port of described pulse-generating circuit function generator respectively, programmable power supply and the first numeral I/O module is connected；Described conversion control circuit is connected with the second numeral I/O module and the corresponding port of programmable power supply respectively；

Described change-over circuit includes laser receiver change-over circuit, electronic installation change-over circuit, steering wheel amplifier change-over circuit, steering gear component change-over circuit, gyroscope change-over circuit, electronic delay parts change-over circuit and Missile Body change-over circuit；

Described laser receiver change-over circuit includes the 101st to the 104th relay and the 1028th relay；

The port DY1+ of 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 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 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；

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；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 through described 102nd relay successively holds JGND with connecing the power supply of laser receiver X1；

Described electronic installation change-over circuit includes the 105th to the 1012nd relay and the 1029th to the 1030th relay；

The port DY1+ of programmable power supply meets the power positive end DZZ of electronic installation X2 through the 1st normally opened contact KDZ107-1 of described 107th relay；The port DY1-of programmable power supply connect the power supply of electronic installation X2 through the 2nd normally opened contact KDZ107-2 of described 107th relay holds DZGD；

The port DY2-of programmable power supply meets the power supply negative terminal DZF of electronic installation X2 through the 1st normally opened contact KDZ1029-1 of described 1029th relay；The port DY2+ of programmable power supply connect the power supply of electronic installation X2 through the 2nd normally opened contact KDZ1029-2 of described 1029th relay holds DZGD；

The port DY3+ of programmable power supply meets the heavily benefit voltage input end CBDY of electronic installation X2 through the 1st normally opened contact KDZ106-1 of described 106th relay；The port DY3-of programmable power supply connect the power supply of electronic installation X2 through the 2nd normally opened contact KDZ106-2 of described 106th relay holds DZGD；

The port x WC of fine phase meter meets the detection of Z channel phases and the ripple amplitude test output terminal ZXW of electronic installation X2 through the 1st normally opened contact KDZ1012-1 of described 1012nd relay；The port x WJ of fine phase meter meets the-Z outfan Z-of electronic installation X2 through the 2nd normally opened contact KDZ1012-2 of described 1012nd relay；

The port x WC of fine phase meter meets the detection of Y channel phases and the ripple amplitude test output terminal YXW of electronic installation X2 through the 1st normally opened contact KDZ1011-1 of described 1011st relay；The port x WJ of fine phase meter meets the-Y outfan Y-of electronic installation X2 through the 2nd normally opened contact KDZ1011-2 of described 1011st relay；

The port CGD of fine phase meter connect the power supply of electronic installation X2 through the 1st normally opened contact KDZ1030-1 of described 1030th relay holds DZGD；The port JGD of fine phase meter connect the power supply of electronic installation X2 through the 2nd normally opened contact KDZ1030-2 of described 1030th relay holds DZGD；

The command signal input MZR of electronic installation X2 connects the corresponding port of described pulse-generating circuit through the 1st normally opened contact KDZ109-1 of described 109th relay；The command signal ground end ZLGD of electronic installation X2 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KDZ109-2 of described 109th relay；

The Y channel phases detection of electronic installation X2 and ripple amplitude test output terminal YXW connect the corresponding port of described pulse-generating circuit through the 1st normally opened contact KDZ1010-1 of described 1010th relay；The power supply ground end DZGD of electronic installation X2 connects the corresponding port of pulse-generating circuit through the 2nd normally opened contact KDZ1010-2 of described 1010th relay；

The Z channel phases detection of electronic installation X2 and ripple amplitude test output terminal ZXW connect the corresponding port of described pulse-generating circuit through the 1st normally opened contact KDZ105-1 of described 105th relay；The power supply ground end DZGD of electronic installation X2 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KDZ105-2 of described 105th relay；

The command signal input MZR of electronic installation X2 the 1st normally opened contact KDZ108-1, the 2nd normally opened contact KDZ108-2 through described 108th relay successively holds ZLGD with connecing the command signal of electronic installation X2；

Described steering wheel amplifier change-over circuit includes the 1013rd to the 1019th relay and the 1021st to the 1027th relay；

The port DY1+ of programmable power supply meets the power positive end DFZ of steering wheel amplifier X3 through the 1st normally opened contact KDF1013-1 of described 1013rd relay；The port DY1-of programmable power supply connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1013-2 of described 1013rd relay holds DFGD；

The power positive end DFZ of steering wheel amplifier X3 connect the power supply of steering wheel amplifier X3 through the 1st normally opened contact KDF1023-1 of described 1023rd relay holds DFGD；The power supply negative terminal DFF of steering wheel amplifier X3 connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1023-2 of described 1023rd relay holds DFGD；

The port DY2-of programmable power supply meets the power supply negative terminal DFF of steering wheel amplifier X3 through the 1st normally opened contact KDF1014-1 of described 1014th relay；The port DY2+ of programmable power supply connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1014-2 of described 1014th relay holds DFGD；

The pulse command end DF41 of steering wheel amplifier X3 connects the corresponding port of described pulse-generating circuit through the 1st normally opened contact KDF1021-1 of described 1021st relay；The power supply ground end DFGD of steering wheel amplifier X3 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KDZ1021-2 of described 1021st relay；

The pulse command end DF41 of steering wheel amplifier X3 connect the power supply of steering wheel amplifier X3 through the 1st normally opened contact KDF1015-1 of described 1015th relay holds DFGD；The pulse command end DF26 of steering wheel amplifier X3 connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1015-2 of described 1015th relay holds DFGD；

The pulse command end DF26 of steering wheel amplifier X3 connects the corresponding port of described pulse-generating circuit through the 1st normally opened contact KDF1022-1 of described 1022nd relay；The power supply ground end DFGD of steering wheel amplifier X3 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KDF1022-2 of described 1022nd relay；

The pulse command end DF40 of steering wheel amplifier X3 connects the corresponding port of described pulse-generating circuit through the 1st normally opened contact KDF1017-1 of described 1017th relay；The power supply ground end DFGD of steering wheel amplifier X3 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KDF1017-2 of described 1017th relay；

The port DY3+ of programmable power supply meets the pulse command end DF40 of steering wheel amplifier X3 through the 1st normally opened contact KDF1024-1 of described 1024th relay；The port DY3-of programmable power supply connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1024-2 of described 1024th relay holds DFGD；

The pulse command end DF40 of steering wheel amplifier X3 connect the power supply of steering wheel amplifier X3 through the 1st normally opened contact KDF1019-1 of described 1019th relay holds DFGD；The pulse command end DF25 of steering wheel amplifier X3 connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1019-2 of described 1019th relay holds DFGD；

The port DY3+ of programmable power supply meets the pulse command end DF25 of steering wheel amplifier X3 through the 1st normally opened contact KDF1027-1 of described 1027th relay；The port DY3-of programmable power supply connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1027-2 of described 1027th relay holds DFGD；

The pulse command end DF25 of steering wheel amplifier X3 connects the corresponding port of pulse-generating circuit through the 1st normally opened contact KDF1018-1 of described 1018th relay；The power supply ground end DFGD of steering wheel amplifier X3 connects the corresponding port of pulse-generating circuit through the 2nd normally opened contact KDF1018-2 of described 1018th relay；

The port DY3+ of programmable power supply meets the port DCD of described adapter circuit through the 1st normally opened contact KDF1016-1 of described 1016th relay；The port DY3-of programmable power supply connect the power supply of steering wheel amplifier X3 through the 2nd normally opened contact KDF1016-2 of described 1016th relay holds DFGD；

The multimeter port DF31 of steering wheel amplifier X3 connects the corresponding port of described adapter circuit through the 1st normally opened contact KDF1025-1 of described 1025th relay；The multimeter port DF37 of steering wheel amplifier X3 connects the corresponding port of described adapter circuit through the 2nd normally opened contact KDF1025-2 of described 1025th relay；

The multimeter port DF28 of steering wheel amplifier X3 connects the corresponding port of described adapter circuit through the 1st normally opened contact KDF1026-1 of described 1026th relay；The multimeter port DF35 of steering wheel amplifier X3 connects the corresponding port of described adapter circuit through the 2nd normally opened contact KDF1026-2 of described 1026th relay；

Described steering gear component change-over circuit includes the 1st to the 3rd relay, the 5th to the 7th relay and the 9th to the 14th relay；

The port DY1+ of programmable power supply meets the power positive end DBZ of steering gear component X5 through the 1st normally opened contact KDB1-1 of described 1st relay；The port DY1-of programmable power supply connect the power supply of steering gear component X5 through the 2nd normally opened contact KDB1-2 of described 1st relay holds DBGD；

The port DY2-of programmable power supply meets the power supply negative terminal DBF of steering gear component X5 through the 1st normally opened contact KDB9-1 of described 9th relay；The port DY2+ of programmable power supply connect the power supply of steering gear component X5 through the 2nd normally opened contact KDB9-2 of described 9th relay holds DBGD；

The power supply negative terminal DBF of steering gear component X5 connects the corresponding port of described adapter circuit through the 1st normally opened contact KDB6-1 of described 6th relay；The port DY2-of programmable power supply connects the corresponding port of described adapter circuit through the 2nd normally opened contact KDB6-2 of described 6th relay；

The z access port DB4 of steering gear component X5 connects the corresponding port of described pulse-generating circuit through the 1st normally opened contact KDB2-1 of described 2nd relay；The power supply ground end DBGD of steering gear component X5 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KDB2-2 of described 2nd relay；

The y access port DB5 of steering gear component X5 connects the corresponding port of described pulse-generating circuit through the 1st normally opened contact KDB3-1 of described 3rd relay；The power supply ground end DBGD of steering gear component X5 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KDB3-2 of described 3rd relay；

Oscillographic port SB1 connects the corresponding port of described adapter circuit through the 1st normally opened contact KDB7-1 of described 7th relay；Oscillographic port SB1D connect the power supply of steering gear component X5 through the 2nd normally opened contact KDB7-2 of described 7th relay holds DBGD；

The signal output port DB9 of steering gear component X5 connects the corresponding port of described adapter circuit through the 1st normally opened contact KDB5-1 of described 5th relay；The signal output port DB10 of steering gear component X5 connects the corresponding port of described adapter circuit through the 2nd normally opened contact KDB5-2 of described 5th relay；

The signal output port DB9 of steering gear component X5 connects the corresponding port of described adapter circuit through the 1st normally opened contact KDB10-1 of described 10th relay；The signal output port DB10 of steering gear component X5 connects the corresponding port of described adapter circuit through the 2nd normally opened contact KDB10-2 of described 10th relay；

The signal output port DB9 of steering gear component X5 connects the corresponding port of described adapter circuit through the 1st normally opened contact KDB13-1 of described 13rd relay；The signal output port DB10 of steering gear component X5 connects the corresponding port of described adapter circuit through the 2nd normally opened contact KDB13-2 of described 13rd relay；

Oscillographic port SB1 connects the corresponding port of described adapter circuit through the 1st normally opened contact KDB11-1 of described 11st relay；Oscillographic port SB1D connect the power supply of steering gear component X5 through the 2nd normally opened contact KDB11-2 of described 11st relay holds DBGD；

Oscillographic port SB1 connects the corresponding port of described adapter circuit through the 1st normally opened contact KDB12-1 of described 12nd relay；Oscillographic port SB1D connect the power supply of steering gear component X5 through the 2nd normally opened contact KDB12-2 of described 12nd relay holds DBGD；

The port DY2+ of described programmable power supply connect the power supply of steering gear component X5 through the 1st normally opened contact KDB14-1 of described 14th relay holds DBGD；

Described gyroscope change-over circuit includes the 15th to the 16th relay and the 19th to the 20th relay；

The port DY1+ of programmable power supply meets the+Uz port TL2 of gyroscope X6 through the 1st normally opened contact KTL19-1 of described 19th relay；The port DY1-of programmable power supply connect the power supply of gyroscope X6 through the 2nd normally opened contact KTL19-2 of described 19th relay holds TLGD；

The port DY2-of programmable power supply meets the-Uz port TL3 of gyroscope X6 through the 1st normally opened contact KTL15-1 of described 15th relay；The port DY2+ of programmable power supply connect the power supply of gyroscope X6 through the 2nd normally opened contact KTL15-2 of described 15th relay holds TLGD；

The port DY1+ of programmable power supply meets the+Uy port TL4 of gyroscope X6 through the 1st normally opened contact KTL20-1 of described 20th relay；The port DY1-of described programmable power supply connect the power supply of gyroscope X6 through the 2nd normally opened contact KTL20-2 of described 20th relay holds TLGD；

The port DY2-of programmable power supply meets the-Uy port TL5 of gyroscope X6 through the 1st normally opened contact KTL16-1 of described 16th relay；The port DY2+ of described programmable power supply connect the power supply of gyroscope X6 through the 2nd normally opened contact KTL16-2 of described 16th relay holds TLGD；

Described electronic delay parts change-over circuit includes the 17th relay, the 21st to the 24th relay and the 29th to the 30th relay；

The port DY2-of programmable power supply meets the power supply negative terminal mouth DYF of electronic delay parts X7 through the 1st normally opened contact KDY17-1 of described 17th relay；The port DY2+ of programmable power supply meets the GND port DYGD of electronic delay parts X7 through the 2nd normally opened contact KDY17-2 of described 17th relay；

Oscillographic port SB1 meets the outfan DYC of electronic delay parts X7 through the 1st normally opened contact KDY24-1 of described 24th relay；Oscillographic port SB1D meets the GND port DYGD of electronic delay parts X7 through the 2nd normally opened contact KDY24-2 of described 24th relay；

The port DY1+ of programmable power supply meets the power positive end mouth DYZ of electronic delay parts X7 through the 1st normally opened contact KDY22-1 of described 22nd relay；The port DY1-of programmable power supply meets the GND port DYGD of electronic delay parts X7 through the 2nd normally opened contact KDY22-2 of described 22nd relay；

The input DYR of electronic delay parts X7 connects the corresponding port of described pulse-generating circuit through the 1st normally opened contact KDY23-1 of described 23rd relay；The GND port DYGD of electronic delay parts X7 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KDY23-2 of described 23rd relay；

The port K21-1 of electronic delay parts X7 meets the port K21-2 of electronic delay parts X7 through the 1st normally opened contact KDY21-1 of described 21st relay；The port K21-3 of electronic delay parts X7 meets the port K21-4 of electronic delay parts X7 through the 2nd normally opened contact KDY21-2 of described 21st relay；

The port K29-1 of electronic delay parts X7 meets the port K29-2 of electronic delay parts X7 through the 1st normally opened contact KDY29-1 of described 29th relay；The port K29-3 of electronic delay parts X7 meets the port K29-4 of electronic delay parts X7 through the 2nd normally opened contact KDY29-2 of described 29th relay；

The port K30-1 of electronic delay parts X7 meets the port K30-2 of electronic delay parts X7 through the 1st normally opened contact KDY30-1 of described 30th relay；The port K30-3 of electronic delay parts X7 meets the port K30-4 of electronic delay parts X7 through the 2nd normally opened contact KDY30-2 of described 30th relay；

Described Missile Body change-over circuit includes the 25th to the 28th relay and the 18th relay；

The port DY1+ of programmable power supply meets the power positive end mouth DTZ of Missile Body X8 through the 1st normally opened contact KDT25-1 of described 25th relay；The port DY1-of programmable power supply meets the GND port DTGD of Missile Body X8 through the 2nd normally opened contact KDT25-2 of described 25th relay；

The port DY2-of programmable power supply meets the power supply negative terminal mouth DTF of Missile Body X8 through the 1st normally opened contact KDT18-1 of described 18th relay；The port DY2+ of programmable power supply meets the GND port DTGD of Missile Body X8 through the 2nd normally opened contact KDT18-2 of described 18th relay；

The fin test point port DT6 of Missile Body X8 connects the corresponding port of described pulse-generating circuit through the 1st normally opened contact KDT28-1 of described 28th relay；The GND port DTGD of Missile Body X8 connects the corresponding port of described pulse-generating circuit through the 2nd normally opened contact KDT28-2 of described 28th relay；

The z port DT4 of Missile Body X8 through the 1st normally opened contact KDT26-1 of described 26th relay connect Missile Body X8-Y-port DT7；The y port DT5 of Missile Body X8 meets the-Z port DT8 of Missile Body X8 through the 2nd normally opened contact KDT26-2 of described 26th relay；

The fin test point port DT6 of Missile Body X8 meets the VA port DT18 of Missile Body X8 through the 1st normally opened contact KDT27-1 of described 27th relay.

Gun launched missile electrical property emulation testing the most according to claim 1 conversion adaptive device, 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 described 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 described functional generator connects 11 feet of described switch module U14；

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

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

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

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

The transmitter control signal input JFX of laser receiver X1 meets the port MZ1 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 meets the port MGD1 of described pulse-generating circuit through the 2nd normally opened contact KJG104-2 of described 104th relay；

The command signal input MZR of electronic installation X2 meets the port MZ1 of described pulse-generating circuit through the 1st normally opened contact KDZ109-1 of described 109th relay；The command signal ground end ZLGD of electronic installation X2 meets the port MGD1 of described pulse-generating circuit through the 2nd normally opened contact KDZ109-2 of described 109th relay；

The Y channel phases detection of electronic installation X2 and ripple amplitude test output terminal YXW meet the port MZ1 of described pulse-generating circuit through the 1st normally opened contact KDZ1010-1 of described 1010th relay；The power supply ground end DZGD of electronic installation X2 meets the port MGD1 of pulse-generating circuit through the 2nd normally opened contact KDZ1010-2 of described 1010th relay；

The Z channel phases detection of electronic installation X2 and ripple amplitude test output terminal ZXW meet the port MZ1 of described pulse-generating circuit through the 1st normally opened contact KDZ105-1 of described 105th relay；The power supply ground end DZGD of electronic installation X2 meets the port MGD1 of described pulse-generating circuit through the 2nd normally opened contact KDZ105-2 of described 105th relay；

The pulse command end DF41 of steering wheel amplifier X3 meets the port MZ1 of described pulse-generating circuit through the 1st normally opened contact KDF1021-1 of described 1021st relay；The power supply ground end DFGD of steering wheel amplifier X3 meets the port MGD1 of described pulse-generating circuit through the 2nd normally opened contact KDZ1021-2 of described 1021st relay；

The pulse command end DF26 of steering wheel amplifier X3 meets the port MZ1 of described pulse-generating circuit through the 1st normally opened contact KDF1022-1 of described 1022nd relay；The power supply ground end DFGD of steering wheel amplifier X3 meets the port MGD1 of described pulse-generating circuit through the 2nd normally opened contact KDF1022-2 of described 1022nd relay；

The pulse command end DF40 of steering wheel amplifier X3 meets the port MZ1 of described pulse-generating circuit through the 1st normally opened contact KDF1017-1 of described 1017th relay；The power supply ground end DFGD of steering wheel amplifier X3 meets the port MGD1 of described pulse-generating circuit through the 2nd normally opened contact KDF1017-2 of described 1017th relay；

The pulse command end DF25 of steering wheel amplifier X3 meets the port MZ1 of pulse-generating circuit through the 1st normally opened contact KDF1018-1 of described 1018th relay；The power supply ground end DFGD of steering wheel amplifier X3 meets the port MGD1 of pulse-generating circuit through the 2nd normally opened contact KDF1018-2 of described 1018th relay；

The z access port DB4 of steering gear component X5 meets the port MZ1 of described pulse-generating circuit through the 1st normally opened contact KDB2-1 of described 2nd relay；The power supply ground end DBGD of steering gear component X5 meets the port MGD1 of described pulse-generating circuit through the 2nd normally opened contact KDB2-2 of described 2nd relay；

The y access port DB5 of steering gear component X5 meets the port MZ1 of described pulse-generating circuit through the 1st normally opened contact KDB3-1 of described 3rd relay；The power supply ground end DBGD of steering gear component X5 meets the port MGD1 of described pulse-generating circuit through the 2nd normally opened contact KDB3-2 of described 3rd relay；

The input DYR of electronic delay parts X7 meets the port MZ1 of described pulse-generating circuit through the 1st normally opened contact KDY23-1 of described 23rd relay；The GND port DYGD of electronic delay parts X7 meets the port MGD1 of described pulse-generating circuit through the 2nd normally opened contact KDY23-2 of described 23rd relay；

The fin test point port DT6 of Missile Body X8 meets the port MZ1 of described pulse-generating circuit through the 1st normally opened contact KDT28-1 of described 28th relay；The GND port DTGD of Missile Body X8 meets the port MGD1 of described pulse-generating circuit through the 2nd normally opened contact KDT28-2 of described 28th relay；

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

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；

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

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 described 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.

Gun launched missile electrical property emulation testing the most according to claim 2 conversion adaptive device, it is characterised in that: described adapter circuit includes Missile Body adapter circuit, steering gear component adapter circuit and steering wheel amplifier adapter circuit；

Described Missile Body adapter circuit includes R10-R13 and port DT11A-DT14A；

Described resistance R13 is connected between the DT11 port of port DT11A and Missile Body X8；

Described resistance R12 is connected between the DT12 port of port DT12A and Missile Body X8；

Described resistance R11 is connected between the DT13 port of port DT13A and Missile Body X8；

Described resistance R10 is connected between the DT14 port of port DT14A and Missile Body X8；

Described port DT11A-DT14A connects the described corresponding port selecting switch respectively；

Described steering gear component adapter circuit includes resistance R1-R9, resistance R15-R22, electric capacity C1-C4, rheostat VR1-VR4, operational amplifier U16-U18, port DB9A-DB9E, port DB10A-DB10E, port ZYZ, port ZJY, port TQD, port DBFA and port DBFB;

Described rheostat VR1 connects with described resistance R1 and is followed by between described port ZYZ and described port DB9A；The sliding end of described rheostat VR1 is connected on the node of described rheostat VR1 and described resistance R1；

Described rheostat VR2 connects with described resistance R2 and is followed by between described port ZJY and described port DB10A；The sliding end of described rheostat VR2 is connected on the node of described rheostat VR2 and described resistance R2；

Described electric capacity C1 and electric capacity C2 connects and is followed by between the node of described rheostat VR1 and the node of described resistance R1 and described rheostat VR2 and described resistance R2；

Described resistance R4 and resistance R6 connects and is followed by between described port DB9B and port DB9C；

Described resistance R5 and resistance R7 connects and is followed by between described port DB10B and port DB10C；

Described electric capacity C3 and electric capacity C4 connects and is followed by between described resistance R4 and the node of resistance R6 and described resistance R5 and the node of resistance R7；

Described resistance R8 is connected between described port DB9D and port DB9E；

Described resistance R9 is connected between described port DB10D and port DB10E；

Described rheostat VR3 and rheostat VR4 connects and is followed by between described port DB9E and port DB10E；

The sliding end of described rheostat VR3 and rheostat VR4 connects the node of described rheostat VR3 and rheostat VR4 respectively；

The in-phase input end of described operational amplifier U16 meets described port DBFB through described resistance R15；

The in-phase input end of described operational amplifier U17 meets described port DBFA through described resistance R16；

The inverting input of described operational amplifier U16 connects the inverting input of described operational amplifier U17 through described resistance R17；

The outfan of described operational amplifier U16 connects the inverting input of described operational amplifier U18 through described resistance R20；

The outfan of described operational amplifier U17 connects the in-phase input end of described operational amplifier U18 through described resistance R22；

The output of described operational amplifier U18 terminates described port TQD；

Described resistance R3 is connected between described port DBFA and port DBFB；

Described resistance R18 is connected between inverting input and its outfan of described operational amplifier U16；

Described resistance R19 is connected between inverting input and its outfan of described operational amplifier U17；

Described resistance R21 is connected between inverting input and its outfan of described operational amplifier U18；

The positive power source terminal of described operational amplifier U16-U18 meets the port+15V+ of described programmable power supply respectively；The negative power end of described operational amplifier U16-U18 meets the port-15V-of described programmable power supply respectively；

Described port DB9E, port DB10E, port ZYZ and port ZJY connect the described corresponding port selecting switch respectively；

The power supply negative terminal DBF of steering gear component X5 meets the port DBFB of described steering gear component adapter circuit through the 1st normally opened contact KDB6-1 of described 6th relay；The port DY2-of programmable power supply meets the port DBFA of described steering gear component adapter circuit through the 2nd normally opened contact KDB6-2 of described 6th relay；

The signal output port DB9 of steering gear component X5 meets the port DB9A of described steering gear component adapter circuit through the 1st normally opened contact KDB5-1 of described 5th relay；The signal output port DB10 of steering gear component X5 meets the port DB10A of described steering gear component adapter circuit through the 2nd normally opened contact KDB5-2 of described 5th relay；

The signal output port DB9 of steering gear component X5 meets the port DB9B of described steering gear component adapter circuit through the 1st normally opened contact KDB10-1 of described 10th relay；The signal output port DB10 of steering gear component X5 meets the port DB10B of described steering gear component adapter circuit through the 2nd normally opened contact KDB10-2 of described 10th relay；

The signal output port DB9 of steering gear component X5 meets the port DB9D of described steering gear component adapter circuit through the 1st normally opened contact KDB13-1 of described 13rd relay；The signal output port DB10 of steering gear component X5 meets the port DB10D of described steering gear component adapter circuit through the 2nd normally opened contact KDB13-2 of described 13rd relay；

Oscillographic port SB1 meets the port DB9C of described steering gear component adapter circuit through the 1st normally opened contact KDB11-1 of described 11st relay；Oscillographic port SB1D connect the power supply of steering gear component X5 through the 2nd normally opened contact KDB11-2 of described 11st relay holds DBGD；

Oscillographic port SB1 meets the port DB10C of described steering gear component adapter circuit through the 1st normally opened contact KDB12-1 of described 12nd relay；Oscillographic port SB1D connect the power supply of steering gear component X5 through the 2nd normally opened contact KDB12-2 of described 12nd relay holds DBGD；

Described steering wheel amplifier adapter circuit includes resistance R31-R38, port DCD, port DK28, port DK35, port DK31, port DK37, port DC37, port DC31, port DC35 and port DC28；

Described resistance R31 and resistance R35 connects and is followed by between described port DC37 and port DCD；Described port DK37 is the node of described resistance R31 and resistance R35；

Described resistance R32 and resistance R36 connects and is followed by between described port DC31 and port DCD；Described port DK31 is the node of described resistance R32 and resistance R36；

Described resistance R33 and resistance R37 connects and is followed by between described port DC35 and port DCD；Described port DK35 is the node of described resistance R33 and resistance R37；

Described resistance R34 and resistance R38 connects and is followed by between described port DC28 and port DCD；Described port DK28 is the node of described resistance R34 and resistance R38；

Described port DC37, port DC31, port DC35 and port DC28 connect the described corresponding port selecting switch respectively；

The port DY3+ of programmable power supply meets the port DCD of described steering wheel amplifier adapter circuit through the 1st normally opened contact KDF1016-1 of described 1016th relay；The multimeter port DF31 of steering wheel amplifier X3 meets the port DK31 of described steering wheel amplifier adapter circuit through the 1st normally opened contact KDF1025-1 of described 1025th relay；The multimeter port DF37 of steering wheel amplifier X3 meets the port DK37 of described steering wheel amplifier adapter circuit through the 2nd normally opened contact KDF1025-2 of described 1025th relay；The multimeter port DF28 of steering wheel amplifier X3 meets the port DK28 of described steering wheel amplifier adapter circuit through the 1st normally opened contact KDF1026-1 of described 1026th relay；The multimeter port DF35 of steering wheel amplifier X3 meets the port DK35 of described steering wheel amplifier adapter circuit through the 2nd normally opened contact KDF1026-2 of described 1026th relay.

Gun launched missile electrical property emulation testing the most according to claim 3 conversion adaptive device, it is characterised in that: described conversion control circuit includes the first conversion control circuit and the second conversion control circuit；

Described first conversion control circuit includes buffer U1-5 ~ U1-10, rp-drive U1-11 ~ U1-15 and 9 foot exclusion RP1 ~ RP4；

Input 1A ~ the 6A of described buffer U1-5 connects the corresponding port of described second numeral I/O module respectively；Outfan 1Y ~ the 6Y of described buffer U1-5 connects corresponding input 6 foot ~ 1 foot of described rp-drive U1-11 respectively；The power end VCC of described buffer U1-5 meets the port+5V+ of described programmable power supply；The earth terminal GND ground connection of described buffer U1-5；9 feet of described rp-drive U1-11 meet the port+24V+ of described programmable power supply；The 8 foot ground connection of described rp-drive U1-11；

Input 1A ~ the 6A of described buffer U1-6 connects the corresponding port of described second numeral I/O module respectively；Outfan 1Y ~ the 5Y of described buffer U1-6 connects corresponding input 5 foot ~ 1 foot of described rp-drive U1-12 respectively；The outfan 6Y of described buffer U1-6 connects input 7 foot of described rp-drive U1-11；The power end VCC of described buffer U1-6 meets the port+5V+ of described programmable power supply；The earth terminal GND ground connection of described buffer U1-6；9 feet of described rp-drive U1-12 meet the port+24V+ of described programmable power supply；The 8 foot ground connection of described rp-drive U1-12；

Input 1A ~ the 6A of described buffer U1-7 connects the corresponding port of described second numeral I/O module respectively；Outfan 1Y ~ the 4Y of described buffer U1-7 connects corresponding input 4 foot ~ 1 foot of described rp-drive U1-13 respectively；Outfan 5Y ~ the 6Y of described buffer U1-7 connects input 7 foot ~ 6 foot of described rp-drive U1-12 respectively；The power end VCC of described buffer U1-7 meets the port+5V+ of described programmable power supply；The earth terminal GND ground connection of described buffer U1-7；9 feet of described rp-drive U1-13 meet the port+24V+ of described programmable power supply；The 8 foot ground connection of described rp-drive U1-13；

Input 5A ~ the 6A of described buffer U1-8 connects the corresponding port of described second numeral I/O module respectively；Outfan 5Y ~ the 6Y of described buffer U1-8 connects corresponding input 6 foot ~ 5 foot of described rp-drive U1-13 respectively；The power end VCC of described buffer U1-8 meets the port+5V+ of described programmable power supply；The earth terminal GND ground connection of described buffer U1-8；

Input 1A ~ the 6A of described buffer U1-9 connects the corresponding port of described second numeral I/O module respectively；Outfan 2Y ~ the 6Y of described buffer U1-9 connects corresponding input 7 foot ~ 3 foot of described rp-drive U1-14 respectively；The outfan 1Y of described buffer U1-9 connects input 1 foot of described rp-drive U1-15；The power end VCC of described buffer U1-9 meets the port+5V+ of described programmable power supply；The earth terminal GND ground connection of described buffer U1-9；9 feet of described rp-drive U1-14 meet the port+24V+ of programmable power supply；The 8 foot ground connection of described rp-drive U1-14；

Input 1A ~ the 4A of described buffer U1-10 connects the corresponding port of described second numeral I/O module respectively；Outfan 1Y ~ the 4Y of described buffer U1-10 connects corresponding input 7 foot ~ 4 foot of described rp-drive U1-15 respectively；The power end VCC of described buffer U1-10 meets the port+5V+ of described programmable power supply；The earth terminal GND ground connection of described buffer U1-10；9 feet of described rp-drive U1-15 meet the port+24V+ of programmable power supply；The 8 foot ground connection of described rp-drive U1-15；

The common port of described 9 foot exclusion RP1 ~ RP4 meets the port+5V+ connecing programmable power supply respectively respectively；Remaining 8 not common end pin of described 9 foot exclusion RP1 are corresponding respectively connects input 1 foot ~ 7 foot of described rp-drive U1-11 and input 1 foot of described rp-drive U1-12；Remaining 8 not common end pin of described 9 foot exclusion RP2 are corresponding respectively connects input 2 foot ~ 7 foot of described rp-drive U1-12 and input 1 foot of described rp-drive U1-13；Input 7 foot ~ 5 foot of remaining 8 not common end pin of described 9 foot exclusion RP3 corresponding input 4 foot ~ 7 foot, 1 foot and described rp-drive U1-14 meeting described rp-drive U1-15 respectively；

Wherein 6 not common end pin correspondences respectively of described 9 foot exclusion RP4 connect input 4 foot ~ 3 foot of described rp-drive U1-14 and input 5 foot ~ 2 foot of described rp-drive U1-13；

The coil KDB1 of described 1st relay is connected between outfan 11 foot and the port+24V+ of described programmable power supply of described rp-drive U1-11；

The coil KDB2 of described 2nd relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U1-11；

The coil KDB3 of described 3rd relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U1-11；

The coil KDB5 of described 5th relay is connected between outfan 14 foot and the port+24V+ of described programmable power supply of described rp-drive U1-11；

The coil KDB6 of described 6th relay is connected between outfan 15 foot and the port+24V+ of described programmable power supply of described rp-drive U1-11；

The coil KDB7 of described 7th relay is connected between outfan 16 foot and the port+24V+ of described programmable power supply of described rp-drive U1-11；

The coil KDB9 of described 9th relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U1-12；

The coil KMZ1 of described first Pulse Width Control relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U1-12；

The coil KDB10 of described 10th relay is connected between outfan 14 foot and the port+24V+ of described programmable power supply of described rp-drive U1-12；

The coil KDB11 of described 11st relay is connected between outfan 15 foot and the port+24V+ of described programmable power supply of described rp-drive U1-12；

The coil KDB12 of described 12nd relay is connected between outfan 16 foot and the port+24V+ of described programmable power supply of described rp-drive U1-12；

The coil KDB13 of described 13rd relay is connected between outfan 10 foot and the port+24V+ of described programmable power supply of described rp-drive U1-11；

The coil KDB14 of described 14th relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U1-13；

The coil KDB15 of described 15th relay is connected between outfan 14 foot and the port+24V+ of described programmable power supply of described rp-drive U1-13；

The coil KTL16 of described 16th relay is connected between outfan 15 foot and the port+24V+ of described programmable power supply of described rp-drive U1-13；

The coil KTL17 of described 17th relay is connected between outfan 16 foot and the port+24V+ of described programmable power supply of described rp-drive U1-13；

The coil KDY18 of described 18th relay is connected between outfan 10 foot and the port+24V+ of described programmable power supply of described rp-drive U1-12；

The coil KDT19 of described 19th relay is connected between outfan 11 foot and the port+24V+ of described programmable power supply of described rp-drive U1-12；

The coil KTL20 of described 20th relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U1-13；

The coil KDY21 of described 21st relay is connected between outfan 14 foot and the port+24V+ of described programmable power supply of described rp-drive U1-14；

The coil KDY22 of described 22nd relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U1-14；

The coil KDY23 of described 23rd relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U1-14；

The coil KDY24 of described 24th relay is connected between outfan 11 foot and the port+24V+ of described programmable power supply of described rp-drive U1-14；

The coil KDT25 of described 25th relay is connected between outfan 10 foot and the port+24V+ of described programmable power supply of described rp-drive U1-14；

The coil KDT26 of described 26th relay is connected between outfan 16 foot and the port+24V+ of described programmable power supply of described rp-drive U1-15；

The coil KDT27 of described 27th relay is connected between outfan 10 foot and the port+24V+ of described programmable power supply of described rp-drive U1-15；

The coil KDT28 of described 28th relay is connected between outfan 11 foot and the port+24V+ of described programmable power supply of described rp-drive U1-15；

The coil KDY29 of described 29th relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U1-15；

The coil KDY30 of described 30th relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U1-15；

Described second conversion control circuit includes buffer U2-5 ~ U2-10, rp-drive U2-11 ~ U2-15 and 9 foot exclusion RP5 ~ RP8；

Described second conversion control circuit is identical with the structure of described first conversion control circuit；

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 KDZ105 of described 105th relay is connected between outfan 15 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KDZ106 of described 106th relay is connected between outfan 16 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KDZ107 of described 107th relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U2-12；

The coil KDZ108 of described 108th relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U2-12；

The coil KDZ109 of described 109th relay is connected between outfan 14 foot and the port+24V+ of described programmable power supply of described rp-drive U2-12；

The coil KDZ1010 of described 1010th relay is connected between outfan 15 foot and the port+24V+ of described programmable power supply of described rp-drive U2-12；

The coil KDZ1011 of described 1011st relay is connected between outfan 16 foot and the port+24V+ of described programmable power supply of described rp-drive U2-12；

The coil KDZ1012 of described 1012nd relay is connected between outfan 10 foot and the port+24V+ of described programmable power supply of described rp-drive U2-11；

The coil KDF1013 of described 1013rd relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U2-13；

The coil KDF1013 of described 1014th relay is connected between outfan 14 foot and the port+24V+ of described programmable power supply of described rp-drive U2-13；

The coil KDF1015 of described 1015th relay is connected between outfan 15 foot and the port+24V+ of described programmable power supply of described rp-drive U2-13；

The coil KDF1016 of described 1016th relay is connected between outfan 16 foot and the port+24V+ of described programmable power supply of described rp-drive U2-13；

The coil KDF1017 of described 1017th relay is connected between outfan 10 foot and the port+24V+ of described programmable power supply of described rp-drive U2-12；

The coil KDF1018 of described 1018th relay is connected between outfan 11 foot and the port+24V+ of described programmable power supply of described rp-drive U2-12；

The coil KDF1019 of described 1019th relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U2-13；

The coil KDF1021 of described 1021st relay is connected between outfan 14 foot and the port+24V+ of described programmable power supply of described rp-drive U2-14；

The coil KDF1022 of described 1022nd relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U2-14；

The coil KDF1023 of described 1023rd relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U2-14；

The coil KDF1024 of described 1024th relay is connected between outfan 11 foot and the port+24V+ of described programmable power supply of described rp-drive U2-14；

The coil KDF1025 of described 1025th relay is connected between outfan 10 foot and the port+24V+ of described programmable power supply of described rp-drive U2-14；

The coil KDF1026 of described 1026th relay is connected between outfan 16 foot and the port+24V+ of described programmable power supply of described rp-drive U2-15；

The coil KDF1027 of described 1027th relay is connected between outfan 10 foot and the port+24V+ of described programmable power supply of described rp-drive U2-15；

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

The coil KDZ1029 of described 1029th relay is connected between outfan 12 foot and the port+24V+ of described programmable power supply of described rp-drive U2-15；

The coil KDZ1030 of described 1030th relay is connected between outfan 13 foot and the port+24V+ of described programmable power supply of described rp-drive U2-15.

Gun launched missile electrical property emulation testing the most according to claim 4 conversion adaptive device, 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；Described buffer U1-5 ~ U1-10, the model of buffer U2-5 ~ U2-10 are 74LS07；Described rp-drive U1-11 ~ U1-15, the model of rp-drive U2-11 ~ U2-15 are MC1413.